Classifications

• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
  • F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
  • F25D17/00—Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces
  • F25D17/02—Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating liquids, e.g. brine
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F24—HEATING; RANGES; VENTILATING
  • F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
  • F24F11/00—Control or safety arrangements
  • F24F11/30—Control or safety arrangements for purposes related to the operation of the system, e.g. for safety or monitoring
  • F24F11/46—Improving electric energy efficiency or saving
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
  • F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
  • F25B2400/00—General features or devices for refrigeration machines, plants or systems, combined heating and refrigeration systems or heat-pump systems, i.e. not limited to a particular subgroup of F25B
  • F25B2400/06—Several compression cycles arranged in parallel
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
  • F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
  • F25B2600/00—Control issues
  • F25B2600/13—Pump speed control
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
  • Y02B30/00—Energy efficient heating, ventilation or air conditioning [HVAC]
  • Y02B30/70—Efficient control or regulation technologies, e.g. for control of refrigerant flow, motor or heating

Definitions

• the present invention generally relates to systems and methods for reducing energy consumption of a chilled water distribution system by monitoring and controlling a variable speed drive within a base or controlled chiller station.
• a conventional chilled water system typically includes a cooling loop having a return and a supply line both in fluid communication with at least two chilling stations and with at least two buildings.
• the water supply pressures produced at the chilling stations are relatively high, which in turn may cause any number of undesired consequences.
• the high pressures may reduce an operational life of the system even though a standard maintenance schedule is followed.
• the high pressures may require more frequent maintenance, which in turn leads to higher costs.
• the high pressures may necessitate the installation of pressure reducing valves, but while such valves may drop the incoming chilled water pressures their installation increases capital costs and system control complexity.
• the pressure reducing valves may not adequately close off against the high pressures and over-cooling can become a problem.
• a chilled water distribution system includes a chilled water loop in fluid communication with a plurality of buildings and also in fluid communication with a plurality of chiller stations.
• a monitoring and control system communicates with one of the chiller stations, hereinafter referred to as a "controlled" chiller station because it is configured with one or more variable frequency drives that are controlled by the monitoring and control system to modulate the speed of at least one chiller station component such as, but not limited to, a pump or a fan.
• a differential pressure of the chilled water loop may be maintained in a "sweet spot" so as to optimize chiller station output while minimizing chiller station energy consumption.
• a distributed process chilled water system includes a supply line having a supply line pressure sensor; a return line having a return line pressure sensor, the supply line pressure sensor and the return line pressure sensor cooperating to provide a differential pressure between the supply line and the return line; a plurality of buildings, each building having a building automation system controller, each building in fluid communication with the return and supply lines, the controllers communicatively networked together; a plurality of chiller stations comprising at least one base chiller station, each chiller station in fluid communication with the return and supply lines, the chiller stations communicatively networked together, at least one of the chiller stations in communication with at least one of the buildings; and an operating system operable to process machine-readable instructions, the operating system in communication with at least the base chiller station, the operating system configured to receive a signal indicative of the differential pressure, the operating system further configured, based on the differential pressure, to determine whether to modulate a pump speed of the base chiller station, bring another chiller online or take
• a method for controlling a chilled water distribution system includes the steps of (1) determining a real-time differential pressure at a selected location within a chilled water loop of the distribution system; (2) monitoring a realtime pump speed of a base chiller station that includes a variable frequency drive coupled to a chilled water pump; (3) determining an energy load for a plurality of buildings served by the chilled water loop; (4) modulating the pump speed of the base chiller station to approximately stay within a desired range of pre-determined set point differential pressures of the chilled water loop; and (5) determining whether to change the capacity of distribution system by bringing a chiller of another chiller station either online or offline.
• FIGURE 1 is a schematic system diagram of a chilled water distribution system having an operating system in communication with at least one controlled chiller station to modulate a pump speed within the chiller station and/or to bring other chillers either online or offline according to an embodiment of the present invention
• FIGURE 2A is a schematic system diagram of a controlled chiller station having at least one variable speed drive coupled to at least one chilled water pump according to an embodiment of the present invention
• FIGURE 2B is a schematic system diagram of another chilled water distribution system according to an embodiment of the present invention.
• FIGURE 3 is a flow diagram of a method for determining a mode of operation for a controlled chiller station according to an embodiment of the present invention.
• FIGURE 4 is a chart for indicating a sweet spot range for operating a controlled chiller station according to an embodiment of the present invention.
• the chilled water supply pressures produced at various chilling stations are relatively high, which in turn results in several consequences for the buildings served by the chilled water loop.
• the high chilled water supply pressure for buildings close to the chilling station may necessitate the installation of pressure reducing valves to drop the incoming chilled water supply pressure, which increases capital costs and system complexity in terms of control, installation, and maintenance.
• the high chilled water supply pressure may mean that certain types of control valves cannot close off against the high pressure and combined with low cooling water temperatures this may create an over-cooling situation that requires heating compensation. Further, the high chilled water supply pressure may result in increased maintenance costs and maintenance frequency for all of the components in the system affected by the high pressure.
• At least one aspect of the present invention involves a chilled water distribution system that supplies one or more buildings.
• a building may generally include any structure that utilizes a chilled water supply line of the system and demands a non-zero load.
• the term "load” may generally mean a flow requirement needed by the building's cooling unit, which may take the form of a roof-top cooling unit. Flow requirements are often referred to in terms of tonnage of water, for example a particular building may require 5,000 tons of water from the system to meet its present cooling and/or heating needs.
• the load required by a particular building often fluctuates throughout even a single day due to temperature changes, weather changes, time of day (e.g. , primary work hours), etc.
• the chilled water distribution system may be controlled by monitoring a chilled water loop pressure differential between the supply line and a return line to maintain a minimum pressure that still allows the chiller stations and the building's cooling units to function adequately. Reducing the chilled water loop differential pressure (i.e. , the difference in pressure between the chilled water supply and chilled water return) may realize a number of advantages.
• the chilled water distribution system of the present invention and methods of operating the same may advantageously reduce overall energy use (i.e. , consumption) of the entire system and reduce energy use for at least two networked chilling stations, which in turn would reduce chilled water production costs and chilled water rates.
• the reduction in chilling station energy use may more than make up for any increased power consumption in one or more of the loads. Further, the maintenance costs associated with high pressure related problems may be reduced for the chilled water loop, the chiller stations and the loads.
• FIGURE 1 shows a schematic system diagram for a chilled water distribution system 100 having a chilled water loop or conduit 102 in fluid communication with a plurality of buildings 104 (individually illustrated as buildings 104a - 104d) and also in fluid communication with a plurality of chiller stations 106 (individually illustrated as chiller stations 106a - 106d).
• a monitoring and control system 107 communicates with one of the chiller stations 106, and in particular chiller station 106a, which is the chiller station 106a that is specifically configured with one or more variable frequency drives (not shown) for variably controlling a speed of at least one chiller station component such as, but not limited to, a pump or a fan.
• the chilled water loop 102 includes a supply loop 102a and a return loop 102b.
• Pressure sensors 108 are in communication with the supply and return loops 102a, 102b, respectively, and a pressure difference between the sensor readings provides a chilled water differential pressure. Although two pressure sensors 108 are shown, the system 100 may include a plurality of sensors for taking pressure readings at various locations around the chilled water loop 102.
• Each building 104 includes a building automation system (BAS) 110 (individually 110a - HOd).
• the BASs 110 receive and exchange operating information with the respective building's heating, ventilation and cooling (HVAC) system.
• HVAC heating, ventilation and cooling
• the BASs may take the form of the BASs described in U.S. Patent Application Nos. 12/609,452 and/or 12/874,607, both of which are incorporated herein by reference in their entireties.
• the BASs may be networked together so they may receive and exchange information with each other, the chiller stations and the monitoring and control system 107.
• the BASs 110 may operate independently from another while each communicates with the monitoring and control system 107.
• each chiller station 106 communicates with at least one other chiller station to provide a networked communication link.
• Chiller station 106a communicates directly with the monitoring and control system 107.
• the chiller station 106a operates as the primary chiller station in the group in response to the load requirements of the buildings and in conjunction with each chiller station's output and processing capacity.
• the monitoring and control system 107 takes the form of an operating system having relational control algorithms that automatically calculate the most efficient operation of the chilled water distribution system 100, to include the various components or subsystems within such as, but not limited to, chillers, pumps and cooling tower fans based on real-time, building cooling loads.
• the monitoring and control system 107 in operation as described herein may advantageously provide a holistic approach to maximizing energy efficiency while providing a stable operating performance not possible with conventional proportional-integral-derivative control.
• FIGURE 2A shows a close-up, schematic system diagram of a chiller station 206 in fluid communication with a chilled water loop or conduit 202.
• the chiller station 206 includes a plurality of variable speed drives 212 coupled to supply pumps 214, coupled to return pumps 216 and coupled to cooling tower fans 218, respectively.
• one aspect of the present invention is the monitoring and control of the variable speed drives 212 to quickly respond to real-time building load changes without requiring that the chillers 215 run at either full capacity or zero capacity as happens with conventional, existing systems.
• FIG. 2B shows a schematic system diagram for a chilled water distribution system 200 having a chilled water loop or conduit 202 in fluid communication with a plurality of buildings 204 and also in fluid communication with a plurality of chiller stations 206, which may take the form of the chiller stations 206 described in FIGURE 2A.
• the chilled water loop 202 includes a plurality of pressure sensors 208 for monitoring a differential pressure between a return line and a supply line.
• the BASs for the buildings are not shown.
• each chiller station 206 includes one or more variable frequency drives 212 for variably controlling a speed of a supply pump 214, a return pump 216 and/or a cooling tower fan 218.
• a monitoring and control system (not shown) communicates directly with at least one of the chiller stations 206.
• the chiller station 206 in communication with the monitoring and control system is the chiller station shown on the right hand side and will be referred to hereinafter as the "controlled" chiller station.
• the differential pressure of the chilled water loop 202 may be monitored at several locations and the speed (i.e., power) of at least one of the supply pumps 214 of the primary chiller station may be continuously monitored.
• Each of the differential pressure locations will have a minimum required differential pressure for the buildings to function properly (e.g. , temperature, humidity, etc.).
• the speed of the chilled water supply pumps 214 at the primary chilling station will be modulated to maintain the minimum differential pressure at all of these differential pressure locations.
• information from the building's chilled water pumps for instance pump speed taken from the BAS, will allow the monitoring and control system to perform an analysis in real time or at least contemporaneously in time that ensures that any reduction in pressure at one or more of the chilling stations 206 does not adversely affect the operation of the building.
• pump speed taken from the BAS will allow the monitoring and control system to perform an analysis in real time or at least contemporaneously in time that ensures that any reduction in pressure at one or more of the chilling stations 206 does not adversely affect the operation of the building.
• the differential pressure at one or more locations became too low then this may cause an overall increase in energy consumption among the buildings 204 in aggregate.
• FIGURE 3 shows a flow diagram for a process 300 for controlling the chiller stations based on the differential pressure readings at desired locations throughout the chilled water loop.
• information is obtained by the various buildings by the respective BASs.
• information about the primary chiller station operation is obtained.
• the monitoring and control system analyzes the information 302, 304 to determine a mode of operation as indicated by decision gate 308.
• a first mode of operation (Mode 1), the chiller stations are each online, but none are at capacity.
• the monitoring and control system simply continues to monitor the incoming information as indicated by block 310.
• a second mode of operation (Mode 2), one or more of the chiller stations are operating at capacity or may soon be at capacity based on information from the building BASs.
• the monitoring and control system determines if one of the chillers at one of the chiller stations should be brought online or if online already then whether its capacity should be increased by signaling the variable speed drive for the respective pump.
• one or more of the chiller stations are operating substantially below capacity or may soon be operating at substantially below capacity based on information from the building BASs.
• the monitoring and control system determines if one or more chillers at one of the chiller stations should be brought offline and/or which chiller should have its capacity decreased.
• the control of one or more variable frequency drives coupled to the chilled water pumps may significantly reduce overall energy consumption for the buildings in aggregate.
• the chilled water distribution system shown in FIGURE 2 may be for various buildings on a college campus.
• the primary chiller station may be required to meet an average load of approximately 12,000 tons of chilled water and accomplishes this with three chillers online in the primary chiller station.
• the monitoring and control system determines which chiller or chillers to bring online at one or more of the other chiller stations.
• the monitoring and control system determines when to bring the extra chiller or chillers online on an as- needed basis so as to minimize fluctuations in the chiller stations' steady state operations and thereby reduce overall energy consumption.
• the pump speed at chiller station 106a controls the differential pressure of the chilled water loop 102 to maintain a desired minimum differential pressure.
• the pump speed at chiller station 106c provides only flow/output control in response to the total output at chiller station 106a.
• the monitoring and control system 107 monitors the pump speeds at chiller stations 106a and 106c, the chiller flow/output of chillers stations 106a and 106c, the total flow/output of chiller stations 106a and 106c and the differential pressure at selected locations throughout the chilled water loop 102.
• the monitoring and control system 107 then calculates pump speed for the pumps at chiller stations 106a and 106c and also determines the total number of pumps to be operated at chiller stations 106a and 106c.
• the monitoring and control system 107 may be pre-programmed to store all of the operational set points for flow, output capacity (e.g. , tons of chilled water), pump speed, number of pumps in operation for one chiller station, and the desired differential pressure a various locations in the chilled water loop 102. Further, each of these set points may adjustable as building loads change for a variety of reasons.
• the chilled water loop pressure may be controlled and a minimum energy level (e.g. , Kilowatt per Ton) for the entire system may be achieved by controlling the speed of the pumps at chiller station 106a and bringing other chiller stations either online or offline to maintain the minimum differential pressure in the chilled water loop.
• a minimum energy level e.g. , Kilowatt per Ton
• chiller station 106c may be referred to as the "flow controlled" chiller station because it is the only chiller station besides chiller station 106a to have variable speed drives on its chilled water pumps.
• variable frequency drives may be installed on other chilled water pumps in other chilled water stations.
• the monitoring and control system will control the sequence of operation to operate the controlled chiller station in its "sweet spot" (see FIGURE 4) in terms of energy efficiency and then bring online one or more individual pumps and chillers of other chiller stations.
• FIGURE 4 is a schematic diagram showing how the baseline or "controlled" chiller station operates over a range of capacities or flow rates.
• the controlled chiller station may operate at a maximum flow rate to generate a maximum differential pressure 402 in the chilled water loop or the controlled chiller station may operate at a minimum flow rate to generate a minimum differential pressure 404 in the chilled water loop.
• the monitoring and controlling system 107 functions to control the flow rate of the controlled chiller station to maintain the differential in the chilled water loop between a maximum 406 and minimum 408 set point differential pressure, and thus within a "sweet spot" 410.
• the monitoring and control system will determine whether a second individual chiller at one of the other chiller stations should be brought online or offline to move back into the "sweet spot" 410 and still adequately meet the current chilled water load requirements of the buildings.
• chilling station 206 (controlled chiller station) can handle the entire load. Specific differential pressure measurements from around the chilled water loop 202 will be continuously monitored. The monitoring and control system 207 will determine which of the differential pressure locations should be used for control purposes.
• a minimum set point for one of the buildings 204 is six pound-force per square inch gauge (psig) and another building (say the lower right building in FIGURE 2B) has a minimum set point of two psig, but the actual pressure at the upper left building is six psig and the actual pressure at the lower right building is five psig then the differential pressure for the upper left building would be used for control. Because the minimum set point for the building dictating control is being met by the actual pressure then the monitoring and control system 207 would command the chilled water pump speeds and chilled flow rates at the controlled chiller station 206 to remain constant.
• the differential pressure throughout the chilled water loop 202 may decrease and one or more of the measured pressure locations may drop below its required set point.
• the monitoring and control system 207 will then begin to increase the chilled water pump speeds at the controlled chiller station 206, which will also increase pump flow until the requisite set point differential pressure is again achieved.
• the chilled water pump speeds are incrementally increased until the requisite set point differential pressure is achieved.
• the differential pressure throughout the chilled water loop 202 would correspondingly increase, which may cause one or more of the measured pressure locations to rise above their required set points.
• the monitoring and control system 207 will begin to decrease the chilled water pump speeds at the controlled chiller station 206, which also decreases pump flow until the actual differential pressure in the chilled water loop 202 meets the required set point pressure in the same.
• the chilled water pump speeds are incrementally decreased until the requisite set point differential pressure is achieved.
• the controlled chiller station 206 when the controlled chiller station 206 reaches its maximum output, depending on the anticipated building cooling loads for the remainder of the day, one or both of the other chiller stations may need to be brought on line. Conversely, when the controlled chiller station 206 reaches its minimum output the monitoring and control system 107 (FIGURE 1) would no longer control the pump speed at the controlled chiller station 206, but instead would maintain the pump speed at its minimum speed while temporarily disregarding the high loop differential pressure. Depending on the anticipated building load requirements for the remainder of the day, the controlled chiller station 206 may need to be taken off line.
• the monitoring and control system will modulate pump speed (flow) to generate a corresponding change for maintaining the chilled water loop set point, differential pressure. Since there are multiple differential pressures throughout the loop and multiple minimum set points, the monitoring and control system may also determine which of the differential pressure's is the "controlling differential pressure" at any point in time. In addition to modulating pump speed, the monitoring and control system may also determine the optimum number of chilled water supply pumps that should be in operation at any given time.
• the monitoring and control system alerts the operator to either start or stop a pump, and once accepted by the operator, the BOP system will then start or stop the pump just as it currently does. Consequently, the monitoring and control system attempts to maintain the chilled water distribution system in the "sweet spot" where the desired capacity of the building loads is sufficiently met by the controlled chiller station as other chillers within other chiller stations are brought online or offline. Hence, the pump speed, and thus output, of the controlled chiller station is modulated to maintain the desired chilled water loop differential pressure as selected by the monitoring and control system.
• the monitoring and control system modulates the pump speed of another chiller station brought online to keep the output of the controlled chiller station in the desired "sweet-spot".
• the chilled water pumps at the non-controlled chiller station do not react to loop pressure and will maintain a constant flow unless the output of controlled chiller station goes outside of the desired "sweet-spot".

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• Engineering & Computer Science (AREA)
• Chemical & Material Sciences (AREA)
• Combustion & Propulsion (AREA)
• Mechanical Engineering (AREA)
• General Engineering & Computer Science (AREA)
• Physics & Mathematics (AREA)
• Thermal Sciences (AREA)
• Air Conditioning Control Device (AREA)

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Publications (2)

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• 2018
  • 2018-08-21 EP EP18847766.5A patent/EP3673218A4/de not_active Withdrawn
  • 2018-08-21 WO PCT/US2018/047225 patent/WO2019040435A1/en unknown
  • 2018-08-21 CN CN201880053806.3A patent/CN111094882A/zh active Pending

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