Energy management system for refrigeration systems

US 4,325,223 A
Filed: 03/16/1981
Issued: 04/20/1982
Est. Priority Date: 03/16/1981
Status: Expired due to Fees

First Claim

Patent Images

1. An energy management system for a single stage refrigeration system having evaporative type condensers comprising:

A. a plurality of electrical temperature sensors attached to said refrigeration system, said sensors producing electrical signals representative of operating parameters of said refrigeration system includinga. wet bulb temperature,b. dry bulb temperature,c. condensing temperature, andd. ambient temperature;

B. a plurality of electrical pressure sensors attached to said refrigeration system, said pressure sensors producing electrical signals representative of operating parameters of said refrigeration system includinga. head pressure, andb. suction pressure;

C. signal processing circuits connected to said temperature sensors and said pressure sensors for receiving said respective electrical signals therefrom for producing a sequence of binary digital signals representative of said electrical signals;

D. computer means connected to said signal processing circuits for receiving said sequence of binary digital signals, said computer means having memory means for storing system design parameters, said computer means programmed to periodically calculate other operating parameters of said refrigeration system includinga. relative humidity,b. efficiency of said refrigeration system,c. temperature difference between said condensing temperature and said wet bulb temperature,d. difference between said head pressure and said suction pressure, ande. the cost to operate said refrigeration system;

E. control relays connected to said computer means for controlling, in said refrigeration system,a. condenser fans in response to calculated value of said difference between said condensing temperature and said wet bulb temperature,b. condenser pumps responsive to the calculated value of said difference between said condensing temperature and said wet bulb temperature, andc. compressor loading responsive to calculated value of said diffference between said head pressure and said suction pressure; and

F. first alarm means responsive to a deviation of said head pressure relative to said condensing temperature to indicate presence of non-condensible gases in said refrigeration system, and second alarm means responsive to said difference between said condensing temperature and said wet bulb temperature to indicate fouled condensers in said refrigeration system.

View all claims

0 Assignments

Timeline View

Assignment View

0 Petitions

Accused Products

Abstract

A system and method for managing energy in large refrigeration systems and the like by continuously monitoring operating parameters and controlling to optimize the refrigeration system elements. A multiplicity of remote sensors is disposed at the appropriate points in the refrigeration system to produce analog electrical signals representative of various temperatures such as wet bulb temperature, dry bulb temperature, condensing temperature, evaporator air temperature, evaporator refrigerant temperature, and similar temperatures, and various pressures such as head pressure, booster suction pressure, intermediate suction pressure, and the like. A signal processor is provided to receive signals from the sensors, to condition the analog signals, convert to digital signals and to feed a digital computer which has a memory for storing system design parameters and refrigerant characteristics. The digital computer calculates the instantaneous system operating parameters from the digital signals, compares these parameters to the design parameters, and operates control relays to load and unload compressors to maintain optimum system pressures, to energize and deenergize fans and pumps in accordance with the system requirements, and to produce alarms when non-condensible gases and/or fouled condensers are indicated in the refrigeration system. In systems subject to frost build up on the evaporator, defrost cycles are also controlled by the computer to occur only when necessary.

288 Citations

36 Claims

1. An energy management system for a single stage refrigeration system having evaporative type condensers comprising:
- A. a plurality of electrical temperature sensors attached to said refrigeration system, said sensors producing electrical signals representative of operating parameters of said refrigeration system includinga. wet bulb temperature,b. dry bulb temperature,c. condensing temperature, andd. ambient temperature;
  
  B. a plurality of electrical pressure sensors attached to said refrigeration system, said pressure sensors producing electrical signals representative of operating parameters of said refrigeration system includinga. head pressure, andb. suction pressure;
  
  C. signal processing circuits connected to said temperature sensors and said pressure sensors for receiving said respective electrical signals therefrom for producing a sequence of binary digital signals representative of said electrical signals;
  
  D. computer means connected to said signal processing circuits for receiving said sequence of binary digital signals, said computer means having memory means for storing system design parameters, said computer means programmed to periodically calculate other operating parameters of said refrigeration system includinga. relative humidity,b. efficiency of said refrigeration system,c. temperature difference between said condensing temperature and said wet bulb temperature,d. difference between said head pressure and said suction pressure, ande. the cost to operate said refrigeration system;
  
  E. control relays connected to said computer means for controlling, in said refrigeration system,a. condenser fans in response to calculated value of said difference between said condensing temperature and said wet bulb temperature,b. condenser pumps responsive to the calculated value of said difference between said condensing temperature and said wet bulb temperature, andc. compressor loading responsive to calculated value of said diffference between said head pressure and said suction pressure; and
  
  F. first alarm means responsive to a deviation of said head pressure relative to said condensing temperature to indicate presence of non-condensible gases in said refrigeration system, and second alarm means responsive to said difference between said condensing temperature and said wet bulb temperature to indicate fouled condensers in said refrigeration system.
- View Dependent Claims (3, 4, 5, 6, 7, 8, 9, 10, 11, 17)
- - 3. The system as defined in claim 1 or 2 which further comprises display means connected to said computer means for displaying said operating parameters including said other operating parameters.
  - 4. The system as defined in claim 1 or 2 in which said temperature sensors include a resistance element having a change in resistance with temperature.
  - 5. The system as defined in claim 1 or 2 in which said pressure sensors are sources of current in which said current varies with pressure applied to said sensors.
  - 6. The system as defined in claim 1 or 2 in which said signal processing circuits include:
    - analog multiplexer for selectively scanning said plurality of electrical sensors;
      
      programmable gain amplifier connected to said analog multiplexer for sequentially receiving respective electrical signals from said electrical sensors, said amplifier controllable by said computer means to provide scaling of said electrical signals; and
      
      analog-to-digital converter connected to receive amplified electrical signals from said amplifier and to convert said amplified signals to said sequence of binary digital signals.
  - 7. The system as defined in claim 1 or 2 in which:
    - said computer means includes a microprocessor programmed to perform said periodic calculations and to activate said control relays when required responsive to said calculations; and
      
      said memory means includes random access memory, programmable read only memory, and parameter memory, said parameter memory having a parameter patch panel to permit insertion of system specific data for said refrigeration system, said parameter memory thereby adapted to be modified on occasion.
  - 8. The system as defined in claim 7 in which said computer means further includes printer control logic and external printer for periodically logging refrigeration system operating parameters and controls effected.
  - 9. The system as defined in claim 1 or 2 in which said control relays include override means for manually disabling said control of said relays by said computer.
  - 10. The system as defined in claims 1 or 2 in which said control relays include means for automatically overriding said relays when a failure in said energy management system occurs.
  - 11. The system as defined in claim 1 or 2 in which said first and second alarm means include visual and audible alarms.
  - 17. The system as defined in claim 1 or 2 in which said control relays deenergize said condenser pumps when said wet bulb temperature signals indicate freezing conditions in said condensers.

2. An energy management system for a double stage refrigeration system having evaporative type condensers, booster compressors, and main compressors, comprising:
- A. a plurality of electrical temperature sensors attached to said refrigeration system, said sensors producing electrical signals representative of the following operating parameters of said refrigeration system,a. wet bulb temperature,b. dry bulb temperature,c. condensing temperature,d. evaporator air temperature,e. evaporator refrigerant temperature, andf. ambient temperature;
  
  B. a plurality of electrical pressure sensors attached to said refrigeration system, said pressure sensors producing electrical signals representative of the following operating parameters of said refrigeration systema. head pressure,b. intermediate suction pressure, andc. booster suction pressure;
  
  C. signal processing circuits connected to said temperature sensors and said pressure sensors for receiving said respective electrical signals therefrom for producing a sequence of binary digital signals representative of said respective electrical signals;
  
  D. computer means connected to said signal processing circuits for receiving said sequence of binary digital signals, said computer means having memory means for storing system design parameters, said computer means programmed to periodically calculate other operating parameters of said refrigeration systema. relative humidity,b. efficiency of said refrigeration system,c. temperature difference between said condensing temperature and said wet bulb temperature,d. difference between said head pressure and said booster suction pressure,e. the cost to operate said refrigeration system, andf. difference between said evaporator air temperature and said evaporator refrigerant temperature;
  
  E. control relays connected to said computer means for controlling, in said refrigeration system,a. condenser fans in response to the calculated value of said difference between said condensing temperature and said wet bulb temperature,b. condenser pumps responsive to the calculated value of said difference between said condensing temperature and said wet bulb temperature, andc. compressor loading responsive to calculated value of said difference between said head pressure and said booster suction pressure; and
  
  F. first alarm means responsive to a deviation of said head pressure relative to said condensing temperature to indicate presence of non-condensible gases in said refrigeration system, and second alarm means responsive to said difference between said condensing temperature and said wet bulb temperature to indicate fouled condensers in said refrigeration system.
- View Dependent Claims (12, 13, 14, 15, 16)
- - 12. The system as defined in claim 2 which further comprises evaporator defrosting means responsive to said difference between said evaporator air temperature and said evaporator refrigerant temperature.
  - 13. The system as defined in claim 12 in which the design value of said difference between said evaporator air temperature and said evaporator refrigerant temperature is stored in said memory means, and said evaporator defrost means is activated when said difference between said evaporator air temperature and said evaporator refrigerant temperature is greater than said design difference.
  - 14. The system as defined in claim 13 in which:
    - a low threshold difference between said evaporator air temperature and said evaporator refrigerant temperature is stored in said memory means; and
      
      said control relays include control of the evaporator fans in said referigeration system, said control relays deenergizing said evaporator fans when said calculation of the difference between said evaporator air temperature and said evaporator refrigerant temperature is less than said stored lower threshold difference.
  - 15. The system as defined in claim 2 in which:
    - said control relays control loading and unloading of the main compressors in said refrigeration system; and
      
      said computer means is programmed to periodically calculate an optimum value of said intermediate pressure from said sequences of binary digital signals representative of said head pressure and said booster suction pressure, said computer thereby controlling the loading of said main compressors to produce said optimum intermediate pressure.
  - 16. The system as defined in claim 15 in which said calculation of optimum value is in accordance with the relationship that the absolute value of said optimum intermediate pressure is the absolute booster suction pressure multiplied by the square root of the quotient of the absolute head pressure and the absolute suction pressure.

18. An energy management system for a refrigeration system or the like having evaporative condensers comprising:
- first temperature sensing means for producing a first signal representative of the web bulb temperature in and around said condensers;
  
  second temperature sensing means for producing a second signal representative of the condensing temperature of said refrigeration system;
  
  pressure sensing means for producing a third signal representative of the head pressure of said refrigeration system;
  
  memory means for storing pressure-temperature data representative of the head pressure/condensing temperature relationship of the refrigerant of said refrigeration system, and a design difference-temperature between the design wet bulb temperature and the design condenser temperature; and
  
  calculation means connected to said first and second temperature sensing means for receiving said first and second signals, to said pressure sensing means for receiving said third signal and to said memory means, said calculation means for comparing the sensed head pressure and the sensed condensing temperature to said pressure-temperature data in said memory, and for calculating the difference between said sensed wet bulb temperature and said sensed condensing temperature, and for comparing such difference temperature to said design difference-temperature stored in said memory, said calculation memory means thereby determining the efficiency of said refrigeration system.
- View Dependent Claims (19, 20, 21, 22, 23, 24, 25, 26)
- - 19. The system as defined in claim 18 which includes display means for displaying the value of such calculated efficiency.
  - 20. The system as defined in claim 18 in which said calculation means initiates an alarm indicating a fouled condenser when such temperature difference is greater than the design difference temperature.
  - 21. The system as defined in claim 18 in which said calculation means initiates a non-condensible gases alarm when the relationship of the sensed values of head pressure and condensing temperature deviate from the relationship indicated in said stored pressure-temperature data.
  - 22. The system as defined in claim 18 in which said first temperature sensing means is a resistance bulb, whose resistance varies with temperature, disposed adjacent to an evaporative condenser in said refrigeration system, and said second temperature sensing means is a resistance bulb, whose resistance varies with temperature, disposed in contact with condensed refrigerant in said refrigeration system.
  - 23. The system as defined in claim 18 in which said pressure sensing means is a pressure transducer producing a current proportional to the pressure thereon, said transducer connected to the refrigerant line between said condensers and the receiver of said refrigeration system.
  - 24. The system as defined in claim 18 in which said calculation means includes means for displaying the calculated difference temperature.
  - 25. The system as defined in claim 18 in which said calculation means controls relay means for deenergizing condenser fans and condenser pumps when the calculated temperature difference is less than a preselected lower value.
  - 26. The system as defined in claim 18 in which said calculation means controls relay means for deenergizing said condenser pumps when the sensed wet bulb temperature indicates a freezing value.

27. In a single stage refrigeration system having evaporate condensers, the method of managing energy in the system to minimize operating costs comprising the steps of:
- storing in a memory the pressure and condensing temperature characteristics of the refrigerant, the design value of the web bulb temperature in the condensers, the design value of condensing temperature, the design value of the head pressure, the design value of the suction pressure, and the cost per ton per hour for maximum load;
  
  monitoring electrically the operational parameters of dry bulb temperature, web bulb temperature, head pressure, condensing temperature, and suction pressure;
  
  processing the monitored electrical signals for input to a digital computer;
  
  periodically calculating in the computer the relationship of the head pressure and the condensing temperature during operation of the refrigeration system;
  
  comparing such relationship to the stored characteristics of the refrigerant;
  
  energizing a non-condensible gases alarm when such relationship deviates from the stored relationship;
  
  calculating in the computer the temperature difference between the condensing temperature and the web bulb temperature;
  
  comparing such temperature difference to the difference between the stored design condensing temperature and design wet bulb temperature;
  
  energizing a fouled condenser alarm when such calculated temperature difference is greater than such stored design difference;
  
  deenergizing condenser fans and condenser pumps when such temperature difference is a selected value less than such stored difference;
  
  calculating in the computer the pressure difference between the head pressure and the suction pressure;
  
  comparing such pressure difference to the difference between the stored design head pressure and stored design suction pressure;
  
  correcting the stored cost per ton per hour for a maximum load when such calculated pressure difference is less than such stored difference; and
  
  displaying the corrected cost per ton per hour.
- View Dependent Claims (30, 31, 32)
- - 30. The method as defined in claim 27 or 28 which further comprises the steps of:
    - calculating in the computer the efficiency of the refrigeration system when the relationship of the monitored head pressure and condensing temperature deviate from the stored relationship; and
      
      displaying the calculated efficiency.
  - 31. The method as defined in claim 27 or 28 which further comprises the steps of:
    - storing in the memory a preselected lower threshold of the temperature difference between the condensing temperature and the wet bulb temperature;
      
      comparing the calculated temperature difference between the condensing temperature and the web bulb temperature with the stored lower threshold temperature difference;
      
      deenergizing condenser fans and condenser pumps when such calculated temperature difference is less than the stored lower threshold temperature difference; and
      
      displaying the calculated temperature difference.
  - 32. The method as defined in claim 27 or 28 in which the step of monitoring the wet bulb temperature includes the step of deenergizing condenser pumps when the monitored wet bulb temperature indicates freezing conditions in the condensers.

28. In a two stage refrigeration system having booster compressors, main compressors, and evaporative condensers, the method of managing energy in the system to minimize operating costs comprising the steps of:
- storing in a memory the pressure and condensing temperature characteristics of the refrigerant, the design value of the wet bulb temperature in the condensers, the design value of condensing temperature, the design value of the head pressure, the design value of the booster suction pressure, the design value of the intermediate suction pressure, and the cost per ton per hour for maximum load;
  
  monitoring electrically the operational parameters of dry bulb temperature, wet bulb temperature, head pressure, condensing temperature, booster suction pressure, intermediate suction pressure, evaporator air temperature, and evaporator refrigerant temperature;
  
  processing the monitored electrical signals for input to a digital computer;
  
  periodically calculating in the computer the relationship of the head pressure and the condensing temperature during operation of the refrigeration system;
  
  comparing such relationship to the stored characteristics of the refrigerant;
  
  energizing a non-condensible gases alarm when such relationship deviates from the stored relationship;
  
  calculating in the computer the temperature difference between the condensing temperature and the wet bulb temperature;
  
  comparing such temperature difference to the difference between the stored design condensing temperature and design wet bulb temperature;
  
  energizing a fouled condenser alarm when such calculated temperature difference is greater than such stored design difference;
  
  deenergizing condenser fans and condenser pumps when such temperature difference is a selected value less than such stored difference;
  
  calculating in the computer the pressure difference between the head pressure and the booster suction pressure;
  
  comparing such pressure difference to the difference between the stored design head pressure and stored design booster suction pressure;
- View Dependent Claims (33, 34, 35, 36)
- - 33. The method as defined in claim 28 which further comprises the steps of:
    - calculating in the computer from the monitored head pressure and the monitored booster suction pressure the optimum value of the intermediate suction pressure;
      
      comparing such calculated optimum suction pressure value to the monitored intermediate suction pressure value; and
      
      controlling the loading on the main compressors when the monitored intermediate suction pressure is not equal to the calculated optimum intermediate suction pressure to thereby optimize the intermediate suction pressure.
  - 34. The method as defined in claim 28 which further comprises the steps of:
    - comparing the monitored booster suction pressure to the stored design value of booster suction pressure; and
      
      controlling the loading of the booster compressors when the monitored value of booster suction pressure is not equal to the stored design value thereof to thereby optimize the booster suction pressure.
  - 35. The method as defined in claim 28 which further comprises the steps of:
    - storing in the memory a design value of the difference between the evaporator air temperature and the evaporator refrigerant temperature;
      
      periodically calculating in the computer the temperature difference between the monitored evaporator air temperature and the monitored evaporator refrigerant temperature;
      
      comparing such evaporator temperature difference to the stored design evaporator temperature difference; and
      
      deenerigizing the evaporator fans and initiating a defrost cycle in the evaporator when the evaporator temperature difference is greater than the stored design evaporator temperature difference.
  - 36. The method as defined in claim 34 which further comprises the steps of:
    - storing in the memory a predetermined lower limit of the difference between the evaporator air temperature and the evaporator refrigerant temperature;
      
      deenergizing the evaporator fans when the calculated evaporator temperature difference is less than the stored lower limit of the evaporator temperature difference; and
      
      displaying the calculated evaporator temperature difference.

29. correcting the stored cost per ton per hour for a maximum load when such calculated difference is less than such stored difference;
- anddisplaying the corrected cost per ton per hour.

Specification

Resources

Litigation Campaign Assessment

Current Assignee
Robert J. Cantley
Original Assignee
Robert J. Cantley
Inventors
Cantley, Robert J.
Primary Examiner(s)
Wayner, William E.

Application Number

US06/244,161
Time in Patent Office

400 Days
Field of Search

62/176 C, 62/171, 62/126, 62/127, 62/475
US Class Current

62/126
CPC Class Codes

F25B 1/10   with multi-stage compressio...

F25B 49/02   for compression type machin...

G05D 23/1917   using digital means

Energy management system for refrigeration systems

First Claim

0 Assignments

0 Petitions

Accused Products

Abstract

288 Citations

36 Claims

Specification

Solutions

Use Cases

Quick Links

Energy management system for refrigeration systems

First Claim

0 Assignments

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

288 Citations

36 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links