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Home My WebLink AboutB17-0280_LochinvarCBN135Instructions_1501604460.pdf1 Installation and service must be performed by a qualified service installer, service agency or the gas supplier. Factory warranty (shipped with appliance) does not apply to appliances improperly installed or improperly operated. Experience has shown that improper installation or system design, rather than faulty equipment, is the cause of most operating problems. 1. Excessive water hardness causing a lime buildup in the copper tube is not the fault of the equipment and is not covered under the manufacturers warranty (see Water Treatment and Water Chemistry). 2. Excessive pitting and erosion on the inside of the copper tube may be caused by too much water velocity through the tubes and is not covered by the manufacturers warranty (see Boiler Flow Rates and Temperature Rise for flow requirements). This manual supplies information for the installation, operation and servicing of the appliance. It is strongly recommended that this manual be reviewed completely before proceeding with an installation. Upon receiving equipment, check for signs of shipping damage. Pay particular attention to parts accompanying the appliance which may show signs of being hit or otherwise being mishandled. Verify total number of pieces shown on packing slip with those actually received. In case there is damage or a shortage, immediately notify carrier. Hot Water Heating Boiler Water Heater/Domestic Hot Water Supply Boiler 45,000500,000 Btu/hr Models RB/RW-i&s-07 INSTALLATION AND SERVICE MANUAL WARRANTY NOTE: Retain this manual for future reference. SPECIAL INSTRUCTIONS TO OWNER WARNING: Improper Installation,Adjustment, Alteration, Service or Maintenance can cause injury or property damage. Refer to this manual. For assistance or additional information consult a qualified installer, service agency or the gas supplier. CHECKING EQUIPMENT Use this appliance if any part has been under water. The possible damage to a flooded appliance can be extensive and present numerous safety hazards. Any appliance that has been under water must be replaced. DO NOT If the information in this manual is not followed exactly, a fire or explosion may result causing property damage, personal injury or loss of life. The appliance MUST NOT be installed in any location where gasoline or flammable vapors are likely to be present, unless the installation is such to eliminate the probable ignition of gasoline or flammable vapors. - Do not try to light any appliance. Do not touch any electric switch; do not use any phone in your building. Immediately call your gas supplier from a neighbors phone. Follow the gas suppliers instructions. If you cannot reach your gas supplier, call the fire department. Installation and service must be performed by a qualified installer, service agency or the gas supplier. WARNING: — WHAT TO DO IF YOU SMELL GAS — 08/01/17 2 The information contained in this manual is intended for use by qualified professional installers, service technicians or gas suppliers. Consult your local expert for proper installation or service procedures. Your conventionally vented gas appliance must have a supply of fresh air circulating around it during burner operation for proper gas combustion and proper venting. 1. Boilers and water heaters are heat producing appliances. To avoid damage or injury, do not store materials against the appliance or the vent-air intake system. Use proper care to avoid unnecessary contact (especially children) with the appliance and vent-air intake components. 2. Never cover your appliance, lean anything against it, store trash or debris near it, stand on it or in any way block the flow of fresh air to your appliance. 3. UNDER NO CIRCUMSTANCES must flammable materials such as gasoline or paint thinner be used or stored in the vicinity of this appliance, vent-air intake system or any location from which fumes could reach the appliance or vent-air intake system. The equipment shall be installed in accordance with installation regulations in force in the local area where the installation is to be made. These regulations shall be carefully followed in all cases. Authorities having jurisdiction shall be consulted before installations are made. In the absence of such requirements, the installa- tion shall conform to the latest edition of the National Fuel Gas Code, ANSI Z223.1. Where required by the authority having jurisdiction, the installation must conform to American Society of Mechanical Engineers CONTENTS Warranty Safety Warnings ......................................................................1 Codes ..................................................................................2 Location ..................................................................................3 Clearances................................................................................4 Combustion/Ventilation Air Requirements ............................4 Conventional Venting ..............................................................7 Masonry Chimney Installations............................................10 Sidewall Venting....................................................................10 Automatic Vent Damper........................................................11 Gas Supply ............................................................................12 Gas Pressures & Piping..........................................12 Manifold Pressure Adjustment ..............................15 Supply Pressure Measurement ..............................16 Water Connections ................................................................17 Relief Valve............................................................................19 Flow Switch ..........................................................................19 Gas Valve ..............................................................................20 Electrical Requirements ........................................................21 Temperature Adjustment ......................................................22 Temperature Limit Control....................................................22 Blocked Vent and Flame Roll-out System............................22 Lighting Instructions ............................................................24 Ignition & Control Timings ..................................................29 Freeze Protection ..................................................................29 Maintenance ..........................................................................30 Flame Patterns........................................................30 Burner Cleaning ....................................................31 Heat Exchanger Inspection....................................32 Lubrication ............................................................32 Gas Train................................................................................33 Heating Boiler ......................................................................34 Installation Requirements ......................................34 Pump Requirements ..............................................34 Pressure Drop Chart ..............................................34 Boiler Pump Operation..........................................34 Typical Piping ........................................................35 Bypass Requirements ............................................35 Low Temperature Systems ....................................36 Boiler Flow Rates ..................................................37 Temperature Rise Chart ........................................38 Placing Boiler in Operation ..................................38 Boiler Temperature Control ..................................40 Remote Thermostat Control Connection ............................40 Water Heater/Domestic Hot Water Supply Boiler................40 Water Velocity Control ..........................................41 Temperature Rise....................................................41 Water Chemistry ....................................................42 Piping Requirements..............................................42 Pump Requirements ..............................................43 Temperature Adjustment........................................43 Risk of Scald Warnings..........................................44 USER WARNING IMPORTANT:Consult and follow local Building and Fire Regulations and other Safety Codes that apply to this installation. Consult your local gas utility company to authorize and inspect all gas and flue connections. WARNING: Should overheating occur or the gas supply fail to shut off, do not turn offor disconnect the electrical supply to the pump. Instead, shut off the gas supply at a location external to the appliance. WARNING: To minimize the possibility of serious personal injury, fire or damage to your appliance, never violate the following safety rules. CODES 08/01/17 3 1. Locate the appliance so that if water connections should leak, water damage will not occur. When such locations cannot be avoided, it is recommended that a suitable drain pan, adequately drained, be installed under the appliance. The pan must not restrict combustion air flow. Under no circumstances is the manufacturer to be held responsible for water damage in connection with this appliance, or any of its components. 2. The appliance must be installed indoors where it is protected from exposure to wind, rain and weather. 3. The appliance must be installed so that the ignition system components are protected from water (dripping, spraying, rain, etc.) during appliance operation and service (circulator replacement, control replacement, etc.,). 4. Appliances located in a residential garage and in adjacent spaces that open to the garage and are not part of the living space of a dwelling unit must be installed so that all burners and burner ignition devices have a minimum clearance of not less than 18" (46cm) above the floor. The appliance must be located or protected so that it is not subject to physical damage by a moving vehicle. 5. DO NOT install this appliance in any location where gasoline or flammable vapors are likely to be present. 6. The appliance must be installed on a level, noncombustible floor. A concrete over wood construction is not considered a noncombustible floor. Maintain required clearances from combustible surfaces. 7. The appliance must not be installed on carpet or other combustible material. 8. For installation on a combustible floor only when installed on special base: Appliances installed over a combustible floor MUST use the Special Combustible Floor Base Kit. The appliance must be centered on the base as shown in Figure 4. The correct part number for the required base kit is noted on the rating plate of each appliance and listed in Table A. Safety Code for Controls and Safety Devices for Auto- matically Fired Boilers, ASME CSD-1. All boilers conform to the latest edition of the ASME Boiler and Pressure Vessel Code, Section IV. Where required by the authority having jurisdiction, the installation must comply with the Canadian Association Code, CAN/CGA-B149.1 and/or B149.2 and/or local codes. This appliance meets the safe lighting performance criteria with the gas manifold and control assembly provided as specified in the ANSI standards for gas-fired appliances, ANSI Z21.13. INSTALLATION PROCEDURE FIG. 2 Front View 399,000—500,000 Btu Models Front View 45,000—360,000 Btu Models FIG. 3 Rear View 45,000—500,000 Btu Models LOCATION OF UNIT FIG. 1 08/01/17 4 Clearances from Combustible Construction: Right Side - 6" Rear - 6" Left Side - 6" (24" suggested for service) Front - (24" suggested for service) 45,000 - 180,000 BTU Models - 6" 199,000 - 500,000 BTU Models - ALCOVE* Top - (measured from draft hood) 45,000 - 180,000 BTU Models - 14" 199,000 - 500,000 BTU Models - 29" *An ALCOVE is a closet enclosure without a front door. Allow sufficient space for servicing pipe connections, pump and other auxiliary equipment, as well as the appliance. TABLE - A COMBUSTIBLE FLOOR BASE KITS Input BTU/hr Kit Number 45,000 CFK3045 75,000 CFK3090 90,000 CFK3090 135,000 CFK3135 180,000 CFK3180 199,000 CFK3225 225,000 CFK3225 270,000 CFK3270 315,000 CFK3315 360,000 CFK3360 399,000 CFK3399 500,000 CFK3500 CLEARANCES FROM COMBUSTIBLE CONSTRUCTION FIG. 4 FIG. 5A Provisions for combustion and ventilation air must be in accordance with Section 5.3, Air for Combustion and Ventilation, of the latest edition of the National Fuel Gas Code, ANSI Z223.1, in Canada, the latest edition of CGA Standard B149 Installation Code for Gas Burning Appliances and Equipment, or applicable provisions of the local building codes. The mechanical room MUST be provided with properly sized openings to assure adequate combustion air and proper ventilation when the appliance is installed with conventional venting. COMBUSTION AND VENTILATION AIR REQUIREMENTS FOR CONVENTIONALLY VENTED APPLIANCES FIG. 5B Clearances Models 45,000–180,000 Clearances Models 199,000–500,000 Combustion Floor Base 29" 6" 6" 6" 14" 08/01/17 5 1. If air is taken directly from outside the building with no duct, provide two permanent openings: a. Combustion air opening, with a minimum free area of one square inch per 4000 Btu/hr input (5.5cm2 per kW). This opening must be located within 12" (30 cm) of the bottom of the enclosure. b. Ventilation air opening, with a minimum free area of one square inch per 4000 Btu/hr input (5.5cm2 per kW). This opening must be located within 12" (30cm) of the top of the enclosure. 2. If combustion and ventilation air is taken from the outdoors using a duct to deliver the air to the mechanical room, each of the two openings should be sized based on a minimum free area of one square inch per 2000 Btu/hr (11cm2 per kW). 3. If air is taken from another interior space that is adequately ventilated, each of the two openings specified above should have a net free area of one square inch for each 1000 Btu/hr (22cm2 per kW) of input, but not less than 100 square inches (645 cm2). 4. If a single combustion air opening is provided to bring combustion air in directly from the outdoors, the opening must be sized based on a minimum free area of one square inch per 3000 Btu/hr (7cm2 per kW). This opening must be located within 12" (30cm) of the top of the enclosure. Combustion Air Direct from Outside FIG. 6 Combustion Air Through Ducts Combustion Air from Interior Space Combustion Air from Outside Single Opening FIG. 8 FIG. 7 FIG. 9 08/01/17 6 *Outside air openings shall directly communicate with the outdoors. When combustion air is drawn from the outside through a duct, the net free area of each of the two openings must have twice (2 times) the free area required for Outside Air/2 Openings. The above require- ments are for the appliance only, additional gas fired appliances in the mechanical room will require an increase in the net free area to supply adequate combus- tion air for all appliances. Combustion air requirements are based on the latest edition of the National Fuel Gas Code, ANSI Z223.1, in Canada refer to National Standard CAN B149.1 or B149.2. Check all local code requirements for combustion air. All dimensions based on net free area in square inches. Metal louvers or screens reduce the free area of a combustion air opening a minimum of approximately 25%. Check with louver manufacturers for exact net free area of louvers. Where two openings are provided, one must be within 12" (30 cm) of the ceiling and one must be within 12" (30 cm) of the floor of the mechanical room. Each opening must have net free area as specified in the chart above. Single openings shall be located within 12" (30 cm) of the ceiling. The combustion air supply must be completely free of any flammable vapors that may ignite or chemical fumes which may be corrosive to the appliance. Common corrosive chemical fumes which must be avoided are fluorocarbons and other halogenated compounds, most commonly present as refrigerants or solvents, such as Freon, trichlorethylene, perchlorethylene, chlorine, etc. These chemicals, when burned, form acids which quickly attack the heat exchanger finned tubes, headers, flue collectors, and the vent system. The result is improper combustion and a non-warrantable, premature appliance failure. EXHAUST FANS: Any fan or equipment which exhausts air from the mechanical room may deplete the combustion air supply and/or cause a down draft in the venting system, spilling flue products into the room. Spillage of flue products from the venting system into an occupied living space can cause a very hazardous condition that must be immediately corrected. If a fan is used to supply combustion air to the TABLE - B MINIMUM RECOMMENDED COMBUSTION AIR SUPPLY TO MECHANICAL ROOM Combustion Air Source Input Outside Air*/2 Outside Air*/1 Inside Air/2 Btu/hr Openings Openings Openings 45,000 12 in2 15 in2 100 in2 75,000 19 in2 25 in2 100 in2 90,000 23 in2 30 in2 100 in2 135,000 34 in2 45 in2 135 in2 180,000 45 in2 60 in2 180 in2 199,000 50 in2 67 in2 200 in2 225,000 56 in2 75 in2 225 in2 270,000 68 in2 90 in2 270 in2 315,000 79 in2 105 in2 315 in2 360,000 90 in2 120 in2 360 in2 399,000 100 in2 133 in2 400 in2 500,000 125 in2 167 in2 500 in2 CAUTION:  Under no circumstances should the mechanical room ever be under a negative pressure. Particu- lar care should be taken where exhaust fans, attic fans, clothes dryers, compressors, air handling units, etc., may take away air from the unit. 08/01/17 7 mechanical room, the installer must make sure that it does not cause drafts which could lead to nuisance operational problems with the appliance. Vent installations for connection to gas vents or chimneys must be in accordance with Part 7, Venting of Equipment, of the latest edition of the National Fuel Gas Code, ANSI Z223.1, in Canada, the latest edition of CGA Standard B149 Installation Code for Gas Burning Appliances and Equipment or applicable provisions of the local building codes. Adequate combustion and ventilation air must be supplied to the mechanical room in accordance with the latest edition of the National Fuel Gas Code, ANSI Z223.1, in Canada, the latest edition of CGA Standard B149 Installation Code for Gas Burning Appliances and Equipment, or applicable provisions of the local building codes. The distance of the vent terminal from adjacent buildings, windows that open and building openings MUST comply with the latest edition of the National Fuel Gas Code, ANSI Z223.1, in Canada, the latest edition of CGA Standard B149 Installation Code for Gas Burning Appliances and Equipment. Vent connection is made directly to the top of the appliance. This appliance is designed with a built-in draft diverter. No additional draft diverter is required. The connection from the appliance vent to the common vent or chimney must be made as direct as possible. The negative draft in a conventional vent installation must be within the range of a negative 0.02 to 0.05 inches water to insure proper operation. All draft readings are made while the appliance is in stable operation (approximately 2 to 5 minutes). Multiple appliance installations with combined venting or common venting with other negative draft appliances require that each appliance must have draft within the proper range. If the draft measured above the appliances built-in draft hood exceeds the specified range in a dedicated chimney for a single appliance installation or in combined venting with other negative draft appliances, a barometric damper must be installed to control draft. On a conventionally vented, negative draft appliance, the connection from the vent to the chimney or vent termination on the outside of the building MUST be made with listed Type B doublewall (or equivalent) vent connectors and must be direct as possible with no reduction in diameter. Use the National Fuel Gas Code venting tables for doublewall vent to properly size all vent connectors and stacks. The Type B vent and accessories, such as firestop spacers, thimbles, caps, etc., MUST be installed in accordance with the manufacturers listing. The vent connector and firestop must provide correct spacing to combustible surfaces and seal to the vent connector on the upper and lower sides of each floor or ceiling through which the vent connector passes. VENTING TABLE - C VENT PIPE SIZES Input BTU/hr Flue Size 45,000 3" 75,000 5" 90,000 5" 135,000 5" 180,000 6" 199,000 6" 225,000 7" 270,000 7" 315,000 8" 360,000 8" 399,000 10" 500,000 10" Conventional Negative Draft Vertical Venting FIG. 10 A CONVENTIONAL NEGATIVE DRAFT VENTING SYSTEM 08/01/17 8 Any vent materials used must be listed by a nationally recognized test agency for use as vent material. Locate appliance as close as possible to chimney or gas vent. Avoid long horizontal runs of the vent pipe, 90° elbows, reductions and restrictions. Horizontal portions of the venting system shall be supported to prevent sagging. Horizontal runs must slope upwards not less than 1/4 inch per foot (21 mm/m) from the appliance to the vent terminal. Follow manufacturers instructions. Do not use an existing chimney as a raceway for a flue pipe if another appliance or fireplace is vented through the chimney. The weight of the venting system must not rest on the appliance. Adequate support of the venting system must be provided in compliance with local codes and other applicable codes. All connections should be secured with rustproof sheet metal screws. Vent connectors serving appliances vented by natural draft shall not be connected to any portion of a mechanical draft system operating under positive pressure. Connection to a positive pressure chimney may cause flue products to be discharged into the living space causing serious health injury. Common venting systems may be too large when an existing appliance is removed. At the time of removal of an existing appliance, the following steps shall be followed with each appliance remaining connected to the common venting system placed in operation, while other appliances remaining connected to the common venting system are not in operation. (a) Seal any unused opening in the common venting system. (b) Visually inspect the venting system for proper size and horizontal pitch and determine there is no blockage or restriction, leakage, corrosion and other deficiencies which could cause an unsafe condition. (c) Insofar as is practical, close all building doors and windows and all doors between the space in which the appliances remaining connected to the common venting system are located and other spaces of the building. Turn on clothes dryers and any other appliances not connected to the common venting system. Turn on any exhaust fans, such as range hoods and bathroom exhausts, so they will operate at maximum speed. Do not operate a summer exhaust fan. Close fireplace dampers. (d) Place in operation, the appliance being inspected. Follow the lighting instructions. Adjust thermostat so appliance will operate continuously. (e) Test for spillage at the draft hood/relief opening after five minutes of main burner operation. Use the flame of a match or candle, or smoke from a cigarette, cigar or pipe. (f) After it has been determined that each appliance remaining connected to the common venting system properly vents when tested as outlined above, return doors, windows, exhaust fans, fireplace dampers and other gas burning appliances to their previous conditions of use. (g) Any improper operation of the common venting system should be corrected so that the installation conforms to the latest edition of the National Fuel Gas Code, ANSI Z223.1. In Canada, the latest edition of CGA Standard B149 Installation Code for Gas Burning Appliances and Equipment. When resizing any portion of the common venting system, the common venting system should be resized to approach the minimum size as determined using the appropriate tables in Part 11 in the latest edition of the National Fuel Gas Code, ANSI Z223.1. In Canada, the latest edition of CGA Standard B149 Installation Code for Gas Burning Appliances and Equipment. 08/01/17 9 The vent terminal should be vertical and exhaust outside the building at least 2 feet (0.61m) above the highest point of the roof within a 10 foot (3.05m) radius of the termination. The vertical termination must be a minimum of 3 feet (0.91m) above the point of exit. A vertical termination less than 10 feet (3.05m) from a parapet wall must be a minimum of 2 feet (0.61m) higher than the parapet wall. The vent cap should have a minimum clearance of 4 feet (1.22m) horizontally from and in no case above or below, unless a 4 foot (1.22m) horizontal distance is maintained from electric meters, gas meters, regulators and relief equipment. The venting system shall terminate at least 3 feet (0.9m) above any forced air inlet within 10 feet (3.05m). VENTING TERMINATION FIG. 11 Vent Termination from Peaked Roof 10’ or Less from Ridge FIG. 12 Vent Termination from Peaked Roof More Than 10’ from Ridge RIDGE MORE THAN 10' 3' MIN 2' MIN 10' CHIMNEY FIG. 13 Vent Termination from Flat Roof 10’ or Less from Parapet Wall Vent Termination from Flat Roof More Than 10’ from Parapet Wall 10’ OR LESS 3’ WALL OR PARAPET CHIMNEY NOTE: NO HEIGHT ABOVE PARAPET REQUIRED WHEN DISTANCE FROM WALLS OR PARAPETS IS MORE THAN 10’. FIG. 14 08/01/17 10 The venting system shall terminate at least 4 feet (1.2m) below, 4 feet (1.2m) horizontally from, or 1 foot (30cm) above any door, window or gravity air inlet into any building. Do not terminate the vent in a window well, stairwell, alcove, courtyard or other recessed area. The vent can not terminate below grade. The bottom of the vent terminal shall be located at least 12 inches (30cm) above grade. To avoid a blocked vent condition, keep the vent cap clear of snow, ice, leaves, debris, etc. Flue gases will form a white plume in winter. Plume could obstruct window view. Flue gas condensate can freeze on exterior surfaces or on the vent cap. Frozen condensate on the vent cap can result in a blocked vent condition. Flue gas condensate can cause discoloration of exterior building surfaces. Adjacent brick or masonry surfaces should be protected with a rust resistant sheet metal plate. A masonry chimney must be properly sized for the installation of a high efficiency gas fired appliance. Venting of a high efficiency appliance into a cold or oversized masonry chimney can result in operational and safety problems. Exterior masonry chimneys, with one or more sides exposed to cold outdoor temperatures, are more likely to have venting problems. The temperature of the flue gases from a high efficiency appliance may not be able to sufficiently heat the masonry structure of the chimney to generate proper draft. This will result in condensing of flue gases, damage the masonry flue/tile, insufficient draft and possible spillage of flue gases into an occupied living space. Carefully inspect all chimney systems before installation. If there is any doubt about the sizing or condition of a masonry chimney, it must be relined with a properly sized and approved chimney liner system. Inspection of a Masonry Chimney A masonry chimney must be carefully inspected to determine its suitability for the venting of flue gases. A clay tile lined chimney must be structurally sound, straight and free of misaligned tile, gaps between liner sections, missing sections of liner or any signs of condensate drainage at the breaching or clean out. If there is any doubt about the condition of a masonry chimney, it must be relined. An unlined masonry chimney must not be used to vent flue gases from this high efficiency appliance. An unlined chimney must be relined with an approved chimney liner system when a new appliance is being attached to it. Metallic liner systems (Type B doublewall, flexible or rigid metallic liners) are recommended. Consult with local code officials to determine code requirements or the advisability of using or relining a masonry chimney. This appliance is NOT approved for sidewall venting with the negative draft venting system as shipped from the factory. An induced draft fan MUST be used if the installation requires that the flue gases be vented out a sidewall. A properly sized and installed induced draft fan may also be used to vent the flue gases vertically if required by jobsite restrictions. The induced draft fan must be listed by a nationally recognized test agency, be properly sized and installed per the recommendations of the induced draft fan manufacturer and meet local code requirements. Use care to ensure that the mechanically supplied draft does not exceed the range of a negative IMPORTANT: Examine the venting system at least once a year. Check all joints and vent pipe connections for tightness. Also check for corrosion or deterioration. Immediately correct any problems observed in the venting system. MASONRY CHIMNEY INSTALLATION SIDEWALL VENTING Sidewall Venting with an Induced Draft Fan FIG. 15 08/01/17 11 0.02 to 0.05 inches water to ensure proper operation. If draft exceeds the specified range, the fan must be adjusted or the installation of a barometric damper in the flue may be required to properly control draft. An induced draft fan MUST be interlocked into the appliances control circuit to start when the appliance calls for heat. The induced draft fan MUST also be equipped with a proving switch, properly interlocked into the appliances control circuit to prove fan operation before the main burners are allowed to fire. A vertical or sidewall vent termination for an induced draft fan MUST be installed per the recommendations of the fan manufacturer and provide proper clearances from any combustion or ventilation openings, windows, doors or other openings into the building. All induced draft fan installations must comply with local code requirements. Consult factory for kits available. This heating boiler is design certified for use with the automatic vent damper, part number printed on the boilers rating plate. A vent damper must be installed on all residential heating boilers with inputs of less than 300,000 Btu/hr to comply with minimum efficiency requirements. A vent damper is factory supplied with residential heating boilers with inputs of 45,000 thru 270,000 Btu/hr. A vent damper is optional on heating boilers with inputs of 315,000 and 360,000 Btu/hr. A vent damper is also available as an option on water heater models with inputs of 90,000 thru 360,000 Btu/hr. The vent damper is a useful tool for saving energy when installed inside the building envelope where air can circulate freely around the appliance. The vent damper will not save as much, if any, energy if it is installed in locations such as: - Closet with solid, rather than louvered doors - Outdoors -Unheated garage -Attic -Crawlspace -Mechanical room that is vented outdoors FOR INSTALLATION AND MAINTENANCE ON THE VENT DAMPER, REFER TO THE INSTRUCTIONS SUPPLIED WITH THE VENT DAMPER. Residential heating boilers with inputs of less than 300,000 Btu/hr must have the vent damper properly installed and the wire harness plugged into the terminal on the side of the control panel to allow the boiler to function. Larger input heating boilers and water heaters will have a plug installed in the damper terminal to allow operation without a damper. Remove damper plug from terminal to connect an optional vent damper wire harness. Damper plug MUST be in place if an optional vent damper is not used on water heaters and larger input heating boilers. Install the vent damper to service only the single appliance for which it is intended. If improperly installed, a hazardous condition such as an explosion or carbon monoxide poisoning could result. The damper position indicator must be in a visible location with access for service following installation. The damper must be in open position when appliance main burners are operating. THE PART NUMBER FOR THE AUTOMATIC VENT DAMPER REQUIRED ON THIS HEATING BOILER IS PRINTED ON THE RATING PLATE. DAMPER REGULATIONS PER THE LATEST EDITION OF ANSI Z21.66. AUTOMATIC VENT DAMPER FIG. 16 CAUTION:  Do not install the vent damper within 6" (152 mm) of combustible materials. Automatic Vent Damper 08/01/17 12 . Verify that the appliance is supplied with the type gas specified on the rating plate. This appliance is orificed for operation up to 2000 feet altitude. The appliance will be derated 4% per 1000 feet above 2000 feet elevation. Consult the factory for installations above 2000 feet elevation. Field conversions for operation at high altitude must be performed by factory authorized personnel only. The appliance will be marked to indicate suitability for high altitude operation. INLET PRESSURE: Measured at the inlet pressure tap located upstream of the combination gas valve(s). Nat. Gas LPG Max.(Inches-Water Column) 10.5"w.c. 13"w.c. Min. (Inches-Water column) 5"w.c. 11"w.c. Maximum inlet gas pressure must not exceed the value specified. Minimum value listed is for the purposes of input adjustment. MANIFOLD PRESSURE: Measured at the pressure tap on the downstream side of the combination gas valve(s). The gas regulator on the appliances combination gas valve(s) is adjustable to supply proper manifold pressure for normal operation. If adjustment of regulator pressure is required, see Manifold Adjustment Procedure. Do not increase regulator pressure beyond specified pressure setting. 1. The appliance must be disconnected from the gas supply piping system during any pressure testing of that system at a test pressure in excess of 1/2 PSIG (3.5kPa). 2. The appliance must be isolated from the gas supply piping system by closing a manual shutoff valve during any pressure testing of the gas supply piping system at test pressures equal to or less than 1/2 PSIG (3.5kPa). 3. The appliance and its gas connection must be leak-tested before placing it in operation. FIG. 17 CAUTION:  An appliance which is shut down or will not operate may experience freezing due to convective air flow down the flue pipe connected to the unit. Proper freeze protection must be provided, see Freeze Protection Section. Vent damper must be installed directly on the flue outlet located on the top of the draft hood (see Figure 17). Do not alter the wire harness supplied with the vent damper. Follow the instructions supplied with the vent damper. WARNING: GAS SUPPLY TABLE - D SUPPLY PRESSURE GAS PRESSURE TEST TABLE - E MANIFOLD PRESSURE BTU/hr Regulator Settings Input Gas Natural Gas L.P. 45,000 3.5" 10" 75,000 2.3" 6.9" 90,000 - 180,000 3.5" 10" 199,000 2.7" 7.7" 225,000 - 500,000 3.5" 10" 08/01/17 13 1. Safe operation of the appliance requires properly sized gas supply piping. See data in Table F. 2. Gas pipe size may be larger than appliance gas connection. 3. Installation of a union is suggested for ease of service. 4. Install a manual main gas shutoff valve, outside of the appliance gas connection and before the gas valve or manifold connection, when local codes require. 5. A trap (drip leg) MUST be provided in the inlet of the gas connection to the appliance. 6. The combination gas valve has an integral vent limiting device and does not require venting to atmosphere, outside the building. 7. Optional gas controls may require routing of bleeds and vents to the atmosphere, outside the building when required by local codes. GAS CONNECTION TABLE - F SUGGESTED GAS PIPE SIZE SINGLE APPLIANCE INSTALLATIONS Btu/hr DISTANCE FROM METER INPUT 0-50' 51'-100' 101'-200' 201'-300' 301'-500' 45,000 1/2" 1/2" 3/4" 1" 1 1/4" 75,000 1/2" 3/4" 1" 1 1/4" 1 1/4" 90,000 1/2" 3/4" 1" 1 1/4" 1 1/4" 135,000 3/4" 1" 1 1/4" 1 1/4" 1 1/2" 180,000 1" 1" 1 1/4" 1 1/2" 1 1/2" 199,000 1" 1" 1 1/4" 1 1/2" 2" 225,000 1" 1 1/4" 1 1/4" 1 1/2" 2" 270,000 1" 1 1/4" 1 1/4" 1 1/2" 2" 315,000 1 1/4" 1 1/2" 1 1/2" 1 1/2" 2" 360,000 1 1/4" 1 1/2" 2" 2" 2 1/2" 399,000 1 1/4" 1 1/2" 2" 2" 2 1/2" 500,000 1 1/4" 1 1/2" 2" 2" 2 1/2" For each elbow or tee, add equivalent straight pipe to total length from Table G. TABLE - G FITTINGS TO EQUIVALENT STRAIGHT PIPE Diameter Pipe (inches) 3/4" 1" 1 1/4" 1 1/2" 2" 3" 4" 5" Equivalent length of Straight Pipe (feet) 2' 2' 3' 4' 5' 10' 14' 20' 08/01/17 14 All gas connections must be made with pipe joint compound resistant to the action of liquefied petroleum and natural gas. All piping must comply with local codes. Tubing installations must comply with approved standards and practices. Install Piping to Control 1. The gas line should be a separate line direct from the meter unless the existing gas line is of sufficient capacity. Verify pipe size with your gas supplier. 2. Use new, properly threaded black iron pipe free from chips. If tubing is used, make sure the ends are cut squared, deburred and clean. All tubing bends must be smooth and without deformation. Avoid flexible gas connections. Internal diameter of flexible lines may not provide proper volume of gas. 3. Run pipe or tubing to the gas valve or manifold inlet. If tubing is used, obtain a tube to pipe coupling to connect the tubing to the gas valve or manifold inlet. TABLE- H MULTIPLE APPLIANCE INSTALLATIONS GAS PIPING SIZE CHART Length of Pipe in Straight Feet 10 20 30 40 50 60 70 80 90 100 125 150 175 200 3/4 369 256 205 174 155 141 128 121 113 106 95 86 79 74 1 697 477 384 328 292 267 246 226 210 200 179 164 149 138 1 1/4 1,400 974 789 677 595 543 502 472 441 410 369 333 308 287 1 1/2 2,150 1,500 1,210 1,020 923 830 769 707 666 636 564 513 472 441 2 4,100 2,820 2,260 1,950 1,720 1,560 1,440 1,330 1,250 1,180 1,100 974 871 820 2 1/2 6,460 4,460 3,610 3,100 2,720 2,460 2,310 2,100 2,000 1,900 1,700 1,540 1,400 1,300 3 11,200 7,900 6,400 5,400 4,870 4,410 4,000 3,800 3,540 3,300 3,000 2,720 2,500 2,340 4 23,500 16,100 13,100 11,100 10,000 9,000 8,300 7,690 7,380 6,870 6,150 5,640 5,130 4,720 Nominal Iron Pipe Size, Inches Maximum Capacity of Pipe in Thousands of BTUs per hour for gas pressures of 14 Inches Water Column (0.5 PSIG) or less and a pressure drop of 0.5 Inch Water Column (Based on the calorific value of Natural Gas, 1025 Btu/ft3 @ 0.60 Specific Gravity) GAS PIPING FIG. 18 Gas Line Connection Gas Cock Sediment Trap 08/01/17 15 4. Install a sediment trap in the supply line to the gas valve or manifold assembly (see Figure 18). 5. Thread pipe the proper amount for insertion into gas valve or manifold inlet as shown in Table-I. DO NOT THREAD PIPE TOO FAR. Valve distortion or malfunction may result if the pipe is inserted too deeply into the gas valve. TABLE - I LENGTH OF STANDARD NPT PIPE THREADS (Inches) Pipe Size Effective Length of Thread Overall Length of Thread 1/2" 1/2" 3/4" 3/4" 9/16" 13/16" 1" 9/16" 1" 6. Apply a moderate amount of good quality pipe compound (DO NOT use Teflon tape) to pipe only, leaving two end threads bare. 7. Remove seal over gas valve or manifold inlet. 8. Connect pipe to gas valve or manifold inlet. Use wrench to square ends of the gas valve. 9. For L.P. gas, consult your L.P. gas supplier for expert installation. 1. Turn the power OFF at the main disconnect switch. 2. Turn gas valve control knob to PILOT position on standing pilot models. Ensure that the standing pilot remains on. If the pilot goes out, follow the Lighting Instructions for standing pilot models to light the pilot. Turn gas valve control knob to OFF position on spark ignition models. 3. Remove the 1/8" hex plug located on the outlet side of the gas valve and install a fitting suitable to connect to a manometer or magnahelic gauge. See Figure 20. Minimum range of scale should be up to 5" w.c. for Natural gas models and 10" w.c. for L.P. gas models. 4. The 399,000 and 500,000 Btu/hr models will have two gas valves with a pressure regulator on each valve. Repeat the following adjustment procedure to set the manifold pressure on each gas valve. The manifold pressure for each valve should set at 3.5" w.c. for Natural gas and 10" w.c. for L.P. gas. 5. Remove the pressure regulator adjustment cap screw on the gas valve. See Figures 26, 27 and 28 for location. 6. Turn the power ON at the main disconnect switch. IMPORTANT: Upon completion of any piping connections to the gas system, leak test all gas connections with a soap solution while system is under pressure. Immediately repair any leak found in the gas train or related components. Do Not operate an appliance with a leak in the gas train, valves or related piping. GAS MANIFOLD PRESSURE ADJUSTMENT PROCEDURE APPLY WRENCH FROM TOP OR BOTTOM OF CONTROL TO EITHER SHADED AREA FIG. 19 Gas Valve FIG.20 Manifold Pressure Adjustment 08/01/17 16 7. Turn the gas valve control knob to the ON posi- tion. 8. Set the thermostat(s) to call for heat. 9. Observe gas regulator pressure when all burners are firing. See Table E, Manifold Pressure for proper regulator pressure settings. 10. If adjustment is necessary, turn regulator adjustment screw clockwise to raise regulator gas pressure, counterclockwise to lower gas pressure to proper setting. Note: Adjustment fitting is plastic and may require slightly greater turning force than a metal fitting. 11. Turn the power OFF at the main disconnect switch. 12. Turn gas valve control knob to PILOT position on standing pilot models. Turn gas valve control knob to OFF position on spark ignition models. 13. Remove fitting from the gas valve and replace the 1/8" hex plug that was previously removed and tighten. 14. Repeat the adjustment procedure for the second gas valve on 399,000 and 500,000 Btu/hr models. 15. Turn the gas valve control knob(s) to the ON position. 16. Turn the power ON at the main disconnect switch. The appliance is now ready to operate. If manifold pressure cannot be properly adjusted, use the following procedure to check gas supply pressure with a manometer connected to the inlet pressure tap on the gas control. 1. Turn the power OFF at the main disconnect switch. 2. Turn the gas valve control knob(s) to the OFF position. 3. The 399,000 and 500,000 Btu/hr models will have two gas valves. Turn the gas valve control knob on each valve to the OFF position. 4. Shut off the gas supply at the manual valve in the gas piping to the appliance. If fuel supply is L.P. gas, shut off the gas supply at the tank. 5. Remove the 1/8" hex plug, located on the inlet side of the gas valve and install a fitting suitable to connect to a manometer or magnahelic gauge. On two gas valve models, remove the hex plug from the gas valve closest to the gas supply connection. Range of scale should be 14" w.c. or greater to check inlet pressure. 5. Turn on the gas supply at the manual valve, turn on L.P. gas at the tank if required. 6. Turn the power ON at the main disconnect switch. 7. Turn the gas valve control knob to the PILOT position on the standing pilot models. Follow the Lighting Instructions for standing pilot models to light the pilot. Turn the gas valve control knob NOTE: Do not increase regulator pressure beyond specified pressure setting. CHECKING GAS SUPPLY PRESSURE Gas Valve Gas Supply Pressure FIG. 21 08/01/17 17 to the ON position when the pilot is established. Turn the gas valve control knob(s) to the ON position on spark ignition models. . 8. Set the thermostat(s) to call for heat. 9. Observe the gas supply pressure with all burners firing. Ensure inlet pressure is within specified range. Check gas supply pressure with all other gas fired appliances in operation to ensure proper gas volume during periods of peak gas usage. Minimum and Maximum gas supply pressures are: Natural Gas L.P. Gas Max. (Inches-Water 10.5" w.c. 13" w.c. Column) Min. (Inches-Water 5.0" w.c. 11" w.c. Column) 10. If gas pressure is out of range, contact gas utility, gas supplier, qualified installer or service agency to determine necessary steps to provide proper gas pressure to the control. 11. If the gas supply pressure is within the specified range, proceed with the following steps to return the appliance to service. 12. Turn the power OFF at the main disconnect switch. 13. Turn the gas valve control knob to the PILOT posi- tion on the standing pilot models. Turn the gas valve control knob(s) to the OFF position on spark igni- tion models. 14. Shut off the gas supply at the manual valve in the gas piping to the appliance. If fuel supply is L.P. gas, shut off the gas supply at the tank. 15. Remove the manometer and related fittings from the inlet side of the gas valve, replace 1/8" hex plug in the gas valve. 16. Turn on the gas supply at the manual valve, turn on the L.P. gas at the tank if required. 17. Turn the power ON at the main disconnect switch. 18. Turn the gas valve control knob(s) to the ON position. If the pilot is not burning, follow the Lighting Instructions for standing pilot models to light the pilot. Spark ignition models will automat- ically light the pilot on a call for heat. 19. Set the thermostat(s) to call for heat. The appliance is now ready to operate. Check burner performance by cycling the system while you observe burner response. Burners should ignite promptly. Flame pattern should be stable, see Maintenance-Normal Flame Pattern. Turn system off and allow burners to cool, then cycle burners again to ensure proper ignition and flame characteristics. Inlet and Outlet Connections Heating boilers with inputs from 45,000 to 180,000 Btu/hr have 1 1/4" NPT threaded water connections for inlet and outlet. Heating boilers with inputs from 225,000 to 500,000 Btu/hr have 1 1/2" NPT threaded flange water connections for inlet and outlet. All water heaters and hot water supply boilers are supplied with 1 1/2" NPT threaded flange water connections. For ease of service, install unions on inlet and outlet of the header. The connection marked Inlet on the header should be used for return from the system. The connection marked Outlet is to be connected to the supply side of the system. WATER CONNECTIONS FIG. 22 IMPORTANT: Upon completion of any testing on the gas system, leak test all gas connections with a soap solution while main burners are operating. Immediately repair any leak found in the gas train or related components. Do Not operate an appliance with a leak in the gas train, valves or related piping. Inlet Outlet 08/01/17 18 REVERSING THE HEAT EXCHANGER WATER CONNECTIONS a. Turn OFF power at the main disconnect switch and disconnect power wire from control panel. b. Turn OFF the external main manual gas shutoff valve. c. Disconnect water supply and return piping from heat exchanger. d. Remove temperature sensors and pressure gauge from front header. e. Remove electrical wiring from combination gas valve(s) and spark igniter (if equipped). Mark wires for proper reassembly. f. Loosen mounting screws and remove control panel. g. Loosen mounting screws from front jacket panels and remove. h. Remove heat exchanger by sliding out toward front of the appliance. Use caution to prevent damage to burners, refractory, pilot, spark igniter (if equipped) or wiring. I. Turn heat exchanger so inlet/outlet header is on the right and slide back into unit. Ensure that V baffles are in place on top of the finned tubes and heat exchanger is properly positioned. j. Reinstall front jacket panels and tighten screws. k. Install water piping to header of reversed heat exchanger. Ensure that the relief valve is installed in the outlet from the heat exchanger. Check water piping for leaks. l. Install control panel and reconnect wiring to gas valve(s), spark igniter (if equipped) and controls. m. Install temperature sensors and pressure gauge in front header. The operating thermostat(s) is installed in the inlet side of the header and the high limit is installed in the outlet side of the header. n. Reconnect electric supply to control panel. Ensure all wiring is properly reconnected to the controls. Turn on power at the main disconnect switch. o. Turn ON external main manual gas supply. Use a soap solution to test for leaks on any gas line connections that were loosened or disconnected while reversing the heat exchanger. p. Cycle the burners on and check for proper operation. FIG. 23 NOTE: The heat exchanger is reversible from the left to right side. Reversing of the heat exchanger should only be performed by a qualified installer, service agency or the gas supplier. 08/01/17 19 A water flow switch is available as a factory supplied option on all heating boilers, hot water supply boilers and water heaters. The flow switch should be wired in series with the 24 VAC power to the gas valve (red wire) on standing pilot models and in series with the 24 VAC power to the ignition module (purple wire to 24V terminal on module) on intermittent pilot models. This wiring connection installs the flow switch in the 24 VAC safety circuit to prove water flow before main burner ignition. A flow switch installed with the factory supplied minimum adjustment setting requires a specif- ic minimum flow to make the switch and start burner operation. The minimum flow requirement to actuate the switch is specified in Table J. The flow rate required is a function of the diameter of pipe and tee used for installation. Ensure that the pump installed on the boiler or water heater will supply adequate flow to make the flow switch contacts and operate the boiler. A water flow switch meets most code requirements for a low-water cut off device on boilers requiring forced circulation for operation. TABLE J MINIMUM FLOW RATE REQUIRED TO ACTUATE FLOW SWITCH Pipe Size GPM Flow Rate 1 1/4 9.8 1 1/2 12.7 A hot water boiler installed above radiation level must be provided with a low water cutoff device either as part of the unit or installed at the time the boiler is installed. An electronic or float type low water cutoff is available as a factory supplied option on all units. Low water cutoffs should be inspected every six months, including flushing of float types. This appliance is supplied with a relief valve(s) sized in accordance with ASME Boiler and Pressure Vessel Code, Section IV (Heating Boilers). The relief valve(s) is mounted in the vertical position and installed in a tee immediately downstream of the heat exchanger hot water outlet. No valve is to be placed between the relief valve and the heat exchanger outlet. To prevent water damage, the discharge from the relief valve shall be piped to a suitable floor drain for disposal when relief occurs. No reducing couplings or other restrictions shall be installed in the discharge line. The discharge line shall allow complete drainage of the valve and line. Relief valves should be manually operated at least once a year. RELIEF VALVE CAUTION:  Avoid contact with hot discharge water. FIG.24 WATER FLOW SWITCH (IF EQUIPPED) FIG.25 LOW WATER CUTOFF (IF EQUIPPED) Relief Valve Flow Switch 08/01/17 20 Each unit has a combination gas valve(s) to control the gas supply to the burners. The 399,000 and 500,000 Btu/hr models have two combination gas valves to supply gas to the burners. Two stage burner operation (M-9) is available as an option on intermittent pilot models. A two stage gas valve is used on models with inputs of 90,000 thru 360,000 Btu/hr. The 399,000 and 500,000 Btu/hr models achieve two stage burner firing by staging the operation of each combination gas valve. The combination valve consists of a gas regulator and two valve seats to meet the requirements for redundant gas valves. The valve has a gas control knob that must remain in the open position at all times when the appliance is in service. Each gas valve has pressure taps located on the inlet and outlet sides. Manifold pressure is adjusted using the regulator located on the valve. The manifold pressure is preset at the factory and adjustment is not usually required. If the manifold pressure is to be adjusted, follow the Gas Manifold Pressure Adjustment Procedure for proper adjustment. Venting of Combination Gas Valves The combination gas valve regulator used on all models is equipped with an integral vent limiting orifice. The vent limiter ensures that the volume of gas emitted from the valve does not exceed the maximum safe leakage rate allowed by agency requirements. Combination gas valve/regulators equipped with integral vent limiters are not required to have vent or relief lines piped to the outdoors. A dust cap is provided at the vent termination point on the valve to prevent blockage of the vent limiter by foreign material. The combination gas valve regulator with an integral vent limiter complies with the safety code requirements of CSD-1, CF-190(a) as shipped from the manufacturer without the installation of additional vent lines. OPTIONAL TWO STAGE BURNER CONTROL SYSTEM (M-9) The 90,000 thru 500,000 Btu/hr models with intermittent pilot may be optionally equipped with a two stage burner control system (M-9). The 90,000 thru 360,000 Btu/hr models will be equipped with a two stage gas valve to control high/low burner operation. The 399,000 and 500,000 Btu/hr models achieve two stage burner firing by staging the operation of the two combination gas valves. The optional M-9 control system is equipped with two operating temperature controls to allow each burner stage to fire at a different temperature set point. Stage one (Low Fire) must fire before stage two (High Fire) will function. Set the Low Fire operator at the desired system set point, set the High Fire operator at a COMBINATION GAS VALVES FIG.26 FIG. 28 FIG.27 Inlet Pressure Tap Red Reset Button Gas Control Knob Pilot Outlet Wiring Terminals Regulator Outlet Pressure Tap F-1 Gas Valve Models 045–135 F-9 Gas Valve Models 045–500 Inlet Pressure Tap Gas Control Knob Pilot Outlet Wiring Terminals Regulator Outlet Pressure Tap Inlet Pressure Tap Gas Control Knob Pilot Outlet Wiring Terminals Regulator Outlet Pressure Tap M-9 Gas Valve Models 180–360 08/01/17 21 lower setting, approximately 5-15 degrees lower, for staged burner operation. Two stage burner control systems (M-9) are recommended for application on heating boilers only. ELECTRICAL CONNECTIONS This appliance is wired for 120 VAC service. The appliance, when installed, must be electrically grounded in accordance with the requirements of the authority having jurisdiction or in the absence of such requirements, with the latest edition of the National Electrical Code ANSI/NFPA No. 70. When the unit is installed in Canada, it must conform to the CAE C22.1, Canadian Electrical Code, Part 1 and/or local Electrical Codes. 1. All wiring between the appliance and field installed devices shall be made with type T wire [63° F(35° C) rise]. 2. Line voltage wire exterior to the appliance must be enclosed in approved conduit or approved metal clad cable. 3. The pump must run continuously when the appliance is being fired. 4. To avoid serious damage, DO NOT energize the appliance until the system is full of water. Serious damage may result. 5. Provide the unit with proper overload protection. 6. Install a wall thermostat on the inside wall. DO NOT install thermostat in an area affected by drafts, sunlight, light fixtures, hot or cold water pipes or near a fireplace. See Terminal Strip Con- nection of a Room Thermostat for proper wiring connection. TABLE - K AMP DRAW DATA 45,000 thru 500,000 Btu/hr Models MAXIMUM FIRING TOTALAMPS CONTROLS @ 120 VAC F-1 Standing Pilot (Single Stage 45,000-270,000 Btu/hr) 1.20 F-9 Intermittent Pilot (Single Stage 45,000-360,000 Btu/hr) 1.15 F-9 Intermittent Pilot (Single Stage/2 valves 399,000- 500,000 Btu/hr) 1.65 M-9 Intermittent Pilot (Two Stage Valve 90,000-360,000 Btu/hr) 1.20 M-9 Intermittent Pilot(Two Stage/2 valves 399,000-500,000 Btu/hr) 1.65 Pump Wiring for a Heating Boiler The heating boiler circulating pump must be purchased locally. The boilers internal pump control relay may be used to cycle the pump. The maximum current draw for the pump switched by this relay must not exceed 12 AMPS at 120 VAC, 6 AMPS at 208/240/277 VAC or 3 AMPS at 480 VAC. The current draw for a field installed 120 VAC pump may be added to the boilers current draw to determine the minimum wire size for 120 volt service if a single power supply is provided for the boiler controls and pump. STANDING PILOT SYSTEM - F1 CONTROL PANEL HIGH LIMIT OPERATOR TERMINAL BOARD FIG. 29 TRANSFORMER 08/01/17 22 OPERATOR TRANSFORMER MV MV/PV PV GND 24V 24V TH-W SPARK 1 2 3 4 5 6 7 8 9 HIGH LIMIT TERMINAL BOARD TEMPERATURE ADJUSTMENT Operating Temperature Control An adjustable immersion operating control is located in the control panel. F-1 and F-9 control systems use a single operating control, M-9 control systems use two operating controls (see Two Stage Burner Control System for operation and setup). The operating control uses a remote sensing bulb mounted in the inlet side of the header. Turn the control set point dial to adjust the desired operating water temperature of the appliance. High Water Temperature Limit Controls The appliance may be supplied with either an adjustable or fixed setting high water temperature limit control based on the units application, ignition controls or as a specified optional control. The sensing bulb for the high water temperature limit control is mounted in the outlet side of the header. Adjustable High Water Temperature Limit Control The appliance may be supplied with an adjustable setting, auto-reset high water temperature limit control(s) located in the front control panel, beside the temperature control. The setting of this control(s) limits maximum discharge water temperature. An adjustable high water temperature limit control is typically set 40°F (22°C) higher than the set point of the operating temper- ature control or at the limits maximum setting. If water temperature exceeds the set point, the limit will break the control circuit and shut down the appliance. The limit control will only be reset after the water temperature has cooled below the set point of the limit. The high water temperature limit sensor is mounted in the outlet side of the front header. Manual Reset High Water Temperature Limit Control (Optional) The appliance may be supplied with a fixed setting, manual reset high water temperature limit control. This manual reset temperature limit control has a fixed limit setting of 230°F (110°C). If water temperature exceeds this set point, the limit will break the control circuit and shut down the unit. The limit control can only be reset after the water temperature has cooled below the set point of the limit. Reset of the limit control is accomplished by pushing the Red Reset Button located on the bottom side of the control panel. A label on the control panel indicates the exact location of the reset button. BLOCKED VENT AND FLAME ROLL-OUT SYSTEM (Heating Boilers Only) NOTE:The limit control will not reset until the water temperature has dropped below the set point of the high limit. FIG. 31 INTERMITTENT PILOT SYSTEM - F9 CONTROL PANEL IGNITION MODULE BLOCKED VENT SWITCH 45,000–90,000 BTU MODELS FIG. 30 Draft Hood Spill Switch 08/01/17 23 The 45,000 thru 270,000 Btu/hr Heating Boilers are equipped with a manual reset blocked vent and flame roll-out system. Temperature switches are located on the front of the burner tray and/or in the relief opening of the boilers built-in draft hood. Each switch has a red reset button. In the event the system has actuated to shut off the main burner gas supply, wait for the boiler to cool, then press the red reset to return the boiler to operation. Operation of a blocked vent and/or flame roll-out switch usually indicates a problem with the venting system, obstruction of the heat exchanger flue gas passageway and/or a combustion air supply problem. The cause for operation of the blocked vent and/or flame roll-out switch must be determined and corrected. If the boiler can not be restored to normal operation, contact a qualified service installer, service agency or the gas supplier. INITIAL START-UP Follow instructions on the label applied to the top of the appliance. A. Pump Operation - MOST IMPORTANT - This appliance is designed for continuous pump operation when the burners are firing. A heating boiler may cycle the pump by using the pump control relay located in the control panel (see Circulator Pump Operation-Heating Boilers). A water heater or hot water supply boiler cycles the pump by using the pump delay. Pump delay controls are standard on water heaters. B. Location - The appliance should be located within a room having a temperature safely above freezing [32°F(0°C)]. C. Shutdown and Draining - If, for any reason, the appliance is shut off, the following precautionary measures must be taken: 1. Shut off gas supply, 2. Shut off water supply. 3. Shut off electrical supply. 4. Drain the heat exchanger completely. Remove one 3/8" NPT plug or bulb well from the inlet side and one from the outlet side of the front header of the heat exchanger. Remove the 3/4" NPT drain plugs located on the rear header. Blow all water out of the heat exchanger. 5. Drain the pump (see Pump Maintenance). FIG. 32 FIG. 33 FIG. 34 FLAME ROLL-OUT SWITCH 45,000 BTU MODELS FLAME ROLL-OUT SWITCH 90,000–270,000 BTU MODELS Burner Burner Tray Roll-out Switch Burner Burners Roll-out Switch HEAT EXCHANGER 08/01/17 24 PRE-START CHECKLIST 1. Inspect the burners to be sure they are properly aligned. 2. Inspect the pilot gas line, thermocouple leads, ignition leads and wire connections to gas valve to be sure none were damaged during shipment. 3. Check to ensure that gas connections have been made properly and the gas line is purged of air. 4. Check to ensure that water connections are tight and the appliance and piping system have been properly filled. 5. Ensure that discharge from the relief valve has been piped to a floor drain. 6. Verify that properly sized combustion and ventilation air openings are provided and not obstructed in any way. 7. Check carefully for gas leaks. 8. Read the appliances safety warnings, lighting instructions and check out procedure carefully, before firing the system. LIGHTING INSTRUCTIONS FOR STANDING PILOT MODELS (F-1) MODELS 45,000 THRU 270,000 Btu/hr INPUT FOR YOUR SAFETY READ BEFORE OPERATING A. This appliance has a pilot which must be ignit- ed by hand. When lighting the pilot, follow these instructions exactly. B. BEFORE OPERATING, smell around the appliance area for gas. Be sure to smell next to the floor because some gas is heavier than air and will settle to the floor. WHAT TO DO IF YOU SMELL GAS Do not try to light any appliance. Do not touch any electric switch; do not use any phone in your building. Immediately call your gas supplier from a neighbors phone. Follow the gas suppliers instructions. If you cannot reach your gas supplier, call the fire department. C. Use only your hand to push in or turn the gas control knob. Never use tools. If the knob will not turn by hand, dont try to repair it, call a qualified service technician. Force or attempted repair may result in a fire or explosion. D. Do not use this appliance if any part has been under water. Immediately call a qualified service technician to inspect the appliance. The possible damage to a flooded appliance can be extensive and present numerous safety hazards. Any appliance that has been under water must be replaced. LIGHTING INSTRUCTIONS 1. STOP! Read the safety information above. 2. Set the thermostat to the lowest setting. 3. Turn off all electrical power to the appliance. 4. Turn the gas control knob on the gas valve clockwise to the OFF position. If you do not follow these instructions exactly, a fire or explosion may result causing property damage, personal injury or loss of life. WARNING: 08/01/17 25 5. Wait five (5) minutes to clear out any gas, then smell for gas, including near the floor. If you smell gas, STOP! Follow B in the safety information. If you dont smell gas go on to the next step. 6. Find the pilot - Follow the metal tube from the gas valve to the pilot. The pilot is located on the right side of a burner approximately centered in the burner tray. 7. Turn the control knob on the gas valve counterclockwise to the PILOT position. 8. Push down and hold in the red button on the gas valve. This should start gas flow to the pilot. Immediately light the pilot with a match. Use the loop end of the wire lighting wand, shipped with the instruction package, to hold the match and reach the pilot. An access slot is provided in the lower front jacket panel, beside the burner, to insert the lighting wand and match to the pilot. Continue to hold the red button in for about one (1) minute after the pilot is lit. Release button and it will pop back up. Pilot should remain lit. If it goes out, repeat steps 4 through 8. If red button does not pop up when released, stop and immediately call your gas supplier. If the pilot will not stay lit after several tries, turn the gas control to OFF and call your service technician or gas supplier. 9. Turn the gas control knob on the gas valve counterclockwise to the ON position. 10. Turn on all electric power to the appliance. 11. Set the thermostat to the desired setting. FIG. 36 FIG. 37 FIG. 35 PILOT LOCATION USING LIGHTING WAND TO LIGHT STANDING PILOT MAIN BURNER MAIN BURNER TOP SIDE OUTLET F-1 GAS VALVE - MODELS 045-135 ALSO SEE FIG. 26 08/01/17 26 TO TURN OFF GAS TO APPLIANCE 1. Set the thermostat to the lowest setting. 2. Turn off all electric power to the appliance if service is to be performed. 3. Turn the gas control knob on the gas valve clockwise to the OFF position. Do not force. SAFETY SHUTOFF TEST FOR STANDING PILOT IGNITION SYSTEM 1. With the main burners on and firing, unscrew the thermocouple connection from the gas valve and remove from the fitting. See Figure 29 to locate thermocouple outlet connection on the gas valve. 2. The main gas valve should extinguish the burners immediately after removal of the thermocouple. 3. If burners do not extinguish, immediately follow steps in TO TURN OFF GAS TO APPLIANCE. 4. Immediately call a qualified serviceman or install- er to repair an ignition system that fails to operate properly and shut down the burners. 5. After successful completion of the test, turn the control knob on the gas valve clockwise to the OFF position. Do not force. 6. Carefully reconnect the thermocouple to the gas valve. 7. Follow the Lighting Instructions to relight the pilot and establish normal operation. LIGHTING INSTRUCTIONS FOR SPARK IGNITION PILOT MODELS (F-9/M-9) MODELS 45,000 THRU 500,000 Btu/hr INPUT FOR YOUR SAFETY READ BEFORE OPERATING A. This appliance is equipped with an ignition device which automatically lights the pilot. Do not try to light the pilot by hand. B. BEFORE OPERATING, smell around the appliance area for gas. Be sure to smell next to the floor because some gas is heavier than air and will settle to the floor. NOTE: The information package shipped with the appliance contains a wire lighting wand. The loop end of the wand will hold a match. The wand will extend your reach to the pilot and make lighting the pilot easier. Should overheating occur or the gas fail to shut off, turn off the external manual gas valve to the appliance. WARNING: FIG. 38 If you do not follow these instructions exactly, a fire or explosion may result causing property damage, personal injury or loss of life. WARNING: 1 PILOT WITH THERMOCOUPLE 08/01/17 27 WHAT TO DO IF YOU SMELL GAS Do not try to light any appliance. Do not touch any electric switch; do not use any phone in your building. Immediately call your gas supplier from a neighbors phone. Follow the gas suppliers instructions. If you cannot reach your gas supplier, call the fire department. C. Use only your hand to turn the gas control knob. Never use tools. If the knob will not turn by hand, dont try to repair it, call a qualified service technician. Force or attempted repair may result in a fire or explosion. D. Do not use this appliance if any part has been under water. Immediately call a qualified service technician to inspect the appliance. The possible damage to a flooded boiler can be extensive and present numerous safety hazards. Any appliance that has been under water must be replaced. OPERATING INSTRUCTIONS 1. STOP! Read the safety information above. 2. Set the thermostat(s) to the lowest setting. M-9 (2-stage) models are equipped with two thermostats. 3. Turn off all electrical power to the appliance. 4. This appliance is equipped with an ignition device which automatically lights the pilot. DO NOT try to light the pilot by hand. 5a. 45,000 - 135,000 and 399,000 - 500,000 Btu/hr models, rotate the gas control knob on the gas valve clockwise to the OFF position. 5b. 180,000 - 360,000 Btu/hr models, rotate the gas control knob on the gas valve clockwise to the line on the collar around the knob. Depress the knob and continue rotation to the OFF position. FIG. 39 FIG. 40 TOP SIDE OUTLET F-9 GAS VALVE - MODELS 045-135 ALSO SEE FIG. 27 TOP SIDE OUTLET F-9 GAS VALVE - MODELS 180-500 ALSO SEE FIG. 27 08/01/17 28 6. Wait five (5) minutes to clear out any gas then smell for gas, including near the floor. If you smell gas, STOP! Follow B in the safety information. If you dont smell gas go on to the next step. 7a. 45,000 - 135,000 and 399,000 - 500,000 Btu/hr models, rotate the gas control knob on the gas valve counterclockwise to the ON position. 7b. 180,000 - 360,000 Btu/hr models, rotate the gas control knob on the gas valve counter- clockwise to the line on the collar around the knob. Allow knob to pop up, and continue rotation to the ON position. 8. Turn on all electric power to the appliance. 9. Set the thermostat(s) to the desired setting. M-9 (2-stage) models are equipped with two thermostats. 10. If the appliance will not operate, follow the instructions To Turn Off Gas To Appliance and call your service technician or gas supplier. 1. Set the thermostat(s) to the lowest setting. M-9 (2-stage) models are equipped with two thermostats. 2. Turn off all electric power to the appliance if service is to be performed. 3a. 45,000 - 135,000 and 399,000 - 500,000 Btu/hr models, rotate the gas control knob on the gas valve clockwise to the OFF position. Do not force. 3b. 180,000 - 360,000 Btu/hr models, rotate the gas control knob on the gas valve clockwise to the line on the collar around the knob. Depress the knob and continue rotation to the OFF position. Do not force. SAFETY SHUTOFF TEST FOR SPARK IGNITION PILOT SYSTEM 1. Turn OFF gas supply to the appliance. 2. Turn thermostat(s) to highest setting. 3. Turn electric power ON. 4. Pump relay pulls in to start pump. 5. The ignition will begin sparking at the pilot. 6. The ignition module will lock out after the 90 second trial for ignition period on the 45,000 thru 399,000 Btu/hr models and after the 15 second trial for ignition period on the 500,000 Btu/hr model. 7. Immediately call a qualified serviceman or installer to repair an ignition system that fails to lock out and properly shut down burner operation. 8. After successful completion of the test, readjust thermostat(s) to normal setting. 9. Turn ON gas supply. 10. Turn power OFF then ON to reset ignition module. 11. If ignition system fails to operate properly, repair work must be performed by a qualified serviceman or installer. FIG. 41 Should overheating occur or the gas fail to shut off, turn off the external manual gas valve to the appliance. WARNING: TOP SIDE OUTLET M-9 GAS VALVE ALSO SEE FIG. 28 TO TURN OFF GAS TO APPLIANCE 08/01/17 29 INTERMITTENT PILOT, SPARK IGNITION SYSTEM (F-9/M-9) The ignition module is not repairable. Any modification or repairs will invalidate the warranty and may create hazardous conditions that result in property damage, personal injury, fire, explosion and/or toxic gases. A faulty ignition module must be replaced with a new module. IGNITION and CONTROL TIMINGS F-1 Standing Pilot Models (thermocouple supervised) Pilot Flame Failure Response Time - 180 Seconds Maximum F-9/M-9 Intermittent Spark Ignition Pilot Models Pilot Trial for Ignition Period - 90 Seconds (45,000 thru 399,000 Btu/hr models) Pilot Trial for Ignition Period - 15 Seconds (500,000 Btu/hr models) Pilot Failure Response Time - 0.8 Seconds at less than 1.0 µA flame current Pump Delay Timing - 30 Seconds after burner shutdown FREEZE PROTECTION Proper freeze protection must be provided for applianc- es installed in unheated mechanical rooms or where temperatures may drop to the freezing point or lower. If freeze protection is not provided for the system, a low ambient temperature alarm is recommended for the mechanical room. Damage to the heat exchanger by freezing is non- warrantable. 1. Pump Operation - MOST IMPORTANT - This appliance is designed for continuous pump operation when the burners are firing. If the system pump does not run continuously an additional pump must be installed to provide constant circulation through the appliance. This flow of warm water can help prevent freezing. 2. Location - Heating boilers, hot water supply boilers and water heaters must be located in a room having a temperature safely above freezing [32°F(0°C)]. 3. Caution - A mechanical room operating under a negative pressure may experience a down draft in the flue of an appliance which is not firing. The cold outside air pulled down the flue may freeze a heat exchanger. This condition must be corrected to provide adequate freeze protection. 4. Freeze protection for a heating boiler or hot water supply boiler using an indirect coil can be provided by using hydronic system antifreeze. Follow the manufacturers instructions. DO NOT use undiluted or automotive type antifreeze. 5. A snow screen should be installed to prevent snow and ice accumulation around the appliance venting system in cold climates. 6. Shut-down and Draining - If for any reason, the appliance is to be shut off, the following precautionary measures must be taken: (a) Shut off gas supply. (b) Shut off water supply. (c) Shut off electrical supply. (d) Drain the unit completely. Remove one threaded plug or bulb well from the inlet side of the front header and one from the outlet side of the front header on the heat exchanger. Blow all water out of the heat exchanger. (e) Drain pump and piping. 08/01/17 30 FREEZE PROTECTION FOR A HEATING BOILER SYSTEM (If Required) 1. Use only properly diluted inhibited glycol anti- freeze designed for hydronic systems. Inhibited propylene glycol is recommended for systems where incidental contact with drinking water is possible. 2. A solution of 50% propylene glycol will provide maximum protection of approximately -30°F. 3. Follow the instructions from the glycol antifreeze manufacturer. Quantity of glycol antifreeze required based on total system volume including expansion tank volume. 4. Glycol is more dense than water and changes the viscosity of the system. The addition of glycol will decrease heat transfer and increase frictional loss in the heating boiler and related piping. A larger pump with more capacity may be required to maintain desired flow rates in a glycol system. 5. Local codes may require a back flow preventer or actual disconnect from city water supply when glycol antifreeze is added to the system. WATER TREATMENT In hard water areas, water treatment should be used to reduce the introduction of minerals to the system. Minerals in the water can collect in the heat exchanger tubes and cause noise on operation. Excessive build up of minerals in the heat exchanger can cause a non-warrantable failure. MAINTENANCE The following list contains items that must be checked to ensure safe reliable operation. Verify proper opera- tion after servicing. 1. Examine the venting system at least once a year. Check more often in the first year to determine inspection interval. Check all joints and pipe connections for tightness, corrosion or deterioration. Clean louvers and/or screens in the combustion air intake system as required. Have the entire system, including the venting system, periodically inspected by a qualified service agency. 2. Visually check main burner flames at each start up after long shutdown periods or at least every six months. a. Normal Flame: A normal flame is blue, with slight yellow tips, with a well defined inner cone and no flame lifting. b. Yellow Tip: Yellow tip can be caused by blockage or partial obstruction of air flow to the burner(s). c. Yellow Flames: Yellow flames can be caused by blockage of primary air flow to the burner(s) or excessive gas input. This condition MUST be corrected immediately. d. Lifting Flames: Lifting flames can be caused by over firing the burner(s) or excessive primary air. If improper flame is observed, examine the venting system, ensure proper gas supply and adequate supply of combustion and ventilation air. 3. Combustion Air Adjustment: This appliance uses an atmospheric combustion process. Combustion CAUTION:  DO NOT used undiluted or automotive type antifreeze. CAUTION:  Label all wires prior to disconnection when servicing controls. Wiring errors can cause improper and dangerous operation. The area around the burners is hot and direct contact could result in burns! WARNING: FIG. 42 B C D A 08/01/17 31 air is provided to the burners by the gas injection pressure into the venturi of the burners. The burners do not have an adjustable air shutter. Adequate combustion air must be supplied to the mechanical room to ensure proper burner operation. Check frequently to be sure the flow of combustion and ventilation air to the unit is not obstructed. When the main burners light, observe the burner flame. Flames should be light blue in color with slight yellow tips; flames should be settled on burner head with no lifting when supplied with correct volume of combustion air. 4. Flue Gas Passageways Cleaning Procedures: Any sign of soot around the outer jacket, at the burners or in the areas between the fins on the copper heat exchanger indicates a need for cleaning. The following cleaning procedure must only be performed by a qualified serviceman or installer. Proper service is required to maintain safe operation. Properly installed and adjusted appliances seldom need flue cleaning. All gaskets on disassembled components must be replaced with new gaskets on reassembly. Gasket kits are available from your distributor. BURNER REMOVAL AND CLEANING a. Turn OFF main power to the appliance. b. Turn OFF external manual gas shutoff valve to appliance. c. Disconnect gas supply piping from combination gas valve on 45,000 thru 360,000 Btu/hr models. Disconnect the gas supply man- ifold at the unions on the inlet to each of the two combination gas valves on the 399,000 thru 500,000 Btu/hr models. d. Remove electrical wiring from combination gas valve(s) and spark igniter (if equipped). Mark wires for proper reassembly. e. Remove mounting screws from lower front jacket panel. f. Remove mounting screws from each side of the burner tray and slide the burner tray assembly and lower front jacket panel out towards the front of the unit. Use caution to prevent damage to burners, refractory, pilot or wiring. Note: The ceramic fiber material used in this appliance is an irritant; when handling or replacing the ceramic materials it is advisable that the installer follow these safety guides. REMOVAL OF COMBUSTION CHAMBER LINING OR BASE PANELS: · Avoid breathing dust and contact with skin and eyes. · Use NIOSH certified dust respirator (N95) (http://www.cdc.gov/niosh/hompage.html). · Lightly mist with water (only those areas being handled) the combustion chamber lining or base insulation to prevent airborne fibers. · Remove combustion chamber lining or base insulation from the boiler and place it in a plastic bag for disposal. · Wash potentially contaminated clothes separately from other clothing. Rinse clothes thoroughly. · NIOSH stated First Aid: Eye: Irrigate immediately. Breathing: Fresh air. g. Remove soot from burners with a stiff bristle brush. Dirt may also be removed from burner ports by rinsing the burner thoroughly with water. Drain and dry burners before reinstalling. Damaged burners must be replaced. An appliance installed in a dust or dirt contaminated atmosphere will require cleaning of the burners on a 3 to 6 month schedule or more often, based on severity of contamination. Contaminants can be drawn in with the combustion air. Noncombustible particulate matter such as dust, dirt, concrete dust or dry wall dust can  WWAARRNNIINNGG: The combustion chamber lining in this appliance contains ceramic fiber materials. Ceramic fibers can transform into cristobalite (crystalline silica) when exposed to temperatures above 2192°F (1200°C) dependent upon the length of exposure time.* The International Agency for Research on Cancer (I.A.R.C.) has concluded, "Crystalline silica inhaled in the form of quartz or cristobalite from occupational sources is carcinogenic to humans."** Testing has confirmed that the ceramic fibers in this application do not reach 2192°F (1200°C). *Reference Dyson, D., Butler, M., Hughes, R., Fisher, R., and Hicks, G. The Devitrification of Alumino-silicate Ceramic Fiber Materials - The Kinetics of the Formation of Different Crystalline Phases, Ann. Occup. Hyg. Vol. 41, No. 55, 1997. **Reference I.A.R.C. Monograph 68, June 1997. 08/01/17 32 block burner ports and cause non-warrantable failure. Use extreme care when operating an appliance for temporary heat during new construction. The burners will probably require a thorough cleaning before the appliance is placed in service. h. Check the heat exchanger surface for sooting. The external surfaces of the copper tubes should be free of any soot deposits. (A slight black smudge is normal with some types of gases.) If abnormal soot deposits are present, the heat exchanger must be cleaned and the cause of the soot problem corrected. Proceed as follows: i. Remove gas manifold/burner tray assembly as described in steps a. thru f. in Burner Removal. Disconnect the gas supply piping from the burner manifold on the 399,000 thru 500,000 Btu/hr models. j. Loosen mounting screws and remove front control panel. k. Loosen screws on the upper front jacket panel and remove toward front of the appliance. Use caution to prevent damage to refractory on the doors inner surface. l. Check V baffles on top of the heat exchang- er. Remove and clean if necessary. m. Remove soot from the heat exchanger with a stiff bristle brush. Soot may also be removed from the heat exchanger by washing thoroughly with detergent and water. Remove the heat exchanger before using water for cleaning. Rinse thoroughly and dry before re-installing. Use a vacuum to remove loose soot from surfaces and inner chamber. n. The heat exchanger can be removed by sliding towards the front of the appliance. Once the heat exchanger is removed from the appliance, a garden hose can be used to wash the tubes to ensure that all soot is removed from the heat exchanger surfaces. o. Ensure that all burner ports are cleaned to remove any soot. See Burner Cleaning Procedure. p. Carefully reinstall the heat exchanger, V baffles, jacket panels, burner tray assembly and wires. q. Reassemble all gas and water piping. Test for gas leaks. r. Cycle the appliance and check for proper operation. 5. Water Circulating Pump: Inspect pump every 6 months and oil if required. Use SAE 30 non-detergent oil or lubricant specified by pump manufacturer. 6. Keep appliance area clear and free from combustible materials, gasoline and other flammable vapors and liquids. 7. Check frequently to be sure the flow of combustion and ventilation air to the boiler is not obstructed. 8. Inspection of Heat Exchanger Waterways: Appliances operated in hard water areas should have periodic inspections of the tubes to be sure that no sediment or scale accumulates on the heat transfer surfaces. Inspection plugs are located at both ends of the heat exchanger. Inspection plugs should be removed and tubes inspected at the end of the first 45 days of operation and again at the end of 90 days of operation. If no scale accumulation is observed, inspections can be made at the end of each six months of operation. 9. Pilot Flame Adjustment Procedure - The pilot flame should envelop 3/8" to 1/2" (10 to 13mm) of the tip of the thermocouple, see Figure 43. a. Remove pilot adjustment cover screw on gas valve. See Gas Valve Illustrations in the Lighting Instructions section for location of cover screw. FIG. 43 PILOT FLAME ON THERMOCOUPLE HEAT EXCHANGER CLEANING 08/01/17 33 b. Turn inner adjustment screw clockwise to decrease or counterclockwise to increase pilot flame. c. If difficulty is experienced in adjusting the pilot flame, a tee may be installed in the pilot line from the gas valve to the pilot burner. d. Replace pilot adjustment cover screw on valve. Tighten firmly after adjustment to prevent gas leakage.SYSTE The drawings in this section show typical heating boiler piping installations. Before beginning the installation, consult local codes for specific plumbing requirements. The installation should provide unions and valves at the inlet and outlet of the boiler so it can be isolated for service. The boiler circulating pump, air separator, expansion tank and other components required for proper installation must be purchased locally. An air separation device must be supplied in the installation piping to eliminate trapped air in the system. Locate a system air vent at the highest point in the system. The system must also have a properly sized expansion tank installed. Typically, an air charged diaphragm-type expansion tank is used. The expansion tank must be installed close to the boiler and on the suction side of the system pump to ensure proper operation. Caution: This boiler system should not be operated at less than 12 PSIG. Hot water piping must be supported by suitable hangers or floor stands, NOT by the boiler. Copper pipe systems will be subject to considerable expansion and contraction. Rigid pipe hangers could allow the pipe to slide in the hanger resulting in noise transmitted into the system. Padding is recommended on rigid hangers installed with a copper system. The boiler pressure relief valve must be piped to a suitable floor drain. See the Relief Valve Section in this manual. R CONNECTIONSHEATING BOILERS IMPORTANT: Upon completion of any testing on the gas system, leak test all gas connections with a soap solution while main burners are operating. Immediately repair any leaks found in the gas train or related components. Do Not operate an appliance with a leak in the gas train, valves or related piping. FIG. 44 FIG. 45 CAUTION:  A leak in a boiler system will cause the system to intake fresh water constantly, which will cause the tubes to accumulate a lime/scale build up. This will cause a NON-WARRANTABLE FAILURE. GAS TRAIN 399,000–500,000 Btu/hr MODELS GAS TRAINS 45,000–180,000 Btu/hr MODELS 199,000–360,000 Btu/hr MODELS GAS TRAIN AND CONTROLS PIPING OF THE BOILER SYSTEM 08/01/17 34 ONLY Heating Boilers with inputs of 45,000-180,000 Btu/hr have 1-1/4" NPT inlet and outlet connections, Heating Boilers with inputs of 225,000-500,000 Btu/hr have 1-1/2" NPT inlet and outlet connections. Caution: Field installed reducing bushings may decrease flow re- sulting in boiler noise or flashing to steam. This is a low mass, high efficiency hot water boiler which must have adequate flow for quiet, efficient operation. The boiler circulating pump must be purchased locally. The boiler circulator pump must operate continuously while the boiler is firing. Pump selection is critical to achieve proper operation. A pump should be selected to achieve proper system design water temperature rise. A heat exchanger pressure drop chart (Table L) is provided to assist in proper pump selection. Also provided is a System Temperature Rise Chart (Table N). This table provides GPM and boiler head-loss at various temperature rises for each boiler based on Btu/hr input. Temperature rise is the difference in boiler inlet temperature and boiler outlet temperature while the boiler is firing. Example: The boiler inlet temperature is 160°F and the boiler outlet temperature is 180°F, this means that there is a 20°F temperature rise across the boiler. 1. Maximum operating pressure for the pump must exceed system operating pressure. 2. Maximum water temperature should not exceed nameplate rating. 3. Cast iron circulators may be used for closed loop systems. 4. A properly sized expansion tank must be installed near the boiler and located on the suction side of the pump. The heating boiler circulating pump must be purchased locally. A pump control relay is supplied in the control panel of each heating boiler. External wire leads can be installed to supply power to the pump, allowing the control relay to cycle the pump on each call for heat (see Pump Wiring). Caution: When the power supply for the pump is wired across switching contacts of the pump control relay, the external power leads to the pump may be Hot when the main power switch is ON or when the boiler is calling for heat. The field installed boiler pump using these wire leads must not exceed 12 AMPS at 120 VAC, 6 AMPS at 208/240/277 VAC or 3 AMPS at 480 VAC. As shipped from the factory, this control relay is set to cycle the boiler pump on each call for heat with an external room thermostat installed across terminals R and W on the internal terminal strip. For continuous pump operation, connect the orange jumper on the terminal board between terminals R and A. See wiring diagram shipped with the unit. FIG. 46 HEAT EXCHANGER PRESSURE DROP Pump Relay WATER CONNECTIONS HEATING BOILERS ONLY CIRCULATOR PUMP REQUIREMENTS TABLE - L HEAT EXCHANGER PRESSURE DROP CHART CIRCULATOR PUMP SPECIFICATIONS CIRCULATOR PUMP OPERATION (Heating Boilers Only) 08/01/17 35 PUMP INSTALLATION AND MAINTENANCE: The boiler circulating pump must be purchased locally. For installation and maintenance information on the circulator pump, refer to pump manufacturers instruction package included with the pump. The installer must ensure that the circulating pump installed with the boiler will supply adequate flow without excessive temperature rise. It is recommended that this boiler be installed with a bypass in the piping, a properly sized circulator and piping system. The bypass will help to ensure that the boiler can be sup- plied with adequate water flow. A typical bypass with a valve is shown in Figure 47. If the boiler temperature rise exceeds 40°F, it is an indication that the boiler may not be receiving adequate flow and adjustment of the bypass is required. If a high temperature rise is experienced, check the pump for proper operation and check the system piping for any obstruction. A larger pump may be necessary. The installation of the recom- mended system bypass as shown in Figure 47 allows an increased flow through the boiler. If there is any doubt that the pump may not provide adequate flow, bypass piping should be provided at the time the boiler is installed. The bypass should be fully sized with a balancing valve to allow for proper adjustment. The balancing valve allows the flow through the bypass to be adjusted based on the individual system requirements. A bypass is recommended on all multiple zone systems in addition to a properly sized circulator and system piping. Heating Boilers with inputs of 225,000 Btu/hr or larger installed on multiple zone systems are recommended to be installed with a primary/secondary piping system as shown in Figure 48. A primary/secondary piping system may also be installed on smaller input boilers to ensure proper boiler flow rates. Primary/secondary piping is also ideal for systems using a mixture of propylene glycol and water. A primary/secondary piping system uses a dedicated pump to supply flow to the boiler only. This pump is sized based on desired boiler flow rate, boiler head loss and head loss in the secondary system piping only. The secondary pump, installed in the boiler piping, ensures a constant water flow rate to the boiler for proper operation. Boiler installation with a primary/secondary piping system can prevent noise problems caused by low system water flows. A primary/secondary piping system is recommended on any boiler where low water flow conditions may present an operational problem. A primary/secondary piping system is ideal for systems filled with a propylene glycol and water mixture. A glycol and water mixture is more dense than water only and may result in a lower boiler flow rate. A lower boiler flow may cause noise on operation or short cycling of the burners. A larger secondary pump may be used on a primary/secondary system to provide an increased boiler flow rate. A glycol and water system may require from 10% to 20% more flow to compensate for the increased density of the glycol and its effect on the heat transfer process in the boiler. The exact FIG. 47 PRIMARY/SECONDARY PIPING OF A SINGLE BOILER MAKE-UP WATER PRV EXPANSION TANK LWCO (OPTIONAL) SECONDARY BOILER PUMP 12” FROM SYSTEM AIR SEPARATOR SYSTEM PUMP TO SYSTEM PRIMARY/SECONDARY BOILER PIPING FIG. 48 MAKE-UP WATER HEATING SUPPLY LOOP TO FLOOR DRAIN HEATING RETURN LOOP BYPASS–LOW FLOW SYSTEMS PRV EXPANSION TANK AIR SEPARATOR SYSTEM PUMP LWCO (OPTIONAL) BYPASS BALANCING VALVE BOILER BYPASS REQUIREMENTS 08/01/17 36 increase in flow that may be required is based on the type and percentage of glycol added to the boiler system. Consult the manufacturer of the glycol for additional recommendations when using a glycol and water fill for your boiler system. The installer must ensure that the boiler has adequate flow without excessive temperature rise. The temperature rise on a multiple zone system should be made when only the zone with the longest length and/or highest head loss is open. Low system flow can result in overheating of the boiler water which can cause short burner on cycles, system noise and in extreme cases, a knocking flash to steam. These conditions indicate the need to open the bypass adjustment valve, installation of a larger circulator pump or installation of the boiler with a primary/secondary piping system. System noise may also indicate an oversized boiler. LOW TEMPERATURE BYPASS REQUIREMENTS A boiler operated with an inlet temperature of less than 140°F (60°C) must have a bypass to prevent problems with condensation. A bypass as shown in Figure 49 must be piped into the system at the time of installation. This piping is like a primary/secondary boiler installation with a bypass in the secondary boiler piping. Inlet water temperatures below 140°F (60°C) can excessively cool the products of combustion resulting in condensation on the heat exchanger and in the flue. Condensation can cause operational problems, bad combustion, sooting, flue gas spillage and reduced service life of the vent system and related components. The bypass allows part of the boiler discharge water to be mixed with the cooler boiler return water to increase the boiler inlet temperature above 140°F (60°C). This should prevent the products of combustion from condensing in most installations. The bypass should be fully sized with a balancing valve to allow for proper adjustment. A valve must also be provided on the boiler discharge, after the bypass. Closing this discharge valve forces water through the bypass. Start boiler adjustment with the bypass valve in the full open position and the boiler discharge valve half open. A small amount of the higher temperature boiler discharge water is mixed with the system water to maintain the desired lower system temperature. A remote low temperature range operator is recommended to control the boiler operation based on the lower system temperature. This remote operator should be wired across the R and W terminals (see Room Thermostat Connection and Terminal Strip instructions). THREE WAY VALVES: CAUTION:  At no time should the system pressure be less than 12 PSIG. BOILER WITH LOW TEMPERATURE BYPASS PIPING FIG. 49 MAKE-UP WATER PRV EXPANSION TANK LWCO (OPTIONAL) SECONDARY BOILER PUMP FROM SYSTEM AIR SEPARATOR SYSTEM PUMP TO SYSTEM BY PASS 12” BOILER PIPING WITH A 3-WAY VALVE SYSTEM PUMP PRV LWCO (OPTIONAL) SECONDARY BOILER PUMP FROM SYSTEM 12” AIR SEPARATOR MAKE-UP WATER TO SYSTEM EXPANSION TANK THREE-WAY VALVE SLOW OPENING/SLOW CLOSING FIG. 50 08/01/17 37 The basic guide for minimum flow in this boiler is based on a 40°F temperature rise in most installations. Lower flow and a higher temperature rise is acceptable if the boiler system is specifically designed for the characteristics of a higher temperature rise. A system not specifically designed for a higher temperature rise may experience overheating of the boiler water. This can cause short burner on cycles, system noise and in extreme cases, a knocking flash to steam. These conditions can lead to operational problems and non-warrantable failures of the boiler. High temperature rise systems must be designed by a qualified engineer. TABLE - M MINIMUM REQUIRED FLOW FOR HEATING BOILER Input Btu/hr GPM Flow 45,000 1.9 75,000 3.1 90,000 3.7 135,000 5.6 180,000 7.4 225,000 9.3 270,000 11.1 315,000 13.0 360,000 14.9 399,000 16.5 500,000 20.7 The installation of a three way valve on this boiler is not generally recommended because most piping methods allow the three way valve to vary flow to the boiler. This boiler is a low mass, high efficiency unit which requires a constant water flow rate for proper operation. Low flow rates can result in overheating of the boiler water which can cause short burner on cycles, system noise and in extreme cases, a knocking flash to steam. These conditions can cause operational problems and non-warrantable failures of the boiler. If a three way valve must be installed, please pipe in a primary/secondary system as shown in Figure 50. Based on boiler sizing and system flow requirements, this piping may still result in boiler short cycling. BOILER FLOW RATES The heat exchanger is generally capable of operating within the flow rates of a residential heating system. Should the flow rate exceed the maximum allowable flow rate through the boiler (30 GPM) an external bypass must be installed. The bypass should be fully sized with a balancing valve to allow for proper adjustment of flow. Flow rate can be determined by measuring the temperature rise through the boiler. CAUTION:  The maximum flow rate through the boiler with a copper heat exchanger must not exceed 33 GPM. NOTE: Minimum flow is based on a 40°F temperature rise across the boiler. Minimum flow may not prove a flow switch installed in the boiler piping. Use care when operating a boiler at or near the minimum recommended flow because conditions unique to the installation (system pressure, operation of multiple zone valves, glycol, variations in flow, etc.), may result in overheating of the boiler water causing noise or nuisance operation of safety limit controls. Typical heating boiler applications will operate with a 20°F to 30°F temperature rise across the boiler. FIG. 51 MAKE-UP WATER PRV EXPANSION TANK LWCO (OPTIONAL) FROM SYSTEM AIR SEPARATOR SYSTEM PUMP TO SYSTEM BOILER BYPASS PIPING BY-PASS VALVE 08/01/17 38 PLACING THE BOILER IN OPERATION Filling the System: All air must be purged from the system for proper operation. An air scoop and air vent must be located close to the boiler outlet and there should be a minimum distance between the cold water feed and the system purge valve. 1. Close all drain cocks and air vents. 2. Open the makeup water valve and slowly fill the system. 3. If a makeup water pump is employed, adjust the pressure to provide a minimum of 12 psi at the highest point in the system. If a pressure regulator is also installed in the line, it should be adjusted to the same pressure. 4. Close all valves. Purge one circuit at a time as follows: A. Open one circuit drain valve and let the water drain for at least five minutes. Ensure that there are no air bubbles visible in the water stream before closing the drain valve. B. Repeat this procedure for each circuit. 5. Open all valves after all circuits have been purged. Make sure there are no system leaks. TABLE - N SYSTEM TEMPERATURE RISE CHART Based on Boiler Output in Btu/hr Btu/hr 10°UT 20°UT 30°UT 40°UT 50°UT Input Output GPM Ft/hd GPM Ft/hd GPM Ft/hd GPM Ft/hd GPM Ft/hd 45,000 36,900 7.4 0.6 3.7 0.2 2.5 0.2 1.9 0.2 - - 75,000 61,500 12.3 1.3 6.2 0.4 4.1 0.3 3.1 0.2 - - 90,000 73,800 14.9 1.4 7.4 0.5 5.0 0.3 3.7 0.2 - - 135,000 110,700 22.3 3.2 11.1 1.2 7.4 0.6 5.6 0.3 - - 180,000 147,600 29.7 5.1 14.9 1.6 9.9 0.7 7.4 0.4 - - 225,000 184,500 - - 18.6 1.3 12.4 0.8 9.3 0.4 - - 270,000 221,400 - - 22.3 2.1 14.9 0.9 11.1 0.5 - - 315,000 258,300 - - 26.0 4.1 17.3 2.2 13.0 1.3 - - 360,000 295,200 - - 29.7 5.4 19.8 2.5 14.9 1.5 - - 399,000 327,180 - - 33.0 8.1 22.0 3.6 16.5 2.0 13.2 1.7 500,000 410,000 ----27.6 6.6 20.7 3.5 16.6 2.1 TEMPERATURE/PRESSURE GAUGE This boiler is equipped with a dial type tempera- ture/pressure gauge. This gauge is factory installed in the outlet side of the heat exchanger. The gauge has one scale to read system pressure and a separate scale to read water temperature in °F. The temperature/pressure gauge can be used to determine temperature rise by first recording the temperature of the boiler water with the boiler off. Record the temperature of the boiler water as the boiler fires and the discharge temperature stabilizes. Subtract the boiler water temperature with the boiler off from the stable outlet water temperature with the boiler firing. This temperature difference is the temperature rise. TYPICAL HEATING BOILER INSTALLATIONS General Plumbing Rules 1. Check all local codes. 2. For serviceability of the boiler, always install unions. 3. Always pipe the pressure relief valve to an open drain. 4. Locate system air vents at highest point of system. 5. Expansion tank must be installed near the boiler and on the suction side of the pump. 6. Support all water piping. 08/01/17 INSTALLATION WITH A CHILLED WATER SYSTEM Pipe refrigeration systems in parallel. Install duct coil downstream at cooling coil. Where the hot water heating boiler is connected to a heating coil located in the air handling units which may be exposed to refrigeration air circulation, the boiler piping system must be equipped with flow control valves or other automatic means to prevent gravity circulation of the boiler water during the cooling cycle. The coil must be vented at the high point and hot water from the boiler must enter the coil at this point. Due to the fast heating capacity of the boiler, it is not necessary to provide a ductstat to delay circulator operation. Also, omit thermostat flow checks as the boiler is cold when heating thermostat is satisfied. This provides greater economy over maintaining standby heat. 39 6. Run the system circulating pump for a minimum of 30 minutes with the boiler turned off. 7. Open all strainers in the system and check for debris. 8. Recheck all air vents as described in step 4. 9. Inspect the liquid level in the expansion tank. The system must be full and under normal operating pressure to ensure proper water level in the expansion tank. Ensure that diaphragm type expansion tanks are properly charged and not water logged. 10. Start the boiler according to the Start-Up Instructions in this manual. Operate the system, including the pump, boiler and radiation units, for one hour. 11. Recheck the water level in the expansion tank. If it exceeds half the tank volume, open the tank to reduce the water level. Recheck pressure charge on diaphragm type tanks. 12. Shut down the entire system and vent all radiation units and high points in the system. 13. Close the water makeup valve and check the strainer and pressure reducing valve for sediment or debris. Reopen the water makeup valve. 14. Verify system pressure with the boiler pressure gauge before beginning regular operation. 15. Within three days of start-up, recheck and bleed all air vents and the expansion tank using these instructions. NOTE:Do not use petroleum based stop leak products. All system leaks must be repaired. The constant addition of make-up water can cause damage to the boiler heat exchanger due to scale accumulation. Scale reduces flow and heat trans- fer, causing overheating of the heat exchanger. FIG. 52 08/01/17 40 Remove the jumper between the R and W terminals on the terminal strip. Refer to the chart in this section to determine maximum allowable length and wire gauge recommended to connect the switching contacts of the room thermostat to the R and W terminals on the terminal strip. Connection to the terminal strip will allow the room thermostat to make and break the 24 VAC boiler control circuit turning the boiler on and off based on the room ambient temperature requirements. Set the boiler operating temperature control as described above. TABLE - O TERMINAL STRIP WIRING Wire Gauge Maximum Allowable Length 12 GA 100 ft 14 GA 75 ft 16 GA 50 ft 18 GA 30 ft DOMESTIC HOT WATER SUPPLY BOILERS 90,000 - 500,000 Btu/hr MODELS WATER HEATERS 90,000 - 360,000 Btu/hr MODELS This section applies only to those units used to supply direct fired domestic hot water and installed with a storage tank(s). The use of a properly sized pump and the control of water velocity, as explained below, are important for correct operation of your hot water supply boiler. This section contains specific instructions for those units used to supply domestic hot water. All warnings, cautions, notes and instructions in the general installation and service sections apply to these instructions. Hot water supply boilers/water heaters are designed for installation with a storage tank. The use of a properly sized pump and the control of water velocity, as explained below, is important for correct operation of your water heater/hot water supply boiler. BOILER OPERATING TEMPERATURE CONTROL The operating temperature control is located in the control panel, behind the control panel front access door. The sensing element for the operator is placed in a bulb well installed in the inlet side of the heat exchanger front header. Carefully observe the discharge water temperature on the initial boiler on cycles. The location of the temperature sensor will generally require a lower temperature set point on the operating control to achieve the desired discharge water temperature from the boiler. This sensing element location allows a boiler operating with a low to moderate flow rate to sustain longer burner on cycles, preventing short boiler ON cycles based on high discharge water temperatures. For example, a boiler operating with a 180°F discharge and a 20°F temperature rise would require approximately a 160°F to 165°F set point with the temperature sensor installed on the inlet side of the heat exchanger. The exact temperature set point is based on your systems requirements. Turn the control set point dial to the desired operating water temperature. Observe the boiler discharge temperature after each set point adjustment to ensure proper operation. ROOM THERMOSTAT OR REMOTE THERMOSTAT CONNECTION TO TERMINAL STRIP A room thermostat or remote temperature control may be connected to the boiler. The room thermostat should be installed on an inside wall, away from the influences of drafts, hot or cold water pipes, lighting fixtures, televisions, sun rays or fireplaces. Follow the manufacturers instructions supplied with the thermostat for proper installation and adjustment. The boiler is equipped with a terminal strip on the left side of the control panel to allow easy connection. FIG. 53 TERMINAL STRIP CONNECTIONS 08/01/17 41 WATER VELOCITY CONTROL IMPORTANT - To ensure proper velocity through the heat exchanger, it is necessary to regulate the temperature rise across the heat exchanger from inlet to outlet. This must be done on initial installation and periodically rechecked. With the correct temperature rise across the heat exchanger, you may be assured of the proper velocity in the tubes. This will yield long life and economical operation from your hot water supply boiler. Excessive lime build-up in the tube is a result of too little velocity in the tubes. Excessive pitting or erosion in the tube is caused by too much velocity through the tubes. Care should be taken to measure temperature rise and maintain a velocity as follows: 1. The pump must run continuously when the burners are firing. 2. With the pump running and the water heater/hot water supply boiler off, the inlet and outlet thermometers should read the same temperatures. If they do not, an adjustment must be made to your final calculation. 3. Turn the water heater/hot water supply boiler on and allow time for the temperature to stabilize. Record the difference between the inlet and outlet temperatures. This difference will be the temperature rise. 4. Compare the temperature rise on the heater with the required temperature rise in Table P. Should adjustment be needed, proceed as follows: If the temperature rise is too high, the water velocity is too low. Check the following: 1. Check for restrictions in the outlet of the water heater/hot water supply boiler. 2. Be sure all valves are open between the water heater/hot water supply boiler and the tank. 3. Check the pump to be sure it is running properly and that the pump motor is running in the proper direction. 4. Be sure the circulation pipes between the water heater/hot water supply boiler and storage tank are not less than 1 1/2" diameter for a single unit installation. 5. Common manifold piping for multiple unit instal- lations will require larger minimum pipe sizes and tank tappings to ensure proper flow, see Table Q. 6. Multiple unit installations may also require a larger circulating pump to achieve the specified flow against the increased head loss of a multiple unit common manifold piping. If the temperature rise is too low, the water velocity is too high. Adjust as follows: 1. Slowly throttle the valve on the outlet side of the water heater/hot water supply boiler until the temperature rise is steady at the required tempera- ture rise as noted in Table P. 2. Sustained high water velocity and low temperature rise may result in pitting or erosion of the copper tubes in the heat exchanger. This is a non-warrantable failure. Temperature rise must be properly adjusted to achieve the specified flow rate. TABLE - P REQUIRED TEMPERATURE RISE Based on heating potable water with a hardness of 5 to 25 grains per gallon and total dissolved solids not exceeding 350 ppm. See Water Chemistry. Btu/hr INPUT Temperature Rise oF 90,000 5° 135,000 7° 180,000 10° 199,000 11° 225,000 12° 270,000 15° 315,000 17° 360,000 20° 399,000 22° 500,000 28° 08/01/17 42 WATER CHEMISTRY The required temperature rise and the standard pump sizing are based on the heating of potable water with a hardness of 5 to 25 grains per gallon and a total dissolved solids not exceeding 350 ppm. Consult the manufacturer when heating potable water exceeding these specifications. Heating of high hardness and/or high total dissolved solids water will require a larger circulating pump, an optional cupro-nickel heat exchanger and a revised temperature rise specification based on the water chemistry of the water to be heated. Water with a hardness of less than 5 grains per gallon will usually have a low pH which can be aggressive and corrosive causing non-warrantable damage to the heater, pump and associated piping. Corrosion due to water chemistry generally shows up first in the hot water system because heated water increases the rate of corrosive chemical reactions. TABLE - Q COMMON WATER MANIFOLD SIZE FOR MULTIPLE HOT WATER SUPPLY BOILER INSTALLATIONS Pipe sizing chart provides minimum pipe size for common manifold piping and tank tappings to ensure adequate flow. Number of Units Common Manifold Size (Min) 1 1 1/2" 2 2" 3 2 1/2" 4 3" 5 3 1/2" 6 3 1/2" PUMP OPERATION 1. The water heater/hot water supply boiler must be connected to a properly sized pump that circulates water between the heater and storage tank. 2. Pump is sized to heater input and water hardness. Care should be taken to size pump correctly. See Water Chemistry. 3. The pump must run continuously when the burners are firing. 4. Lubricate pump to manufacturers recommendations. Pump damage due to inadequate lubrication is non- warrantable. 5. A standard water heater/hot water supply boiler is furnished with a 1/6 HP, 120 VAC, 3.6 AMP circulating pump to be mounted on the units inlet water connection. This pump is sized based on installation of a single storage tank and heater in close proximity. If the number of fittings and straight pipe exceeds the quantities shown in this section, a larger pump will be required. FIG. 54 Typical Water Heater Piping with Storage Tank COLD WATER SUPPLY LOCK-TEMP STORAGE TANK HOT WATER SUPPLY RELIEF VALVE DRAIN RELIEF VALVE BUILDING RETURN CIRCULATING PUMP EXPANSION TANK (If Required) 08/01/17 43 The standard pump selection is based on the following pipe and fittings from the unit to the storage tank: 6 - 90° elbows 2 - ball valves 2 - unions 1 - cold water tee Plus the following length of straight pipe based on the heater size: 90,000 thru 360,000 Btu/hr Models Not more than 45 feet of straight pipe 399,000 thru 500,000 Btu/hr Models Not more than 25 feet of straight pipe For every elbow and tee in excess of those shown above, DEDUCT 5 FEET from maximum allowable straight pipe in heater to tank circulating loop. MINIMUM PUMP PERFORMANCE Based on heating potable water with a hardness of 5 to 25 grains per gallon and total dissolved solids not exceeding 350 ppm. See Water Chemistry. BTU INPUT GPM Ft. Hd. 90,000 - 500,000 30 8 HEAT EXCHANGER This is a highly sophisticated heat exchanger, designed to carry water in such a way that it generates a scouring action which keeps all interior surfaces free from build-up of impurities. The straight-line, two pass design of the tubes sends water into the headers at a properly rated velocity. The configuration of the headers, in turn, creates a high degree of turbulence which is sufficient to keep all contaminants in suspension. This scouring action provides greater cost savings for owners. Tubes are always able to transfer heat at peak efficiency. Every surface within this water containing section is of a nonferrous material, providing clear, clean, rust-free hot water. Straight copper tubes-finned on the outside for maximum heat transfer-glass lined cast iron one piece cored headers make up an entirely rustproof unit. On all models, header inspection plugs can be removed for field inspection and cleaning of copper tubes. The entire heat exchanger may be easily removed from the unit. THERMOSTAT SETTINGS 1. The thermostat is adjusted to a low test setting when shipped from the factory. 2. Set the thermostat to the lowest settings which will satisfy hot water demands and prevent risk of scald injury. TEMPERATURE ADJUSTMENT (Domestic Hot Water Use) This unit has an adjustable thermostat to control water temperature. See temperature adjustment procedure in the general section of the manual. The thermostat is factory preset at approximately 125°F. Households with small children or invalids may require 120°F or lower temperature setting to reduce risk of scald injury. Some states may require a lower temperature setting. Check with your gas supplier for local requirements governing the temperature setting. Remember, no water heating system will provide exact temperature at all times. Allow a few days of operation at this setting to determine the correct temperature setting consistent with your needs. Incorrect piping of the cold water supply to the system may result in excessive low temperature operation causing condensate formation on the heat exchanger and operational problems. The cold water supply piping must be installed in the discharge piping from the heater to the storage tank. This allows the cold water to be tempered in the storage tank before entering the heater. See typical installation drawings provided with the unit for correct piping. Higher water temperatures reduce condensate formation. NOTE: (1) This water heater, when set at the lower temperature setting, is not capable of producing hot water of sufficient temperature for sanitizing purposes. (2) Higher stored water temperature increases the ability of the water heater to supply desired quantities of hot water, however remember: CAUTION:  Hotter water increases the risk ofscald injury. 08/01/17 44 The manufacturer recommends the use of a properly sized thermostatic mixing valve to supply domestic hot water at temperatures less than 140°F. Storing the water at a higher temperature and thermostatically mixing the water will increase the available quantity of mixed hot water, greatly reduce the possibility of condensate formation on the heat exchanger and help prevent the growth of water born bacteria. Adequate care MUST be taken to prevent potential scald injury when storing water at 140°F and hotter. HIGH WATER TEMPERATURE LIMIT CONTROL The unit may be equipped with either a fixed setting, manual-reset high water temperature limit control or an adjustable setting, auto-reset high water temperature limit. See the Temperature Adjustment section of the manual for specific data on the limit provided. A water heater or hot water supply boiler should have the set point of the adjustable temperature limit control set to a maximum of 200°F (93°C). If water temperature exceeds the set point, the limit will break the control circuit and shut down the unit. The limit control will only be reset after the water temperature has cooled below the set point of the limit. The high water temperature limit control is mounted in the outlet side of the front header. A manual reset high water temperature limit control is available as an optional control on all units. AUTOMATIC VENT DAMPERS Automatic vent dampers are not required or furnished on potable water heaters. All water heaters will have a plug installed in the damper terminal on the side of the control panel to allow operation without a vent damper. The damper plug MUST be in place if an optional vent damper is not used on a water heater. Water heaters with inputs of 360,000 Btu/hr and less may be ordered with the vent damper as an option. Remove damper plug from terminal to connect an optional vent damper wire harness. The optional damper must be properly installed and the wire harness plugged into the terminal on the side of the control panel to allow the unit to function. See the Automatic Vent Damper section in the basic portion of the manual. CAUTION:  Do not install an optional vent damper within 6" ( (152mm) of combustible materials. OPTIONAL RELIEF VALVE This water heater/hot water supply boiler is normally supplied with a temperature and pressure relief valve(s) sized in accordance with applicable codes. Units may be supplied with an optional pressure only relief valve(s). When a water heater/hot water supply boiler equipped with this optional relief valve is piped to a separate storage vessel, the storage vessel must have a properly installed temperature and pressure relief valve which complies with local codes. CAUTION:  Setting the temperature selector to higher settings provides hotter water, which increases the risk of scald injury. SHOULD OVERHEATING OCCUR OR THE GAS SUPPLY FAIL TO SHUT OFF, DO NOT TURN OFF OR DISCONNECT THE ELECTRICAL SUPPLY TO THE PUMP. INSTEAD, SHUT OFF THE GAS SUPPLY AT A LOCATION EXTERNAL TO THE APPLIANCE. WARNING: · Water temperature over 125°F (52°C) can cause severe burns instantly or death from scalds. · Children, disabled and elderly are at highest risk of being scalded. · See instruction manual before setting temperature at heating appliance. · Feel water before bathing or showering. · If this appliance is used to produce water that could scald if too hot, such as domestic hot water use, adjust the outlet control (limit) or use temperature limiting valves to obtain a maximum water temperature of 125°F (52°C). 08/01/17 45 THERMAL EXPANSION A relief valve which discharges periodically may be due to thermal expansion in a closed system. A hot water supply boiler installed in a closed system, such as one with a backflow preventer or check valve installed in the cold water supply, shall be provided with means to control expansion. Contact the water supplier or local plumbing inspector on how to correct this situation. Do not plug or cap the relief valve discharge! CATHODIC PROTECTION Hydrogen gas can be produced in a hot water system that has not been used for a long period of time (generally two weeks or more). Hydrogen gas is extremely flammable. To prevent the possibility of injury under these conditions, we recommend the hot water faucet be open for several minutes at the kitchen sink before you use any electrical appliance which is connected to the hot water system. If hydrogen is present, there will be an unusual sound such as air escaping through the pipe as the hot water begins to flow. There should be no smoking or open flames near the faucet at the time it is open. 08/01/17 46 NOTES 08/01/17 47 NOTES 08/01/17 CP-5M-2/04-Printed in U.S.A. 08/01/17