JP5806555B2 - Heat source machine control device and heat source machine control method - Google Patents

Description

  The present invention relates to a heat source machine control device and a heat source machine control method for controlling the number of operating heat source machines based on the load state of heat source water to an external load.

  Conventionally, a heat source device that supplies heat source water to an air conditioner or a district heating / cooling customer provided in a tenant building includes a plurality of heat source devices, and a primary pump provided as an auxiliary device for each of these heat source devices. The heat source water from the heat source unit is sent to the forward header by the primary pump and supplied to the external load (heat load such as air conditioners and fan coils, consumers of district cooling and heating, etc.) via the forward water pipeline. ing.

  In this heat source device, the heat source water heat-exchanged by the external load is returned to the return header via the return water pipeline, enters the heat source unit again, and circulates through the above path. For example, when the heat source machine is a refrigerator, the heat source water is cold water and circulates through the above-described path. When the heat source machine is a heater, the heat source water is warm water and circulates in the above-described path. The forward header and the return water line are communicated by a bypass line, and a bypass valve is provided in the bypass line.

  The heat source device is provided with a heat source device control device that controls the operation of the heat source device. The heat source controller controls the differential pressure between the forward header and the return header, and the opening of the bypass valve, that is, the flow rate of the heat source water flowing through the bypass line (bypass flow rate) so as to make this differential pressure constant. The temperature of the heat source water sent from the forward header (water feed temperature) TS, the temperature of the heat source water returned to the return header (return water temperature) TR, and the flow rate of the heat source water returned to the return header (load flow rate) ) From F, the current load heat quantity W is obtained as F × (TR-TS) (W = F × (TR-TS)), and the number of operating heat source devices is controlled according to the obtained current load heat quantity W. To do. Alternatively, the number of operating heat source units is controlled according to the load flow rate F.

  In this case, an operation order table is set in the heat source unit control device, and in the example of controlling the number of operating heat source units according to the load heat amount W, the load heat amount W is a predetermined value as shown in FIG. Until the temperature reaches W1, the heat source machine of the designated rank 1 is operated. When the load heat amount W1 exceeds the predetermined value W1, the operation of the heat source machine of the designated rank 2 is started in addition to the heat source machine of the designated rank 1. If the load heat amount W exceeds the predetermined value W1 and becomes equal to or less than the predetermined value W1 ′ (W1 ′ <W1), the operation of the heat source unit of the designated rank 2 is stopped. When the operation of the heat source device is started, the primary pump that is an auxiliary device of the heat source device is also turned on in conjunction with the operation, and the operation is started. When the operation of the heat source machine is stopped, the primary pump that is an auxiliary machine of the heat source machine is also turned off in conjunction with the operation, and the operation is stopped (see, for example, Patent Document 1).

[Number correction function based on return temperature (forced stop function)]
Non-Patent Document 1 describes the number correction function (forced stop function) based on the return temperature. In this unit correction function based on the return temperature, if the return temperature falls below a certain value (cooling) or exceeds a certain value (heating), the heat source unit is turned off. One unit is forcibly stopped. This is a function for avoiding the stop by the heat source unit thermostat.

[Stop all heat source units]
When the above-described heat source unit control device is provided with the function of correcting the number of units based on the return temperature, if the number of operating heat source units is one and the state where the return water temperature TR is below a certain value continues for a certain time (when cooling ) Or when the return water temperature TR exceeds a certain value for a certain period of time (during heating), the operation of all the heat source devices is stopped. Thereby, at the time of low load, operation | movement of all the heat source machines is stopped, and energy saving is achieved.

  In this case, if all the primary pumps are also stopped, the detection of the return water temperature TR cannot be continued. Therefore, even after the operation of all the heat source devices is stopped, the primary pump of the last heat source device is not turned off and the on state (normal operation (continuous operation)) is continued. As a result, when the return water temperature TR exceeds a certain value during cooling (when cooling) or when the return water temperature TR falls below a certain value (when heating), the operation of the heat source apparatus is resumed. It becomes possible to return to normal operation number control.

JP 2008-18673 A

Introduction to automatic control of environmentally symbiotic generation building equipment, Technical Shoin, p. 176, 2007/04).

  However, according to the heat source unit control apparatus having the function of correcting the number of units based on the return temperature described above, the primary pumps of the last heat source unit are turned on even after the operation of all the heat source units is stopped, and the normal operation is performed. Since (continuous operation) is continued, the power consumption of the primary pump is one factor that hinders energy saving at low loads.

  In Patent Document 2, the opening degree of a valve (air conditioner valve) that adjusts the amount of heat source water flowing into the air conditioner is monitored, and the number of operating heat source machines is determined based on the opening degree of the air conditioner valve. A heat source machine control device adapted to control the above is shown. According to the heat source device control apparatus disclosed in Patent Document 2, if all the valves of the air conditioner are fully closed, the operation of all the heat source devices is stopped. In this case, since it is not necessary to continue the detection of the return water temperature, the operation of all the primary pumps can be stopped.

  However, in the heat source apparatus control device disclosed in Patent Document 2, the opening degree of the air conditioner valve must be input to the heat source apparatus control apparatus, and wiring between the air conditioner valve and the heat source apparatus control device is required. And engineering is necessary, and there is a problem that construction is difficult.

  The present invention has been made to solve such a problem, and the object of the present invention is to provide a heat source machine control device and a heat source that can promote energy saving at low loads without involving difficult construction. It is to provide a machine control method.

In order to achieve such an object, the present invention conveys the first to Nth (N ≧ 1) heat source units that generate heat source water and the heat source water generated by the first to Nth heat source units. In the first to N-th primary pumps, the forward header that receives the heat source water from the first to N-th heat source units, the external load that receives the supply of the heat source water sent from the forward header, and the external load A heat source control device used in a heat source device including a return header that returns heat-exchanged heat source water to the first to Nth heat source units, and a bypass pipe that communicates the forward header and the return header, When the heat source unit operation number determination means to determine the number of heat source unit operation based on the load condition of the heat source water to the external load, and when the load condition of the heat source water to the external load is in a low load state below the predetermined value The first to Nth heat source machines are stopped, and the first to Nth primary ports are stopped. And a total heat halting means for operating at low power consumption state defined either a single advance of the flop, the total heat source machine stopping means, the one or the primary pump of the first to N It is characterized by intermittent operation with a predetermined duty ratio .

In the present invention, the total heat source unit stopping means stops all of the first to Nth heat source units when the load state of the heat source water to the external load is in a low load state below a predetermined value, Any one of the first to Nth primary pumps is intermittently operated at a predetermined duty ratio. Accordingly, any one of the first to Nth primary pumps is operated in a predetermined low power consumption state.

In the present invention, for example, in a state of low power consumption, any one of the first to N-th primary pumps is intermittently operated with a duty ratio as a time during which the capacity shortage can be allowed on the load side.

  In the present invention, for example, in a low load state, when the heat amount of the heat source water to the external load is lower than a predetermined value, or the water supply temperature of the heat source water supplied from the forward header is lower than the predetermined capacity value. If it is high (if it is cold water, the water supply temperature is lower than the predetermined value), or if the return water temperature of the heat source water returned to the return header is higher than a predetermined capacity value (if cold water, the return water temperature is In the case of lower than a predetermined value), all of the first to Nth heat source units are stopped, and any one of the first to Nth primary pumps is in a predetermined low power consumption state. Try to drive.

  It should be noted that the present invention can be similarly configured even in a system using a secondary pump. In the system using the secondary pump, when the load state of the heat source water to the external load is a low load state lower than a predetermined value, the first to Nth heat source machines and the first to Nth primary pumps Are stopped, and any one of the first to Mth secondary pumps is operated in a predetermined low power consumption state.

Moreover, this invention is also realizable as a heat source machine control method used for a heat source apparatus. The inventions according to claims 7 to 12 use the invention according to the heat source machine control device of claims 1 to 6 as a method.

According to the present invention, when the load state of the heat source water to the external load is in a low load state below a predetermined value, all of the first to Nth heat source machines are stopped and the first to Nth heat source machines are stopped. Since any one of the primary pumps is operated intermittently (with low power consumption) at a predetermined duty ratio, energy saving at low load can be promoted without difficult construction. It becomes possible.

It is an instrumentation figure which shows the principal part (application example to a primary pump system) of one Embodiment of the heat-source apparatus using the heat-source equipment control apparatus which concerns on this invention. It is a flowchart for demonstrating the 1st example (Embodiment 1) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a flowchart for demonstrating the 2nd example (Embodiment 2) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a flowchart for demonstrating the 3rd example (Embodiment 3) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a flowchart for demonstrating the 4th example (Embodiment 4) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a flowchart for demonstrating the 5th example (Embodiment 5) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a flowchart for demonstrating the 6th example (Embodiment 6) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a functional block diagram of the principal part of the heat source machine control apparatus of Embodiment 1,2. It is a functional block diagram of the principal part of the heat-source equipment control apparatus of Embodiment 3,4. It is a functional block diagram of the principal part of the heat-source equipment control apparatus of Embodiment 5,6. It is an instrumentation figure which shows the principal part (application example to a secondary pump system) of other embodiment of the heat-source apparatus using the heat-source equipment control apparatus which concerns on this invention. It is a flowchart for demonstrating the 1st example (Embodiment 7) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a flowchart for demonstrating the 2nd example (Embodiment 8) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a flowchart for demonstrating the 3rd example (Embodiment 9) of the operation number control function and stop control function of all the refrigerators which the heat-source equipment control apparatus used for this heat-source apparatus has. It is a figure explaining a mode that the number of operation of a heat source machine is controlled according to load calorie | heat amount.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is an instrumentation diagram showing a main part of an embodiment of a heat source device using a heat source machine control device according to the present invention. In addition, in the following description, what is not included in the scope of the right of the present invention is described as an embodiment, but here, it will be described as an embodiment.

  In the figure, 1-1 to 1-n are refrigerators that generate cold water, 2-1 to 2-n are primary pumps that convey the cold water generated by refrigerators 1-1 to 1-n, and 3 is a refrigerator. Outbound headers for receiving cold water from the machines 1-1 to 1-n, 4 is an outward load pipe, 5 is an external load for receiving the supply of cold water sent from the forward header 3 through the outbound water line 4 (air conditioner A heat load such as a fan coil, a consumer of district heating and cooling, etc.), 6 is a return pipe. The external load 5 is provided with a valve 5-1 for adjusting the flow rate of supplied cold water.

  Reference numeral 7 denotes a return header to which the cold water sent through the return water pipe 6 is exchanged by heat exchange in the external load 5, 8 is a bypass pipe that connects the forward header 3 and the return header 7, and 9 is a bypass pipe 8. The bypass valve 10 is provided with a differential pressure gauge 10 for measuring the differential pressure ΔP of the cold water between the forward header 3 and the return header 7, and 11 is the temperature of the cold water from the forward header 3 to the external load 5 as the water supply temperature TS. A water supply temperature sensor to be measured, 12 is a return water temperature sensor for measuring the temperature of cold water returned to the return header 7 as a return water temperature TR, and 13 is a flow rate of cold water to be returned to the return header 7 (cool water supplied to the external load 5). 14 (14A) is a heat source apparatus control device according to the present invention.

  In this heat source device, the return water pumped by the primary pumps 2-1 to 2-n is cooled by the refrigerators 1-1 to 1-n, reaches the forward header 3, and passes through the forward water pipe 4 to the outside. Supplied to the load 5. And it heat-exchanges in the external load 5, returns to the return header 7 via the return water pipe 6, is pumped again by the primary pumps 2-1 to 2-n, and circulates the above path | route.

  The heat source controller 14A monitors the differential pressure ΔP between the forward header 3 and the return header 7 measured by the differential pressure gauge 10, and opens the opening θ of the bypass valve 9 so that the differential pressure ΔP is constant. That is, the flow rate (bypass flow rate) of the cold water flowing through the bypass line 8 is controlled. Further, the heat source device control device 14A calculates F × (TR-TS) from the water supply temperature TS from the water supply temperature sensor 11, the return water temperature TR from the return water temperature sensor 12, and the load flow rate F from the flow meter 13. ), The current load heat quantity W is obtained (W = F × (TR-TS)), and the number of operating refrigerators 1-1 to 1-n is controlled according to the obtained current load heat quantity W. Moreover, the operation | movement of the primary pumps 2-1 to 2-n provided as an auxiliary machine with respect to each of the refrigerator 1-1 to 1-n is controlled.

  The heat source machine control device 14A is realized by hardware including a processor and a storage device, and a program that realizes various functions as a control device in cooperation with these hardware. The operation number control function of the machines 1-1 to 1-n and the stop control function of all refrigerators are provided. Hereinafter, according to the flowcharts shown in FIGS. 2 to 7, the operation number control function and the stop control function of all the refrigerators included in the heat source apparatus control device 14A will be described.

[Embodiment 1]
FIG. 2 is a flowchart for explaining a first example (Embodiment 1) of the operation number control function and the stop control function of all refrigerators included in the heat source apparatus control device 14A. In the first embodiment, the primary pumps 2-1 to 2-n are controlled to be turned on / off by the heat source apparatus control device 14A.

[Control of the number of operating refrigerators]
The heat source machine control device 14A measures the current load at regular intervals (step S101). In this example, the current load heat amount W is obtained from the water supply temperature TS from the water supply temperature sensor 11, the return water temperature TR from the return water temperature sensor 12, and the load flow rate F from the flow meter 13.

  If the load heat quantity W is not W = 0 (no load) (NO in step S102), the number of operating refrigerators 1-1 to 1-n is controlled according to the obtained current load heat quantity W. (See step S103, FIG. 15).

  In the control of the number of operating refrigerators, when the operation of the refrigerator 1 is started, the primary pump 2 that is an auxiliary device of the refrigerator 1 is also turned on, and the operation of the primary pump 2 is started. When the operation of the refrigerator 1 is stopped, the primary pump 2 that is an auxiliary device of the refrigerator 1 is also turned off, and the operation of the primary pump 2 is stopped.

  Therefore, for example, when the refrigerator 1-1 is the final-stage refrigerator in the step-down direction, the refrigerator 1-1 and the primary pump 2-1 are operated until the load heat quantity W exceeds W1. . In this case, the primary pump 2-1 is continuously operated.

[Stop control of all refrigerators]
On the other hand, if the load heat quantity W becomes W = 0 (no load) (YES in step S102), the heat source apparatus control device 14A stops the operation of the refrigerator 1-1 in the final stage in the step-down direction ( Step S104). Thereby, the operation of all the refrigerators 1 is stopped, and the number of operated refrigerators 1 becomes zero.

  Further, the heat source device control device 14A intermittently operates the primary pump 2-1 that is an auxiliary device of the refrigerator 1-1 at the same time as the operation of the refrigerator 1-1 is stopped (step S105). ). In this example, the operation / stop of the primary pump 2-1 is repeated in a cycle of about 10 minutes. Due to the intermittent operation of the primary pump 2-1, the return water from the return header 7 continues to flow along the route of the forward header 3, the bypass conduit 8, and the return header 7 through the refrigerator 1-1.

  As a result, the cold water can be supplied from the forward header 3 to the external load 5, and the measurement of the water supply temperature TS, the measurement of the return water temperature TR, and the measurement of the load flow rate F are continued in the heat source apparatus control device 14A. When all the refrigerators are stopped, if the load heat quantity W satisfies W> 0 (NO in step S102), the operation number control of the refrigerators is immediately returned (step S103).

  In the first embodiment, when no load is applied, all of the refrigerators 1-1 to 1-n are stopped, and the operation of the primary pump 2-1 of the refrigerator 1-1 that is stopped last is continued in an intermittent operation. Therefore, compared with the method of continuing the operation of the primary pump 2-1 in the normal operation (continuous operation), the power consumption in the primary pump 2-1 is reduced and the energy saving is promoted. .

[Intermittent operation with a duty ratio that allows the load to run out of capacity]
In the first embodiment, the primary pump 2-1 is intermittently operated while all the refrigerators are stopped. In this case, the load cannot be measured while the primary pump 2-1 is stopped. However, as shown as step S105 ′ in FIG. It becomes possible to return to the normal number control within a time that allows the shortage.

[Embodiment 2]
FIG. 3 is a flowchart for explaining a second example (Embodiment 2) of the operation number control function and the stop control function of all refrigerators included in the heat source apparatus control device 14A. In the second embodiment, it is assumed that the primary pumps 2-1 to 2-n are each provided with an inverter for adjusting the rotational speed. In this case, 14 A of heat-source equipment control apparatuses control the rotation speed by sending an inverter frequency to the primary pumps 2-1 to 2-n.

[Control of the number of operating refrigerators]
The heat source machine control device 14A measures the current load at regular intervals (step S201). In this example, the current load heat amount W is obtained from the water supply temperature TS from the water supply temperature sensor 11, the return water temperature TR from the return water temperature sensor 12, and the load flow rate F from the flow meter 13.

  Here, if the load heat quantity W is not W = 0 (no load) (NO in step S202), the number of operating refrigerators 1-1 to 1-n is controlled according to the obtained current load heat quantity W. (See step S203, FIG. 15).

  In the control of the number of operating refrigerators, when the operation of the refrigerator 1 is started, the inverter frequency to the primary pump 2 that is an auxiliary machine of the refrigerator 1 is set to 100%, and the primary pump 2 is operated at the rated rotational speed. To drive. Further, when the operation of the refrigerator 1 is stopped, the inverter frequency to the primary pump 2 that is an auxiliary device of the refrigerator 1 is set to 0%, and the operation of the primary pump 2 is stopped.

  Therefore, for example, when the refrigerator 1-1 is the last-stage refrigerator in the decreasing direction, the refrigerator 1-1 and the primary pump 2-1 are operated until the load heat quantity W exceeds W1. The In this case, the primary pump 2-1 is operated at the rated speed.

[Stop control of all refrigerators]
On the other hand, if the load heat quantity W becomes W = 0 (no load) (YES in step S202), the heat source apparatus control device 14A stops the operation of the refrigerator 1-1 in the final stage in the step-down direction ( Step S204). Thereby, the operation of all the refrigerators 1 is stopped, and the number of operated refrigerators 1 becomes zero.

  Further, the heat source device control device 14A reduces the inverter frequency to the primary pump 2-1 that is an auxiliary device of the refrigerator 1-1 simultaneously with the stop of the operation of the refrigerator 1-1 (step S205). Due to the operation of the primary pump 2-1 with the inverter frequency lowered, the return water from the return header 7 flows through the refrigerator 1-1 through the path of the forward header 3, the bypass pipe 8, and the return header 7. to continue.

  As a result, the cold water can be supplied from the forward header 3 to the external load 5, and the measurement of the water supply temperature TS, the measurement of the return water temperature TR, and the measurement of the load flow rate F are continued in the heat source apparatus control device 14A. When all the refrigerators are stopped and the load heat quantity W becomes W> 0 (NO in step S202), the operation number control of the refrigerators is immediately returned (step S203).

  In the second embodiment, when no load is applied, all of the refrigerators 1-1 to 1-n are stopped, and the operation of the primary pump 2-1 of the refrigerator 1-1 that has been stopped last is reduced in inverter frequency. Therefore, compared with the method of continuing the operation of the primary pump 2-1 with the normal operation (inverter frequency 100%), the power consumption in the primary pump 2-1 is reduced and the energy saving is promoted. Will be.

[Operation at minimum flow rate]
In the second embodiment, the primary pump 2-1 is operated with the inverter frequency lowered while all the refrigerators are stopped. In this case, since the refrigerator 1-1 is stopped, the flow rate value of the return water flowing to the refrigerator 1-1 is made smaller than the minimum flow rate value Q _LOW required when the refrigerator 1-1 is operated. It is possible.

Therefore, as shown in FIG. 3 as step S205 ′, when the primary pump 2-1 is operated with the inverter frequency lowered, the flow rate of the return water to the refrigerator 1-1 is set during the operation of the refrigerator 1-1. When the inverter frequency f _MIN is set so that the minimum flow rate value Q _MIN is smaller than the required minimum flow rate value Q _LOW , the power consumption in the primary pump 2-1 is reduced as much as possible. It becomes possible to further promote energy saving.

[Embodiment 3]
FIG. 4 is a flowchart for explaining a third example (Embodiment 3) of the operation number control function and the stop control function of all refrigerators included in the heat source apparatus control device 14A. In the third embodiment, the primary pumps 2-1 to 2-n are controlled to be turned on / off by the heat source device control device 14A.

[Control of the number of operating refrigerators]
The heat source machine control device 14A measures the current water supply temperature TS at regular intervals (step S301). Here, if water supply temperature TS is 7.5 degreeC or more (NO of step S302), 14 A of heat source machine control apparatuses will measure the present load (step S305).

  In this example, the current load heat amount W is obtained from the water supply temperature TS from the water supply temperature sensor 11, the return water temperature TR from the return water temperature sensor 12, and the load flow rate F from the flow meter 13.

  Then, the number of operating refrigerators 1-1 to 1-n is controlled according to the obtained current load heat amount W (see step S306, FIG. 15).

[Stop control of all refrigerators]
If the water supply temperature TS is below 7.5 ° C. (YES in step S302), the heat source controller 14A determines that the capacity is excessive (low load) and stops the operation of all the refrigerators 1. (Step S303). As a result, the number of operating refrigerators 1 becomes zero.

  Further, the heat source device control device 14A intermittently operates the primary pump 2-1 of the last-stage refrigerator 1-1 in the decreasing direction simultaneously with the stop of the operation of all the refrigerators 1 ( Step S304). All other primary pumps 2 are stopped. In this example, the operation / stop of the primary pump 2-1 is repeated in a cycle of about 10 minutes. Due to the intermittent operation of the primary pump 2-1, the return water from the return header 7 continues to flow along the route of the forward header 3, the bypass conduit 8, and the return header 7 through the refrigerator 1-1.

  Thereby, the supply of cold water from the forward header 3 to the external load 5 is enabled, and the measurement of the water supply temperature TS, the measurement of the return water temperature TR, and the measurement of the load flow rate F are continued in the heat source apparatus control device 14A. .

  When the water supply temperature TS becomes 7.5 ° C. or higher while all the refrigerators are stopped (NO in step S302), the heat source controller 14A performs current load measurement (step S305) and controls the number of operating refrigerators. Is resumed (step S306).

  In this third embodiment, when the water supply temperature TS is below 7.5 ° C., it is determined that the capacity is excessive (low load), and all the refrigerators 1-1 to 1-n are stopped. Since the operation of the primary pump 2-1 of the chiller 1-1 in the final stage in the decreasing direction is continued with intermittent operation, the operation of the primary pump 2-1 is continued with normal operation (continuous operation). Compared with the method of making it, the power consumption in the primary pump 2-1 is reduced, and energy saving is promoted.

[Intermittent operation with a duty ratio that allows the load to run out of capacity]
In Embodiment 3, the primary pump 2-1 is intermittently operated while all the refrigerators are stopped. In this case, the load cannot be measured while the primary pump 2-1 is stopped. However, as shown as step S304 ′ in FIG. It becomes possible to return to the normal number control within a time that allows the shortage.

[Embodiment 4]
FIG. 5 is a flowchart for explaining a fourth example (Embodiment 4) of the operation number control function and the stop control function of all refrigerators included in the heat source apparatus control device 14A. In the fourth embodiment, it is assumed that the primary pumps 2-1 to 2-n are each provided with an inverter for adjusting the rotational speed. In this case, 14 A of heat-source equipment control apparatuses control the rotation speed by sending an inverter frequency to the primary pumps 2-1 to 2-n.

[Control of the number of operating refrigerators]
The heat source machine control device 14A measures the current water supply temperature TS at regular intervals (step S401). Here, if water supply temperature TS is 7.5 degreeC or more (NO of step S402), 14 A of heat-source equipment control apparatuses will measure the present load (step S405).

  In this example, the current load heat amount W is obtained from the water supply temperature TS from the water supply temperature sensor 11, the return water temperature TR from the return water temperature sensor 12, and the load flow rate F from the flow meter 13.

  Then, the number of operating refrigerators 1-1 to 1-n is controlled in accordance with the obtained current load heat amount W (see step S406, FIG. 15).

[Stop control of all refrigerators]
If the water supply temperature TS is below 7.5 ° C (YES in step S402), the heat source controller 14A determines that the capacity is excessive (low load) and stops the operation of all the refrigerators 1. (Step S403). As a result, the number of operating refrigerators 1 becomes zero.

  In addition, the heat source device control device 14A reduces the inverter frequency to the primary pump 2-1 of the final-stage refrigerator 1-1 in the decreasing direction simultaneously with the stop of the operation of all the refrigerators 1 (step S404). ). All other primary pumps 2 are stopped. Due to the operation of the primary pump 2-1 with the inverter frequency lowered, the return water from the return header 7 flows through the refrigerator 1-1 through the path of the forward header 3, the bypass pipe 8, and the return header 7. to continue.

  Thereby, the supply of cold water from the forward header 3 to the external load 5 is enabled, and the measurement of the water supply temperature TS, the measurement of the return water temperature TR, and the measurement of the load flow rate F are continued in the heat source apparatus control device 14A. .

  When the water supply temperature TS becomes 7.5 ° C. or higher while all the refrigerators are stopped (NO in step S402), the heat source controller 14A performs current load measurement (step S405), and controls the number of operating refrigerators. Is resumed (step S406).

  In this Embodiment 4, when the water supply temperature TS is lower than 7.5 ° C. at the time of low load, it is determined that the state is excessive capacity (low load state), and all of the refrigerators 1-1 to 1-n. Is stopped, and the operation of the primary pump 2-1 of the chiller 1-1 in the final stage in the step-down direction is continued with the inverter frequency lowered, so that the operation of the primary pump 2-1 is performed normally. Compared with the method of continuing with operation (inverter frequency 100%), the power consumption in the primary pump 2-1 is reduced, and energy saving is promoted.

[Operation at minimum flow rate]
In the fourth embodiment, the primary pump 2-1 is operated with the inverter frequency lowered while all the refrigerators are stopped. In this case, since the refrigerator 1-1 is stopped, the flow rate value of the return water flowing to the refrigerator 1-1 is made smaller than the minimum flow rate value Q _LOW required when the refrigerator 1-1 is operated. It is possible.

Therefore, as shown in FIG. 5 as step S404 ′, when the primary pump 2-1 is operated at a reduced inverter frequency, the flow rate of the return water to the refrigerator 1-1 is set during the operation of the refrigerator 1-1. When the inverter frequency f _MIN is set so that the minimum flow rate value Q _MIN is smaller than the required minimum flow rate value Q _LOW , the power consumption in the primary pump 2-1 is reduced as much as possible. It becomes possible to further promote energy saving.

[Embodiment 5]
FIG. 6 is a flowchart for explaining a fifth example (Embodiment 5) of the operation number control function and the stop control function of all refrigerators included in the heat source apparatus control device 14A. In the fifth embodiment, the primary pumps 2-1 to 2-n are controlled to be turned on / off by the heat source apparatus control device 14A.

  The fifth embodiment is almost the same as the third embodiment. In the third embodiment, the water supply temperature TS is used to determine whether or not to stop all the refrigerators. Water temperature TR is used. In this case, if the return water temperature TR falls below 10 ° C. (YES in step S502), the operation of all the refrigerators 1 is stopped (step S503), and if the return water temperature TR becomes 10 ° C. or more (in step S502). NO), the control of the number of operating refrigerators is resumed according to the current load heat quantity W (step S506). Since others are the same as Embodiment 3, the description is abbreviate | omitted.

[Embodiment 6]
FIG. 7 is a flowchart for explaining a sixth example (Embodiment 6) of the operating unit control function and the stop control function of all refrigerators included in the heat source apparatus control device 14A. In the sixth embodiment, it is assumed that the primary pumps 2-1 to 2-n are each provided with an inverter for adjusting the rotational speed. In this case, 14 A of heat-source equipment control apparatuses control the rotation speed by sending an inverter frequency to the primary pumps 2-1 to 2-n.

  The sixth embodiment is almost the same as the fourth embodiment. In the fourth embodiment, the water supply temperature TS is used to determine whether or not to stop all the refrigerators. Water temperature TR is used. In this case, if the return water temperature TR is lower than 10 ° C. (YES in step S602), the operation of all the refrigerators 1 is stopped (step S603), and if the return water temperature TR becomes 10 ° C. or more (in step S602). NO), the control of the number of operating refrigerators is resumed according to the current load heat quantity W (step S606). Since others are the same as those of the fourth embodiment, the description thereof is omitted.

  FIG. 8 shows a functional block diagram of a main part of the heat source machine control device 14A of the first and second embodiments. In the first and second embodiments, the heat source apparatus control device 14A is obtained by the load heat amount calculation unit 141 that obtains the current load heat amount W from the water supply temperature TS, the return water temperature TR, and the load flow rate F, and the load heat amount calculation unit 141. The load status determination unit 142 that determines whether or not the current load heat amount W is W = 0 (no load), and when the load status determination unit 142 determines that there is no load, the control of the number of operating refrigerators And a total refrigerator stop control unit 144 that controls stop of all refrigerators when the load status determination unit 142 determines that there is no load.

In the first embodiment, the all-chiller stop control unit 144 stops the operation of the last-stage refrigerator 1-1 in the reduction direction, and sets the primary pump 2-1 of the refrigerator 1-1 to a predetermined level. Operates intermittently at a duty ratio. For example, intermittent driving is performed using a time during which the capacity shortage can be tolerated on the load side as a duty ratio. In the second embodiment, the all-chiller stop control unit 144 stops the operation of the last-stage refrigerator 1-1 in the decreasing direction and the inverter to the primary pump 2-1 of the refrigerator 1-1. Reduce the frequency. For example, the inverter frequency f _MIN is set such that the minimum flow rate value Q _MIN is smaller than the minimum flow rate value Q _LOW .

  FIG. 9 shows a functional block diagram of a main part of the heat source machine control device 14A of the third and fourth embodiments. In the third and fourth embodiments, the heat source controller 14A performs a load heat amount calculation unit 141 that obtains the current load heat amount W from the water supply temperature TS, the return water temperature TR, and the load flow rate F, and controls the number of operating refrigerators. Based on the water supply temperature TS, it is determined whether or not there is an excessive capacity state (low load state) based on the chiller operation number control unit 143 to be performed, the total chiller stop control unit 144 ′ that performs stop control of all chillers, An overcapability state determination unit 145.

  In the third embodiment, the all refrigerator stop control unit 144 ′ is determined to be in an overcapacity state (low load state) by the overcapacity state determination unit 145 (the water supply temperature TS is below 7.5 ° C.). In this case, the operation of all the refrigerators 1 is stopped, and the primary pump 2-1 of the final-stage refrigerator 1-1 in the decreasing direction is intermittently operated at a predetermined duty ratio. For example, intermittent driving is performed using a time during which the capacity shortage can be tolerated on the load side as a duty.

In the fourth embodiment, the total refrigerator stop control unit 144 ′ is determined to be in an overcapacity state (low load state) by the overcapacity state determination unit 145 (the water supply temperature TS is less than 7.5 ° C.). In this case, the operation of all the refrigerators 1 is stopped and the inverter frequency to the primary pump 2-1 of the refrigerator 1-1 in the final stage in the step-down direction is decreased. For example, the inverter frequency f _MIN is set such that the minimum flow rate value Q _MIN is smaller than the minimum flow rate value Q _LOW .

  FIG. 10 shows a functional block diagram of a main part of the heat source machine control device 14A of the fifth and sixth embodiments. In the fifth and sixth embodiments, the heat source controller 14A performs a load heat amount calculation unit 141 that obtains the current load heat amount W from the water supply temperature TS, the return water temperature TR, and the load flow rate F, and controls the number of operating refrigerators. Refrigerator operation number control unit 143 to be performed, all chiller stop control unit 144 ′ for controlling stop of all chillers, and whether or not the capacity is excessive (low load state) based on the return water temperature TR And an overcapacity state determination unit 145 ′.

  In the fifth embodiment, the total refrigerator stop control unit 144 ′ is determined to be in an overcapacity state (low load state) by the overcapacity state determination unit 145 ′ (the return water temperature TR is below 10 ° C.). In this case, the operation of all the refrigerators 1 is stopped, and the primary pump 2-1 of the final-stage refrigerator 1-1 in the decreasing direction is intermittently operated at a predetermined duty ratio. For example, intermittent driving is performed using a time during which the capacity shortage can be tolerated on the load side as a duty ratio.

In the sixth embodiment, the total refrigerator stop control unit 144 ′ is determined to be in an overcapacity state (low load state) by the overcapacity state determination unit 145 ′ (return water temperature TR is below 10 ° C.). In this case, the operation of all the refrigerators 1 is stopped and the inverter frequency to the primary pump 2-1 of the refrigerator 1-1 in the final stage in the step-down direction is decreased. For example, the inverter frequency f _MIN is set such that the minimum flow rate value Q _MIN is smaller than the minimum flow rate value Q _LOW .

In the above-described first to sixth embodiments, the current load is measured as the load heat amount W, but may be measured as the load flow rate F.
In the first and second embodiments described above, the operation of all the refrigerators 1 is stopped when there is no load. However, all the refrigerators 1 are operated at a low load determined as a value lower than W1 ′. The operation may be stopped.

  Moreover, in Embodiment 1-6 mentioned above, the driving | operation of the primary pump 2-1 of the freezer 1-1 of the last stage of the reduction | decrease direction (refrigerator 1-1 stopped last) is a state of low power consumption. (Intermittent operation, operation with the inverter frequency lowered) is continued, but one of the other primary pumps in the primary pumps 2-1 to 2-n is operated as the primary pump 2-1. Similarly to the above, it may be continued in a low power consumption state.

  Moreover, although Embodiment 1-6 mentioned above demonstrated the case where a heat source machine was used as the refrigerator, the same operation | movement can be performed also when a heat source machine is used as a heater. In this case, only the logic is reversed, and the basic operation is the same as that of the refrigerator.

  Moreover, although Embodiment 1-6 mentioned above demonstrated as an application example to the system (primary pump system) using only a primary pump, it is the same also in the system (secondary pump system) using a secondary pump. It is possible to apply. FIG. 11 shows an application example to the secondary pump system.

  In this secondary pump system, 3-1 and 3-2 are first and second forward headers provided in a cold water supply path from the refrigerators 1-1 to 1-n to the external load 5, Secondary pumps 15-1 to 15-m are connected in parallel between the first forward header 3-1 and the second forward header 3-2. Further, between the first forward header 3-1 and the second forward header 3-2, a bypass valve 16 is connected to a bypass pipe line 18 that communicates between the forward headers 3-1 and 3-2. Is provided. In addition, a differential pressure gauge 17 for measuring a chilled water pressure difference ΔP between the forward headers 3-1 and 3-2 is provided between the first forward header 3-1 and the second forward header 3-2. Is provided.

  In this secondary pump system, the heat source device control device 14 (14B) monitors the differential pressure ΔP between the forward header 3-1 and the forward header 3-2 measured by the differential pressure gauge 17, and this differential pressure ΔP. Is controlled so that the opening degree θ of the bypass valve 16, that is, the flow rate of cold water flowing through the bypass line 18 (bypass flow rate) is controlled. Further, the heat source device control device 14B calculates F × (TR-TS) from the water supply temperature TS from the water supply temperature sensor 11, the return water temperature TR from the return water temperature sensor 12, and the load flow rate F from the flow meter 13. ), The current load heat quantity W is obtained (W = F × (TR-TS)), and the number of operating refrigerators 1-1 to 1-n is controlled according to the obtained current load heat quantity W. Moreover, the operation | movement of the primary pumps 2-1 to 2-n and the secondary pumps 15-1 to 15-m provided as auxiliary machines with respect to each of the refrigerators 1-1 to 1-n is controlled.

[Embodiment 7]
FIG. 12 is a flowchart for explaining a first example (Embodiment 7) of the operation number control function and the stop control function of all refrigerators included in the heat source apparatus control device 14B, and is shown in FIG. 2 in the primary pump system. This corresponds to the flowchart. In the seventh embodiment, the secondary pumps 15-1 to 15-m are controlled to be turned on / off by the heat source device control device 14B.

[Control of the number of operating refrigerators]
The heat source machine control device 14B measures the current load at regular intervals (step S701). In this example, the current load heat amount W is obtained from the water supply temperature TS from the water supply temperature sensor 11, the return water temperature TR from the return water temperature sensor 12, and the load flow rate F from the flow meter 13.

  Here, if the load heat quantity W is not W = 0 (no load) (NO in step S702), the number of operating refrigerators 1-1 to 1-n is controlled according to the obtained current load heat quantity W. (Step S703, see FIG. 15).

  In the control of the number of operating refrigerators, when the operation of the refrigerator 1 is started, the primary pump 2 that is an auxiliary device of the refrigerator 1 is also turned on, and the operation of the primary pump 2 is started. When the operation of the refrigerator 1 is stopped, the primary pump 2 that is an auxiliary device of the refrigerator 1 is also turned off, and the operation of the primary pump 2 is stopped.

  Therefore, for example, when the refrigerator 1-1 is the final-stage refrigerator in the step-down direction, the refrigerator 1-1 and the primary pump 2-1 are operated until the load heat quantity W exceeds W1. .

  It is assumed that all the secondary pumps 15-1 to 15-m are turned on and the normal operation (continuous operation) is continued during the control of the number of operating refrigerators.

[Stop control of all refrigerators]
On the other hand, if the load heat quantity W becomes W = 0 (no load) (YES in step S702), the heat source controller 14B stops the operation of the refrigerator 1-1 in the final stage in the reduction direction, In conjunction with this, the operation of the primary pump 2-1 which is an auxiliary machine of the refrigerator 1-1 is also stopped (step S704). Thereby, the operation of all the refrigerators 1 is stopped, the operation of all the primary pumps 2 is stopped, and the number of the refrigerators 1 operated becomes zero.

  In addition, the heat source device control device 14B intermittently operates one of the secondary pumps 15-1 to 15-m at a predetermined duty ratio simultaneously with the stop of the operation of the refrigerator 1-1 (step S705). In this case, the operation of the other secondary pumps 15 is stopped. In this example, the operation / stop of the secondary pump 15-1 is repeated in a cycle of about 10 minutes. Due to the intermittent operation of the secondary pump 15-1, the return water from the return header 7 is supplied to the primary pumps 2-1 to 2-n, the refrigerators 1-1 to 1-n, and the first forward header 3-1. , The secondary pump 15-1, the second forward header 3-2, the bypass pipeline 18, the bypass pipeline 8, and the return header 7 continue to flow.

  As a result, it is possible to supply cold water from the forward headers 3-1 and 3-2 to the external load 5, measurement of the water supply temperature TS in the heat source unit control device 14B, measurement of the return water temperature TR, load flow rate When the measurement of F is continued and the load heat amount W becomes W> 0 (NO in step S702) while all the refrigerators are stopped, the operation number control of the refrigerators is immediately returned (step S703).

  In the seventh embodiment, when no load is applied, all of the refrigerators 1-1 to 1-n and the primary pumps 2-1 to 2-n are stopped and the operation of the secondary pump 15-1 is performed intermittently. Since it continues, the power consumption in the secondary pump 15-1 is reduced, and energy saving is promoted.

[Intermittent operation with a duty ratio that allows the load to run out of capacity]
In the seventh embodiment, the secondary pump 15-1 is intermittently operated while all the refrigerators are stopped. In this case, the load cannot be measured while the secondary pump 15-1 is stopped. However, as shown in step S705 'in FIG. It becomes possible to return to the normal number control within a time that allows the shortage.

[Embodiments 8 and 9]
For reference, FIGS. 13 and 14 show the second example (Embodiment 8) and the third example (Embodiment 9) of the operation number control function and the stop control function of all the refrigerators that the heat source unit control device 14B has. A flowchart is shown. The flowcharts shown in FIGS. 13 and 14 correspond to the flowcharts shown in FIGS. 4 and 6 in the primary pump system. Since Embodiments 8 and 9 differ from Embodiments 3 and 5 only in that the pump operated in a low power consumption state is a secondary pump, description thereof is omitted.

[Extension of the embodiment]
The present invention has been described above with reference to the embodiment, but the present invention is not limited to the above embodiment. Various changes that can be understood by those skilled in the art can be made to the configuration and details of the present invention within the scope of the present invention. Each embodiment can be implemented in any combination within a consistent range.

  DESCRIPTION OF SYMBOLS 1 (1-1-1-n) ... Refrigerator, 2 (2-1-2-n) ... Primary pump, 3 ... Outgoing header, 4 ... Outgoing pipe line, 5 ... External load, 5-1 ... Valve , 6 ... Return water line, 7 ... Return header, 8 ... Bypass line, 9 ... Bypass valve, 10 ... Differential pressure gauge, 11 ... Water supply temperature sensor, 12 ... Return water temperature sensor, 13 ... Flow meter, 14 (14A, 14B) ... heat source device control device, 141 ... load heat amount calculation unit, 142 ... load condition determination unit, 143 ... refrigerating machine operation number control unit, 144,144 '... all refrigerator stop control unit, 145,145' ... overcapacity State determination unit, 3-1 ... first forward header, 3-2 ... second forward header, 15 (15-1 to 15-m) ... secondary pump, 16 ... bypass valve, 17 ... differential pressure gauge, 18 ... bypass.

Claims (12)

First to Nth (N ≧ 1) heat source units that generate heat source water, first to Nth primary pumps that transport the heat source water generated by the first to Nth heat source units, and the first A forward header that receives heat source water from the 1st to Nth heat source machines, an external load that receives supply of heat source water sent from the forward header, and the heat source water that is heat-exchanged in the external load A heat source device control device used in a heat source device including a return header that returns to the N heat source device, and a bypass pipe that communicates the forward header and the return header,
Heat source unit operation number determination means for determining the number of operation of the heat source unit based on the load status of the heat source water to the external load;
When the load state of the heat source water to the external load is in a low load state below a predetermined value, all of the first to Nth heat source machines are stopped and the first to Nth primary pumps are stopped. A total heat source machine stop means for operating any one of the above in a state of predetermined low power consumption ,
The total heat source machine stopping means is
Any one of the first to N-th primary pumps is intermittently operated at a predetermined duty ratio . In the heat source machine control device according to claim 1,
The total heat source machine stopping means is
One of the first to N-th primary pumps is intermittently operated with the duty ratio being a time during which the capacity shortage can be allowed on the load side . In the heat source machine control device according to claim 1 or 2 ,
The total heat source machine stopping means is
When the heat amount of the heat source water to the external load is lower than a predetermined value as the low load state, all of the first to Nth heat source machines are stopped and the first to Nth primary pumps are stopped. Any one of the above is operated in the state of low power consumption . In the heat source machine control device according to claim 1 or 2 ,
The total heat source machine stopping means is
When the water supply temperature of the heat source water sent from the forward header as the low load state is higher than a predetermined capacity value, all of the first to Nth heat source machines are stopped and the first to Nth Any one of the primary pumps is operated in the state of low power consumption . In the heat source machine control device according to claim 1 or 2 ,
The total heat source machine stopping means is
When the return temperature of the heat source water returned to the return header as a low load state is higher than a predetermined capacity value, all of the first to Nth heat source machines are stopped and the first to Nth Any one of the primary pumps is operated in the state of low power consumption . First to Nth (N ≧ 1) heat source units that generate heat source water, first to Nth primary pumps that transport the heat source water generated by the first to Nth heat source units, and the first A first forward header that receives heat source water from the 1st to Nth heat source units, a second forward header that receives supply of heat source water sent from the first first forward header, and the second forward header An external load that receives supply of heat source water sent from the forward header, a return header that returns the heat source water heat-exchanged in the external load to the first to Nth heat source units, the forward header, and the return header, A first bypass pipe that communicates with each other, first to M-th (M ≧ 2) secondary pumps connected in parallel between the first forward header and the second forward header, A heat source control used in a heat source device comprising a first forward header and a second bypass conduit communicating with the second forward header An apparatus,
Heat source unit operation number determination means for determining the number of operation of the heat source unit based on the load status of the heat source water to the external load;
When the load condition of the heat source water to the external load is in a low load state below a predetermined value, all of the first to Nth heat source machines and the first to Nth primary pumps are stopped. A total heat source machine stopping means for operating any one of the first to M-th secondary pumps in a predetermined low power consumption state,
The total heat source machine stopping means is
One of the first to M-th secondary pumps is intermittently operated with a predetermined duty ratio . First to Nth (N ≧ 1) heat source units that generate heat source water, first to Nth primary pumps that transport the heat source water generated by the first to Nth heat source units, and the first A forward header that receives heat source water from the 1st to Nth heat source machines, an external load that receives supply of heat source water sent from the forward header, and the heat source water that is heat-exchanged in the external load A heat source device control method applied to a heat source device including a return header that returns to the N heat source device, and a bypass pipe that communicates the forward header and the return header,
A heat source unit operation number determination step of determining the number of operation of the heat source unit based on the load status of the heat source water to the external load;
When the load state of the heat source water to the external load is in a low load state below a predetermined value, all of the first to Nth heat source machines are stopped and the first to Nth primary pumps are stopped. A total heat source unit stop step of operating any one of the above in a state of predetermined low power consumption ,
The total heat source machine stopping step includes:
One of the first to N-th primary pumps is intermittently operated at a predetermined duty ratio . In the heat source machine control method according to claim 7,
The total heat source machine stopping step includes:
Any one of the first to N-th primary pumps is intermittently operated with a duty ratio as a time during which the capacity shortage can be tolerated on the load side.
The heat source machine control method characterized by the above-mentioned . In the heat source machine control method according to claim 7 or 8,
The total heat source machine stopping step includes:
When the heat amount of the heat source water to the external load is lower than a predetermined value as the low load state, all of the first to Nth heat source machines are stopped and the first to Nth primary pumps are stopped. Any one of the above is operated in the low power consumption state
The heat source machine control method characterized by the above-mentioned . In the heat source machine control method according to claim 7 or 8,
The total heat source machine stopping step includes:
When the water supply temperature of the heat source water sent from the forward header as the low load state is higher than a predetermined capacity value, all of the first to Nth heat source machines are stopped and the first to Nth Any one of the primary pumps is operated in the state of low power consumption . In the heat source machine control method according to claim 7 or 8 ,
The total heat source machine stopping step includes:
When the return temperature of the heat source water returned to the return header as a low load state is higher than a predetermined capacity value, all of the first to Nth heat source machines are stopped and the first to Nth Any one of the primary pumps is operated in the state of low power consumption . First to Nth (N ≧ 1) heat source units that generate heat source water, first to Nth primary pumps that transport the heat source water generated by the first to Nth heat source units, and the first A first forward header that receives heat source water from the 1st to Nth heat source units, a second forward header that receives supply of heat source water sent from the first first forward header, and the second forward header An external load that receives supply of heat source water sent from the forward header, a return header that returns the heat source water heat-exchanged in the external load to the first to Nth heat source units, the forward header, and the return header, A first bypass pipe that communicates with each other, first to M-th (M ≧ 2) secondary pumps connected in parallel between the first forward header and the second forward header, A heat source control applied to a heat source device comprising a first bypass header and a second bypass conduit communicating with the second forward header There is provided a method,
A heat source unit operation number determination step of determining the number of operation of the heat source unit based on the load status of the heat source water to the external load;
When the load condition of the heat source water to the external load is in a low load state below a predetermined value, all of the first to Nth heat source machines and the first to Nth primary pumps are stopped. And a total heat source machine stopping step of operating any one of the first to M-th secondary pumps in a predetermined low power consumption state,
The total heat source machine stopping step includes:
One of the first to M-th secondary pumps is intermittently operated at a predetermined duty ratio .

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