Hydronic System and Control Method

US 20130240172A1
Filed: 03/13/2012
Published: 09/19/2013
Est. Priority Date: 03/13/2012
Status: Abandoned Application

First Claim

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1. A hydronic system for controlling the air temperature in at least one zone, said hydronic system comprising:

a working fluid for effecting heat transfer;

a first heat exchanger for imparting or removing heat to or from said working fluid;

a second heat exchanger for imparting or removing heat to or from air in said at least one zone, said second heat exchanger being in fluid communication with said first heat exchanger;

a valve controlling a mass flow rate of said working fluid through said second heat exchanger;

a pump in fluid communication with said first and second heat exchangers for pumping said working fluid therebetween;

a first temperature measuring device measuring said air temperature in said at least one zone;

a second temperature measuring device measuring a change in temperature of said working fluid across said second heat exchanger;

a controller in communication with said first and second temperature measuring devices and said valve;

whereinsaid controller controls said valve in response to signals from said second temperature measuring device indicative of said change in temperature of said working fluid across said second heat exchanger, and said controller controls said valve in response to signals from said first temperature measuring device indicative of said air temperature in said at least one zone.

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Abstract

A hydronic system controls the air temperature in a plurality of zones. The system has a plurality of heat exchangers, each one being associated with a respective zone. The mass flow rate of a working fluid through each heat exchanger is controlled to maintain the working fluid temperature drop across the heat exchanger a constant, chosen for efficient operation of the boiler or chiller which transfers heat to or from the working fluid. The flow of air in each zone through each heat exchanger is controlled by the air temperature in the zone. A respective valve associated with each heat exchanger is used to control the mass flow rate of the working fluid through the heat exchanger, and also imposes an upper limit of the mass flow rate established by balancing the hydronic system. The upper limit is controlled by a parameter proportional to mass flow rate.

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38 Claims

1. A hydronic system for controlling the air temperature in at least one zone, said hydronic system comprising:
- a working fluid for effecting heat transfer;
  
  a first heat exchanger for imparting or removing heat to or from said working fluid;
  
  a second heat exchanger for imparting or removing heat to or from air in said at least one zone, said second heat exchanger being in fluid communication with said first heat exchanger;
  
  a valve controlling a mass flow rate of said working fluid through said second heat exchanger;
  
  a pump in fluid communication with said first and second heat exchangers for pumping said working fluid therebetween;
  
  a first temperature measuring device measuring said air temperature in said at least one zone;
  
  a second temperature measuring device measuring a change in temperature of said working fluid across said second heat exchanger;
  
  a controller in communication with said first and second temperature measuring devices and said valve;
  
  whereinsaid controller controls said valve in response to signals from said second temperature measuring device indicative of said change in temperature of said working fluid across said second heat exchanger, and said controller controls said valve in response to signals from said first temperature measuring device indicative of said air temperature in said at least one zone.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The hydronic system according to claim 1, wherein said first heat exchanger comprises a boiler for adding heat to said working fluid.
  - 3. The hydronic system according to claim 1, wherein said first heat exchanger comprises a chiller for removing heat from said working fluid.
  - 4. The hydronic system according to claim 1, wherein said second heat exchanger further comprises a fan controlling a mass flow rate of said air through said second heat exchanger, said fan being in communication with said controller, said controller controlling said fan in response to signals from said first temperature measuring device indicative of said air temperature in said at least one zone.
  - 5. The hydronic system according to claim 1, wherein said second heat exchanger further comprises a fan controlling a mass flow rate of said air through said second heat exchanger, said fan being in communication with said first temperature measuring device and said controller, said fan controlling said controller in response to signals from said first temperature measuring device indicative of said air temperature in said at least one zone, said controller controlling said valve.
  - 6. The hydronic system according to claim 1, further comprising a pressure measuring device measuring a change in pressure of said working fluid across said valve, said controller being in communication with said pressure measuring device and controlling said valve so as to limit said mass flow rate of said working fluid through said second heat exchanger to a maximum value in response to signals from said pressure measuring device.
  - 7. The hydronic system according to claim 1, further comprising:
    - an orifice in fluid communication with said second heat exchanger;
      
      a pressure measuring device measuring a change in pressure of said working fluid across said orifice, said controller being in communication with said pressure measuring device and controlling said valve so as to limit said mass flow rate of said working fluid through said second heat exchanger to a maximum value in response to signals from said pressure measuring device.
  - 8. The hydronic system according to claim 1, further comprising:
    - a venturi in fluid communication with said second heat exchanger;
      
      a pressure measuring device measuring a change in pressure of said working fluid across said venturi, said controller being in communication with said pressure measuring device and controlling said valve so as to limit said mass flow rate of said working fluid through said second heat exchanger to a maximum value in response to signals from said pressure measuring device.
  - 9. The hydronic system according to claim 1, further comprising a means for measuring a mass flow rate of said working fluid through said second heat exchanger, said controller being in communication with said means for measuring said mass flow rate and controlling said valve so as to limit said mass flow rate of said working fluid through said second heat exchanger to a maximum value in response to signals from said means for measuring said mass flow rate of said working fluid.
  - 10. The hydronic system according to claim 9, wherein said means for measuring a mass flow rate of said working fluid through said second heat exchanger is selected from the group consisting of a hot wire anemometer, an orifice and a venturi.
  - 11. The hydronic system according to claim 1, wherein said working fluid comprises water.

12. A hydronic system for controlling the air temperature in a plurality of zones, said hydronic system comprising:
- a working fluid for effecting heat transfer;
  
  a first heat exchanger for imparting or removing heat to or from said working fluid;
  
  a plurality of first temperature measuring devices, at least one of said first temperature measuring devices measuring said air temperature in at least one of said zones;
  
  a plurality of second heat exchangers, at least one of said second heat exchangers for imparting or removing heat to or from air in said at least one zone, said at least one second heat exchanger being in fluid communication with said first heat exchanger, said at least one second heat exchanger comprising;
  
  a valve controlling a mass flow rate of said working fluid through said at least one second heat exchanger;
  
  a second temperature measuring device measuring a change in temperature of said working fluid across said at least one second heat exchanger;
  
  said hydronic system further comprising;
  
  at least one pump in fluid communication with said first heat exchanger and said at least one second heat exchanger for pumping said working fluid therebetween;
  
  a controller in communication with said at least one first temperature measuring device, said second temperature measuring device and said valve associated with said at least one second heat exchanger;
  
  wherein for said at least one second heat exchanger in said at least one zone, said controller controlling said valve in response to signals from said first and second temperature measuring devices.
- View Dependent Claims (13, 14, 15, 16, 17, 18, 19, 20, 21, 22)
- - 13. The hydronic system according to claim 12, wherein said first heat exchanger comprises a boiler for adding heat to said working fluid.
  - 14. The hydronic system according to claim 12, wherein said first heat exchanger comprises a chiller for removing heat from said working fluid.
  - 15. The hydronic system according to claim 12, wherein said at least one second heat exchanger further comprises a fan controlling a mass flow rate of said air through said at least one second heat exchanger, said fan being in communication with said controller, said controller controlling said fan in response to signals from said first temperature measuring device indicative of said air temperature in said at least one zone.
  - 16. The hydronic system according to claim 12, wherein said at least one second heat exchanger further comprises a fan controlling a mass flow rate of said air through said at least one second heat exchanger, said fan being in communication with said at least one first temperature measuring device and said controller, said fan controlling said controller in response to signals from said at least one first temperature measuring device indicative of said air temperature in said at least one zone, said controller controlling said valve.
  - 17. The hydronic system according to claim 12, wherein said at least one second heat exchanger further comprises a pressure measuring device measuring a change in pressure of said working fluid across said valve, said controller being in communication with said pressure measuring device and controlling said valve so as to limit said mass flow rate of said working fluid through said at least one second heat exchanger to a maximum value in response to signals from said pressure measuring device.
  - 18. The hydronic system according to claim 12, further comprising:
    - an orifice in fluid communication with said at least one second heat exchanger;
      
      a pressure measuring device measuring a change in pressure of said working fluid across said orifice, said controller being in communication with said pressure measuring device and controlling said valve so as to limit said mass flow rate of said working fluid through said at least one second heat exchanger to a maximum value in response to signals from said pressure measuring device.
  - 19. The hydronic system according to claim 12, further comprising:
    - a venturi in fluid communication with said at least one second heat exchanger;
      
      a pressure measuring device measuring a change in pressure of said working fluid across said venturi, said controller being in communication with said pressure measuring device and controlling said valve so as to limit said mass flow rate of said working fluid through said at least one second heat exchanger to a maximum value in response to signals from said pressure measuring device.
  - 20. The hydronic system according to claim 12, further comprising a means for measuring a mass flow rate of said working fluid through said at least one second heat exchanger, said controller being in communication with said means for measuring said mass flow rate and controlling said valve so as to limit said mass flow rate of said working fluid through said at least one second heat exchanger to a maximum value in response to signals from said means for measuring said mass flow rate of said working fluid.
  - 21. The hydronic system according to claim 20, wherein said means for measuring a mass flow rate of said working fluid through said at least one second heat exchanger is selected from the group consisting of a hot wire anemometer, an orifice and an venturi.
  - 22. The hydronic system according to claim 12, wherein said working fluid comprises water.

23. A method of operating a hydronic system for controlling the air temperature in at least one zone, said method comprising:
- moving a working fluid through a heat exchanger;
  
  moving air from said at least one zone through said heat exchanger for transferring heat between said working fluid and said air;
  
  measuring a first temperature of said working fluid before heat is transferred between said working fluid and said air;
  
  measuring a second temperature of said working fluid after heat is transferred between said working fluid and said air;
  
  adjusting a mass flow rate of said working fluid through said heat exchanger so as to maintain a constant temperature difference between said first and second temperatures of said working fluid;
  
  measuring said air temperature in said at least one zone;
  
  adjusting a mass flow rate of said air from said at least one zone through said heat exchanger so as to achieve and maintain a desired air temperature in said at least one zone.
- View Dependent Claims (24, 25, 26, 27, 28, 29, 30)
- - 24. The method according to claim 23, further comprising:
    - establishing a maximum permitted mass flow rate of said working fluid through said heat exchanger;
      
      measuring said mass flow rate of said working fluid through said heat exchanger; and
      
      adjusting said mass flow rate of said working fluid through said heat exchanger so that it is no greater than said maximum permitted mass flow rate.
  - 25. The method according to claim 24, wherein establishing said maximum permitted mass flow rate of said working fluid through said heat exchanger comprises balancing a mass flow of said working fluid through said hydronic system so that said mass flow rate of said working fluid through said heat exchanger is sufficient to meet a maximum required heat load at all times during operation of said hydronic system.
  - 26. The method according to claim 23, further comprising adjusting the mass flow rate of said working fluid through said heat exchanger so as to maintain a constant temperature difference of about 20°
    - F. between said first and second temperatures of said working fluid.
  - 27. The method according to claim 23, further comprising adjusting the mass flow rate of said working fluid through said heat exchanger so as to maintain a constant temperature difference of about 40°
    - F. between said first and second temperatures of said working fluid.
  - 28. The method according to claim 23, further comprising adjusting the mass flow rate of said working fluid through said heat exchanger so as to maintain a constant temperature difference from about 20°
    - F. to about 60°
      
      F. between said first and second temperatures of said working fluid.
  - 29. The method according to claim 23, further comprising adjusting the mass flow rate of said working fluid through said heat exchanger so as to maintain a constant temperature difference of about 10°
    - F. between said first and second temperatures of said working fluid.
  - 30. The method according to claim 23, further comprising adjusting the mass flow rate of said working fluid through said heat exchanger so as to maintain a constant temperature difference from about 10°
    - F. to about 30°
      
      F. between said first and second temperatures of said working fluid.

31. A method of operating a hydronic system for controlling the air temperature in a plurality of zones, said method comprising:
- moving a working fluid through a plurality of heat exchangers, each heat exchanger being associated with a respective one of said zones;
  
  for each said zone, moving air from said zone through said heat exchanger associated therewith for transferring heat between said working fluid and said air in said zone;
  
  for each said heat exchanger, measuring a first temperature of said working fluid before heat is transferred between said working fluid and said air;
  
  for each said heat exchanger, measuring a second temperature of said working fluid after heat is transferred between said working fluid and said air;
  
  for each said heat exchanger, adjusting the mass flow rate of said working fluid through said heat exchanger so as to maintain a constant temperature difference between said first and second temperatures of said working fluid;
  
  for each said zone, measuring the air temperature in said zone;
  
  for each said heat exchanger and each said zone, adjusting the mass flow rate of air from said zone through said heat exchanger associated therewith so as to achieve and maintain a desired air temperature in said zone.
- View Dependent Claims (32, 33, 34, 35, 36, 37, 38)
- - 32. The method according to claim 31, further comprising:
    - for each said heat exchanger, establishing a respective maximum permitted mass flow rate of said working fluid therethrough;
      
      for each said heat exchanger, measuring said mass flow rate of said working fluid therethrough; and
      
      for each said heat exchanger, adjusting said mass flow rate of said working fluid therethrough so that it is no greater than said respective maximum permitted mass flow rate.
  - 33. The method according to claim 32, wherein establishing said respective maximum permitted mass flow rate of said working fluid through each said heat exchanger comprises balancing a mass flow of said working fluid through said hydronic system so that said mass flow rate of said working fluid through each said heat exchanger is sufficient to meet a maximum required heat load at all times during operation of said hydronic system.
  - 34. The method according to claim 31, further comprising adjusting the mass flow rate of said working fluid through each said heat exchanger so as to maintain a constant temperature difference of about 20°
    - F. between said first and second temperatures of said working fluid.
  - 35. The method according to claim 31, further comprising adjusting the mass flow rate of said working fluid through each said heat exchanger so as to maintain a constant temperature difference of about 40°
    - F. between said first and second temperatures of said working fluid.
  - 36. The method according to claim 31, further comprising adjusting the mass flow rate of said working fluid through each said heat exchanger so as to maintain a constant temperature difference from about 20°
    - F. to about 60°
      
      F. between said first and second temperatures of said working fluid.
  - 37. The method according to claim 31, further comprising adjusting the mass flow rate of said working fluid through each said heat exchanger so as to maintain a constant temperature difference of about 10°
    - F. between said first and second temperatures of said working fluid.
  - 38. The method according to claim 31, further comprising adjusting the mass flow rate of said working fluid through each said heat exchanger so as to maintain a constant temperature difference from about 10°
    - F. to about 30°
      
      F. between said first and second temperatures of said working fluid.

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Current Assignee
Victaulic Company
Original Assignee
Victaulic Company
Inventors
Reilly, William J., Reilly, William C.

Application Number

US13/418,738
Publication Number

US 20130240172A1
Time in Patent Office

Days
Field of Search
US Class Current

165/11.1
CPC Class Codes

F24D 19/1018   Radiator valves

F24D 19/1036   Having differential pressur...

F24D 2220/044   Flow sensors

F24D 2220/046   Pressure sensors

F24D 2220/2027   Convectors (radiators where...

F24D 3/02   with forced circulation, e....

F24D 5/02   operating with discharge of...

F24F 11/77   by controlling the speed of...

F24F 11/83   by controlling the supply o...

F24F 11/84   using valves

F24F 11/85   using variable-flow pumps

F25B 25/005   using primary and secondary...

G05D 23/1931   to control the temperature ...

Y02B 30/70   Efficient control or regula...

Hydronic System and Control Method

First Claim

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Abstract

35 Citations

38 Claims

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Hydronic System and Control Method

First Claim

1 Assignment

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Abstract

35 Citations

38 Claims

Specification

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