Lochinvar CP-5M-4/08, 45 LOW Temperature Bypass Requirements, Three WAY Valves, Boiler Flow Rates

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LOW TEMPERATURE BYPASS

REQUIREMENTS

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 tem- perature 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:

SECONDARY

BOILER PUMP

EXPANSION

 

FROM

TANK

PRV

SYSTEM

MAKE-UP

WATER

 

LWCO

THREE-WAY VALVE

 

(OPTIONAL)

 

SLOW

 

 

 

 

OPENING/SLOW

TO SYSTEM

 

CLOSING

 

 

 

AIR SEPARATOR

 

 

SYSTEM PUMP

 

FIG. 45 Boiler Piping with a 3-Way Valve

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 45. Based on boiler sizing and system flow requirements, this piping may still result in boiler short cycling.

BOILER FLOW RATES

￿CAUTION

The maximum flow rate through the boiler with a copper heat exchanger must not exceed 30 GPM.

MAKE-UP WATER

PRV

EXPANSION TANK

TO SYSTEM

LWCO (OPTIONAL)

SYSTEM PUMP

AIR SEPARATOR

BYPASS VALVE

FROM SYSTEM

FIG. 46 Boiler Bypass Piping

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.

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.

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Contents Checking Equipment WarrantySpecial Instructions to Owner Contents User Warning Location of Unit Installation ProcedureCodes Clearances from Combustible Construction Clearance from Combustible ConstructionCombustion Air Through Ducts Openings Table a Minimum Recommended Combustion AIR SupplyInput Btu/hr Flue Size VentingConventional Negative Draft Venting System Table B Vent Pipe SizesPage Vent Termination from Peaked Roof 10’ or Less from Ridge Venting TerminationInspection of a Masonry Chimney Sidewall Venting Masonry Chimney InstallationVent Damper and Vent Damper Terminal Block Automatic Vent DamperTable D Manifold Pressure GAS Supply GAS Pressure TestTable C GAS ConnectionBtu/hr Distance from Meter In Feet Table F Fittings to Equivalent Straight PipeTable G GAS Connections GAS Piping Install Piping to ControlWrench GAS Manifold Pressure Adjustment ProcedurePilot Checking GAS Supply PressureVenting of Combination Gas Valves Combination GAS ValvesRelief Valve Water Heater Relief Valve Water Flow Switch if EquippedTable J AMP Draw Data Minimum Flow Rate Required to Actuate Flow SwitchLOW Water Cutoff if Equipped TWO Stage Burner Control SystemLocating Temperature Control Temperature AdjustmentTemperature Control Settings Operating Temperature ControlHigh-Fire Offset Temperature Control SensorsInstallation of Remote Sensors Wiring of Remote SensorsAdditional Temperature Controls Outdoor AIR Reset OptionInitial START-UP Blocked Vent and Flame ROLL-OUT/FLAME Interlock SwitchManual Reset High Water Temperature Limit What to do if YOU Smell GAS PRE-START ChecklistInput for Your Safety Read Before Operating Lighting Instructions for Standing Pilot Models F1Lighting Wand Lighting Instructions for Spark Ignition Pilot Models F9/M9 Safety Shutoff Test for Standing Pilot Ignition SystemTo Turn OFF GAS to Appliance Operating Instructions To Turn OFF GAS to Appliance Safety Shutoff Test for Spark Ignition Pilot SystemF9/M9 Intermittent Spark Ignition Pilot Models Intermittent Pilot Spark Ignition System F9/M9Freeze Protection Freeze Protection for a HeatingWater Treatment MaintenanceRemoval of Combustion Chamber Lining or Base Panels Inspection Cleaning ProcedureOuter Air Deflector and HEX Filler Bracket Circulator Pump Requirements GAS Train and ControlsWater Connections Heating Boilers only Piping of the Boiler SystemCirculator Pump Operation Circulator Pump SpecificationsTable L Primary/Secondary Piping of a Single Boiler PRIMARY/SECONDARY Boiler PipingBoiler Flow Rates LOW Temperature Bypass RequirementsThree WAY Valves General Plumbing Rules Table M Minimum Required Flow for Heating BoilerTable N Installation with a Chilled Water SystemWire Gauge Boiler Operating Temperature ControlPower Venter Connection To Terminal Strip Table O Terminal Strip WiringBtu/hr To 7 Grains To 25 Grains Hardness Required Temperature RiseTable P Required Temperature Rise Water Velocity ControlPump Operation Water ChemistrySoftened Water Systems Heat Exchanger Remote Sensor Installation InstructionsThermostat Settings Minimum Pump PerformanceOptional Relief Valve Automatic Vent DampersDo not plug or cap the relief valve discharge Thermal ExpansionCathodic Protection Troubleshooting Guide 90,000 270,000 Btu/hr Models Water Heaters F1 Schematic Diagram F1 Unit Schematic Diagram F9 Unit Schematic Diagram M9 Unit Schematic Diagram F9/M9 Unit Page
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