JP3828485B2 - Control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a control device used in a heat source device that circulates a heat medium.
[0002]
[Prior art]
FIG. 4 shows an instrumentation diagram of a conventional heat source device. In the figure, G1 to G3 are heat sources that generate a heat medium, P1 to P3 are heat medium pumps that convey the heat medium generated by the heat sources G1 to G3, and 2 is a heat medium (cold water / hot water) from the heat sources G1 to G3. Outer header, 3 for outgoing water pipe, 4 for external load that receives supply of heat medium sent from outgoing header 2 through outgoing water pipe 3 (local cooling / heating customers, air conditioners, fan coils, etc. No. 5 is a return pipe. The heat source G (G1 to G3) is provided with a cooling water pump GP (GP1 to GP3) and a cooling tower fan GF (GF1 to GF3) as auxiliary machines.
[0003]
6 is a return header in which the heat medium exchanged in the external load 4 and sent through the return water pipe 5 is returned, 7 is a bypass pipe that connects the forward header 2 and the return header 6, and 8 is a bypass pipe 7 is a bypass valve, 9 is a differential pressure gauge that measures the pressure difference ΔP of the heat medium between the forward header 2 and the return header 6, and 10 is the temperature of the heat medium from the forward header 2 to the external load 5. A forward water temperature sensor that measures the water temperature TS, a return water temperature sensor 11 that measures the temperature of the heat medium returned to the return header 6 as a return water temperature TR, and a flow rate of the heat medium that returns to the return header 6 (external The flow meter 13 measures the flow rate of the heat medium supplied to the load 5 as the load flow rate F, and 13 is a control device.
[0004]
In this heat source device, the heat medium pumped by the heat medium pumps P1 to P3 is cooled or heated by the heat sources G1 to G3, mixed in the forward header 2, and supplied to the external load 4 through the forward water line 3. . And it heat-exchanges in the external load 4, returns to the return header 6 via the return water pipe 5, is again pumped by the heat medium pumps P1-P3, and circulates the above path | route. For example, when the heat sources G1 to G3 are refrigerators, the heat medium is cold water and circulates through the above-described path. When the heat sources G1 to G3 are heaters, the heat medium is warm water and circulates through the above-described path.
[0005]
The control device 13 monitors the differential pressure ΔP between the forward header 2 and the return header 6 measured by the differential pressure gauge 9, and the opening of the bypass valve 8, that is, the bypass pipe so as to keep this differential pressure ΔP constant. The flow rate (bypass flow rate) of the heat medium flowing through the passage 7 is controlled. The control device 13 controls the number of operating heat sources G1 to G3 and heat medium pumps P1 to P3 according to the load flow rate F measured by the flow meter 12. The heat medium pumps P1 to P3 are turned on / off via the heat sources G1 to G3.
[0006]
In this heat source device, the design capacity (maximum capacity) of the heat sources G1 to G3, the design flow rate (design value of the pump heat medium flow rate when the maximum capacity is exhibited), the transfer capacity (rated flow rate) of the heat medium pumps P1 to P3, etc. It is determined in consideration of the maximum heat load required in the external load 4. For example, when this heat source device is a cold water heat source device, it is assumed that the outgoing water temperature TS is 5 ° C., the return water temperature TR is 14 ° C., and cold water that can cover the maximum heat load required for the external load 4 is necessary. Calculate the flow rate. The required flow rate of this cold water is the product of the temperature difference (outward temperature difference) between the outgoing water temperature TS and the return water temperature TR and the flow rate. It is obtained by dividing by the difference.
[0007]
Here, the required flow rate of cold water is 1008m ^Three / H, the design flow rate per unit of heat source (refrigerator) G is 336 m. ^Three / H, the transfer capacity (rated flow rate) per unit of heat medium pump P is 336m ^Three / H. 336m ^Three The maximum capacity per heat source G is set to, for example, 1000 RT so that the 14 ° C. return water sent at / h can be cooled to 5 ° C. when the maximum capacity is exhibited.
[0008]
Hereinafter, the outline of the processing operation performed by the control device 13 will be described by taking as an example the case where the heat source device is a cold water heat source device. When the heat source activation time is reached (step 501 shown in FIG. 5), the control device 13 activates the first heat source G1 and the heat medium pump P1 (step 502). That is, the cooling water pump GP1 and the cooling tower fan GF1 are turned on to start the operation of the heat source (refrigerator) G1, and the heat medium pump P1 is started at the rated flow rate.
[0009]
Thereby, 336m from the heat medium pump P1 to the heat source G1 ^Three / H heating medium is sent, and this heating medium is made cold water at 5 ° C. in the heat source G 1 and sent to the forward header 2. Here, since the operation of the external load 4 has not yet started (the chilled water valve 4-1 is still closed), the entire amount is returned to the return header 6 through the bypass line 7. At this time, the control device 13 monitors the differential pressure ΔP from the differential pressure gauge 9, and controls the opening degree of the bypass valve 8 so that the differential pressure ΔP becomes constant (step 503).
[0010]
When the operation of the external load 4 is started (YES in step 504), that is, when the chilled water valve 4-1 in the external load 4 is opened, the chilled water sent from the forward header 2 to the bypass pipe 7 is diverted. It is sent to the external load 4. At this time, since the differential pressure ΔP tends to decrease, the control device 13 controls the opening degree of the bypass valve 8 so that the differential pressure ΔP does not decrease (step 505). By controlling the bypass valve 8, the bypass valve 8 is closed as the flow rate of the cold water required by the external load 4 increases. When the bypass valve 8 is fully closed, the entire amount of cold water sent from the heat source G 1 to the forward header 2 is sent to the external load 4.
[0011]
The control device 13 monitors the flow rate of cold water supplied to the external load 4 as the load flow rate F by the flow meter 12, and this load flow rate F is set to a predetermined flow rate F1u ( In this example, 336m ^Three / H) (YES in step 506), the second heat source G2 and the heat medium pump P2 are activated (step 507). That is, the cooling water pump GP2 and the cooling tower fan GF2 are turned on to start the operation of the heat source G2, and the heat medium pump P2 is started at the rated flow rate.
[0012]
As a result, 336 m is passed from the heat medium pump P2 to the heat source G2. ^Three / H heat medium is sent, and this heat medium is made cold water at 5 ° C. in the heat source G 2 and sent to the forward header 2. In this case, since the differential pressure ΔP tends to increase, the control device 13 opens the bypass valve 8 so that the differential pressure ΔP does not increase. Thereby, the excessively generated cold water is returned to the return header 6 through the bypass pipe 7, and the cold water having a required flow rate is supplied to the external load 4.
[0013]
Similarly, the control device 13 controls the opening degree of the bypass valve 8 so that the differential pressure ΔP is constant, and the load flow rate F is a predetermined flow rate F2u (this is determined in advance as a second step-up threshold). In the example, 672m ^Three / H), the third heat source G3 and the heat medium pump P3 are activated. Thereafter, the flow rate of the cold water required by the external load 4 decreases, and the load flow rate F is a predetermined flow rate F2d (in this example, 538 m, which is predetermined as the second step-down threshold). ^Three / H), the operation of the heat source G3 and the heat medium pump P3 is stopped. The flow rate of cold water required by the external load 4 is further reduced, and the load flow rate F is a predetermined flow rate F1d (in this example, 269 m, which is predetermined as the first step-down threshold). ^Three / H), the operation of the heat source G2 and the heat medium pump P2 is stopped (see, for example, Patent Document 1).
[0014]
[Patent Document 1]
Japanese Unexamined Patent Publication No. 2000-18683 (FIG. 2)
[0015]
[Problems to be solved by the invention]
In the cold water heat source device described above, the heat source G is 336 m. ^Three When a heating medium of 14 ° C. is sent at / h, that is, when the temperature difference between the sent heating medium and the generated cold water (5 ° C.) is 9 ° C., the maximum capacity is exhibited. Conversely, 336m ^Three Even if the return water is sent at / h, if the return temperature difference with the generated cold water (5 ° C.) is 9 ° C. or less, the heat source G is operated with its own cooling capacity reduced.
[0016]
When this cold water heat source apparatus is operated in an actual building, the return water temperature TR is actually rarely 14 ° C. and often 14 ° C. or less. This is because chilled water exceeding the design value flows to the external load 4 (valve opening too much, pressure is too much), the amount of air passing through the heat exchanger in the external load 4 is insufficient, or the heat exchanger is deteriorated It can be caused by various causes such as.
[0017]
For example, assuming that only the heat source G1 and the heat medium pump P1 are operated, the outgoing water temperature TS is 5 ° C., but the return water temperature TR is 11 ° C. which is significantly lower than the designed value of 14 ° C. There can be something like that. In this case, the heat source G1 is 336 m ^Three Although it has the maximum capacity to give a temperature difference of 9 ° C (= 14 ° C-5 ° C) to the heating medium of / h, it is self-adjusting to give a temperature difference of 6 ° C (= 11 ° C-5 ° C). Operate with a reduced cooling capacity, and do not demonstrate maximum capacity. To be exact, the heat medium sent to the heat source G1 by the cold water returned to the return header 6 via the bypass pipe 7 becomes lower than the return water temperature TR.
[0018]
In such a state, the flow rate of the cold water required by the external load 4 increases, and the load flow rate F becomes the first stage increase threshold F1u (336m). ^Three / H), although the heat source G1 is operating with a limited capacity, the stage to the heat source G2 is increased. For example, if the capacity of the heat source G1 at this time is set to 60% of the maximum capacity, an increase in the heat source G2 is achieved even though there is still a margin of the cooling capacity of 40%. In order to increase the stage to the heat source G2 while leaving a surplus in the heat source G1, the heat source G2 and the heat medium pump P2 including the cooling water pump GP2 and the cooling tower fan GF2 are started earlier, and the energy Over-consumption.
[0019]
In addition, when the stage to the heat source G2 is increased, surplus cold water is returned from the forward header 2 to the return header 6 through the bypass pipe 7, and the cold water generated by the heat sources G1 and G2 and the heat medium to the heat sources G1 and G2 The temperature difference is further reduced. As a result, the heat sources G1 and G2 are operated with a lower capacity (for example, 30%). The heat source G is designed to have the highest operating efficiency in the state where the maximum capacity is exhibited (full load state) (design conditions are slightly different in the case of an absorption refrigerator), so that the remaining power remains (partial) Driving in a load state and increasing the number of operating units results in excessive consumption of auxiliary machine power, leading to a reduction in operating efficiency of the entire cold water heat source device.
[0020]
[When the transfer capacity of the heat medium pump P is larger than the design flow rate of the heat source G]
For the problem that the operating efficiency of the heat source G decreases because the return water temperature TR is lower than the design value, the transfer capacity (rated flow rate) of the heat medium pumps P1, P2, P3 with respect to the heat sources G1, G2, G3 is set as the heat source G1. , G2 and G3 can be considered to be larger than the designed flow rate. For example, the design flow rate of heat sources G1, G2, G3 (336m) assuming that the heat medium at 14 ° C is cold water at 5 ° C. ^Three / H), the transfer capacity of the heat medium pumps P1, P2, P3 is 600 m ^Three It is possible to increase to / h. In this case, the first increase threshold Fu1 in the control device 13 is set to 600 m. ^Three / H, the second increase threshold Fu2 is 1200 m ^Three If it is / h, even if the return water temperature TR is low and the flow rate of the heat medium is increased, it is possible to suppress an increase in the stage until the heat sources G1 and G2 are in a state of high performance.
[0021]
However, in this method, the heat medium pump P is set to 600 m. ^Three In order to always drive at / h, the amount of energy consumed by the heat medium pump P becomes excessive. In addition, the heat source G is 600m ^Three If the heating medium with a flow rate of / h is cooled from 11 ° C. to 5 ° C. (with a temperature difference of 6 ° C.), if the temperature of the return water to the heat source G is 11 ° C. or higher, the heat source The ability of G1 is insufficient, and cold water at 5 ° C. cannot be generated.
In the above description, the cold water heat source device has been described as an example, but the same problem also occurs in the hot water heat source device.
[0022]
The present invention has been made in order to solve such problems, and its purpose is to have a transfer capacity (rated capacity) larger than the design value (design flow rate) of the pump heat medium flow rate when the maximum capacity of the heat source is exhibited. ) The maximum capacity that is the most efficient operating condition for the heat source even when the temperature difference of the return water is lower than the design value (high capacity) It is an object of the present invention to provide a control device that can increase the number of stages while exhibiting the above, reduce the energy consumption, and operate the heat source device more efficiently.
[0023]
In addition, by using a heat transfer pump that has a transfer capacity (rated flow rate) that is larger than the design value (design flow rate) of the pump heat medium flow rate when the maximum capacity of the heat source is exerted, the temperature difference between the return water and the design value It is possible to increase the stage while the maximum capacity, which is the most efficient operating condition, or the capacity close to it (high capacity) is exhibited even when the heat source is decreasing, and the capacity of the heat source is insufficient. Therefore, in order not to fall into a situation where the temperature of the incoming water is insufficient (rising in the case of cooling, decreasing in the case of heating) It is an object of the present invention to provide a control device that can be operated more efficiently.
[0024]
[Means for Solving the Problems]
In order to achieve such an object, a first invention (invention according to claim 1) is a heat source that generates a heat medium, and a pump that exhibits the maximum capacity of the heat source that conveys the heat medium generated by the heat source. A variable flow rate heat medium pump having a transfer capacity (rated flow rate) larger than the design value (design flow rate) of the heat medium flow rate, a forward header that receives the heat medium from the heat source, and a heat medium that is fed from the forward header Used in a heat source device including an external load that receives the supply of heat, a return header that returns the heat medium exchanged in the external load to the heat source, and a bypass pipe that communicates the forward header and the return header. Compare the flow rate of the heat medium supplied to the external load with the step increase threshold, and increase the number of heat sources and heat medium pumps in operation. A heat source starting means for starting the heat source with the discharge flow rate of the heat medium pump as a predetermined value, and the discharge of the heat medium pump so that the pressure difference of the heat medium between the forward header and the return header is constant When it becomes difficult to make the differential pressure constant by the discharge flow rate control means due to the decrease in the flow rate of the discharge medium and the discharge flow rate control means for controlling the flow rate, the heat medium flowing through the bypass line And a bypass flow rate control means for controlling the flow rate of The increase threshold is determined to be a value larger than the design value of the pump heat medium flow rate when the maximum capacity of the heat source is exerted and less than the transfer capacity of the heat medium pump. Is.
[0025]
For example, when the heat source activation time is reached, the heat source sets the discharge flow rate of the heat medium pump to a predetermined value (for example, 150 m ^Three / H). At this time, if the operation of the external load has not yet started, the entire amount of the heat medium from the heat source is returned to the return header through the bypass pipe. At this time, the control device controls the flow rate of the heat medium flowing through the bypass pipe so that the pressure difference ΔP of the heat medium between the forward header and the return header is constant.
[0026]
When the operation of the external load is started in this state, the heat medium sent from the forward header to the bypass pipe is diverted and sent to the external load. At this time, since the differential pressure ΔP between the forward header and the return header tends to decrease, the control device controls the flow rate (bypass flow rate) of the heat medium flowing through the bypass line so that the differential pressure ΔP does not decrease. To do. By controlling the bypass flow rate, as the flow rate of the heat medium required by the external load increases, the flow rate of the heat medium flowing through the bypass line decreases, and when the bypass flow rate becomes zero, the heat medium sent from the heat source to the forward header. The total amount of is sent to the external load.
[0027]
If the external load further requires a heating medium, no more heating medium can be supplied from the heat source, making it difficult to keep the differential pressure ΔP constant. In this invention, the control device starts to control the discharge flow rate of the heat medium pump that has been set to a predetermined value so as to keep the differential pressure ΔP constant. Thereby, further supply of the heat medium to the external load is performed in a state where the bypass flow rate is zero.
[0028]
As the flow rate of the heat medium required by the external load increases, the discharge flow rate of the heat medium pump increases and eventually the design flow rate of the heat source (for example, 336 m). ^Three / H). In this case, the transfer capacity of the heat medium pump is larger than the design flow rate of the heat source (for example, 600 m ^Three / H), the discharge flow rate of the heat medium pump can be further increased in response to the demand of the external load. Here, the step increase threshold is 600 m. ^Three If it is / h, even if the return water temperature difference is lower than the design value, it is possible to increase the number of stages in a state where the heat source exhibits high performance.
[0029]
On the other hand, if it becomes difficult to make the differential pressure constant by controlling the discharge flow rate of the heat medium pump as the flow rate of the heat medium required by the external load decreases, the flow rate of the heat medium flowing through the bypass line is controlled. It becomes like this. That is, the control is switched from the control of the discharge flow rate of the heat medium pump to the control of the bypass flow rate.
[0030]
It should be noted that the heat medium pump has a rated flow rate (conveyance capacity: 600 m). ^Three / H) is not always driven, but as the flow rate of the heating medium required by the external load increases, a predetermined value (150 m ^Three / H) to the heat source design flow rate (336m) ^Three / H) through the rated flow rate of the heat medium pump (600 m ^Three / H). That is, in the present invention, a heat medium pump having a transfer capacity (rated flow rate) larger than the design flow rate of the heat source is used, but this heat medium pump is not always driven at the rated flow rate, but at each time point. In this case, it is driven only at a flow rate that can cover the flow rate of the heat medium required by the external load. Therefore, the energy consumption of the heat medium pump is much less than when the heat medium pump is always driven at its rated capacity.
[0031]
According to a second invention (invention according to claim 2), in the first invention, the flow rate of the heat medium passing through the heat source is monitored so that the flow rate of the heat medium does not fall below a preset minimum heat medium amount. In addition, a fail-safe means for controlling the discharge flow rate of the heat medium pump is provided. According to this invention, the flow rate of the heat medium passing through the heat source is a preset minimum heat medium amount (for example, 120 m ^Three / H), the discharge flow rate of the heat medium pump is increased.
[0032]
The refrigerator may freeze if the heat medium passing therethrough becomes too small. Therefore, usually, the minimum amount of heat medium is determined, and when the amount is below the minimum amount of heat medium, the refrigerator is automatically stopped. In the first invention, the heat medium pump has a predetermined value (for example, 150 m). ^Three / H), which is a command value to the heat medium pump, and the discharge flow rate of the heat medium pump is actually 150 m. ^Three Whether it is / h or not is not certain. Therefore, in the second invention, the flow rate of the heat medium passing through the heat source is monitored, and the discharge flow rate of the heat medium pump is controlled so as not to fall below the minimum heat medium amount.
[0033]
The third invention (the invention according to claim 3) is the first to Nth (N ≧ 2) heat sources that generate the heat medium and the heat source that conveys the heat medium generated by the first to Nth heat sources. First to Nth flow rate variable heat medium pumps having a transfer capacity (rated flow rate) larger than the design value (design flow rate) of the pump heat medium flow rate when the maximum capacity is exhibited, and the first to Nth heat sources A forward header that mixes the heat medium from the external header, an external load that receives supply of the heat medium sent from the forward header, and a return header that returns the heat medium heat-exchanged in the external load to the first to Nth heat sources And a heat source device including a bypass pipe that communicates the forward header and the return header, and compares the flow rate of the heat medium supplied to the external load with a predetermined increase threshold value and a decrease threshold value. Control device that increases or decreases the number of operating heat sources and heat medium pumps. Threshold change means is provided for changing the increase and decrease thresholds when increasing or decreasing the number of operating heat sources and heat medium pumps according to the temperature difference between the heat transfer medium and the return to the return water header. Is.
[0034]
According to the present invention, the rated flow rate of the heat medium pump is equal to the design flow rate of the heat source (for example, 336 m ^Three / H) (for example, 600 m ^Three / H), for example, assuming that one heat source is in operation, up to 600 m to the external load ^Three / H heating medium can be supplied. Here, the step-up threshold when the number of operating heat sources is one is 600 m. ^Three If it is / h, even when the return water temperature difference is lower than the design value, it is possible to suppress an increase in the stage until the heat source is in a state of high performance.
[0035]
For example, in the cold water heat source apparatus, when the design value of the outgoing water temperature TS is 5 ° C. and the design value of the return water temperature TR is 14 ° C., the actual cold water heat source apparatus has the return water temperature TR of 11 ° C. It can happen. Assuming such a case, return water of 11 ° C is 600m. ^Three When it is sent to the heat source at / h, the heat source exerts its maximum capacity so that 5 ° C. cold water is generated.
[0036]
However, if the temperature of the return water to the heat source is 11 ° C. or higher in this way, the capacity of the heat source is insufficient and 5 ° C. cold water cannot be generated. That is, it becomes difficult to maintain the temperature of the cold water supplied to the external load at the set temperature of 5 ° C. In such a case, the control device determines whether or not to increase or decrease the number of heat source and heat medium pumps in accordance with the difference (outward temperature difference) between the outgoing water temperature TS and the return water temperature TR. Change the threshold.
[0037]
For example, from the current return temperature difference (actual return temperature difference), design temperature difference, and heat source design flow rate, the flow rate Q required for the heat source to exert its maximum capacity at the actual return temperature difference according to the following equation (1) And the obtained flow rate Q is set as the stage increase threshold value F1u when there is one heat source and heat medium pump in operation. Further, for the obtained increase threshold F1u, for example, a value having a hysteresis of 20% is set as the decrease threshold F1d when there are two heat sources and heat medium pumps in operation.
If it does in this way, when it is set as the system which controls the discharge flow rate of a heat-medium pump so that differential pressure | voltage (DELTA) P may be fixed, it will become possible to aim at a stage when a heat source will exhibit the maximum capability.
Q = (design return temperature difference / actual return temperature difference) x heat source design flow rate (1)
[0038]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is an instrumentation diagram of a heat source apparatus showing an embodiment of the present invention. 4, the same reference numerals as those in FIG. 4 denote the same or equivalent components as those described with reference to FIG. 4, and the description thereof will be omitted.
[0039]
In this embodiment, the conveyance capacity (rated flow rate) of the heat medium pumps P1, P2, P3 is set larger than the design value (design flow rate) of the pump heat medium flow rate when the maximum capacity of the heat sources G1, G2, G3 is exhibited. Yes. For example, 336 m which is the design flow rate of the heat sources G1, G2, G3 ^Three / H, the transfer capacity of the heat medium pumps P1, P2, P3 is 600m ^Three / H.
[0040]
Further, inverters INV1, INV2, and INV3 are provided in the heat medium pumps P1, P2, and P3, and inverter outputs are supplied from the control device 13A to the inverters INV1, INV2, and INV3, and the discharge flow rates of the heat medium pumps P1, P2, and P3 are controlled. Like to do. That is, variable flow rate heat medium pumps are used as the heat medium pumps P1, P2, and P3.
[0041]
Further, flow meters 14-1, 14-2, 14-3 are provided in the circulation path from the heat sources G1, G2, G3 to the forward header 2 of the heat medium, and these flow meters 14-1, 14-2, 14- are provided. The flow rate F1, F2, F3 of the heat medium measured by 3 is given to the control device 13A.
[0042]
The control device 13A is realized by hardware including a processor and a storage device, and a program that realizes various functions in cooperation with the hardware. Similarly to the conventional control device 13, the control device 13 </ b> A includes a forward water temperature TS from the forward water temperature sensor 10, a return water temperature TR from the return water temperature sensor 11, a load flow rate F from the flow meter 12, and a differential pressure gauge. A differential pressure ΔP from 12 is given.
[0043]
Hereinafter, the outline of the processing operation performed by the control device 13A will be described by taking the case where the heat source device is a cold water heat source device as an example. Also in this cold water heat source device, similarly to the conventional cold water heat source device described in FIG. 4, the maximum capacity per unit of the heat source G is 1000 RT, the design value of the return water temperature TR is 14 ° C., and the outgoing water temperature Design flow rate per unit of heat source (refrigerator) G when TS design value is 5 ° C is 336m ^Three / H, 336m ^Three The return water of 14 ° C. sent at / h can be cooled to 5 ° C. when the maximum capacity of the heat source G is exhibited. The heat source G is designed to have the highest operating efficiency in a state where the maximum capacity is exhibited.
[0044]
When the heat source activation time is reached (step 201 shown in FIG. 2), the control device 13A activates the first heat source G1 and the heat medium pump P1. At this time, the heat medium pump P1 has a discharge flow rate smaller than the design flow rate of the heat source G1 and a predetermined value (150 m). ^Three / H) (step 202). That is, the cooling water pump GP1 and the cooling tower fan GF1 are turned on to start the operation of the heat source (refrigerator) G1, and a command is sent to the inverter INV1 so that the heat medium pump P1 is set to 150 m. ^Three Start with / h.
[0045]
Thereby, 150 m from the heat medium pump P1 to the heat source G1. ^Three / H heating medium is sent, and this heating medium is made cold water at 5 ° C. in the heat source G 1 and sent to the forward header 2. Here, since the operation of the external load 4 has not yet started (the cold water valve 4-1 is closed), the entire amount is returned to the return header 6 through the bypass line 7. At this time, the control device 13A monitors the differential pressure ΔP between the forward header 2 and the return header 6 from the differential pressure gauge 9, and controls the opening degree of the bypass valve 8 so that the differential pressure ΔP becomes constant. (Step 203).
[0046]
In this state, when the operation of the external load 4 is started (YES in Step 204), that is, when the chilled water valve 4-1 in the external load 4 is opened, the chilled water being sent from the forward header 2 to the bypass line 7 Is divided and sent to the external load 4. Thereby, since the differential pressure ΔP is about to decrease, the control device 13A controls the opening degree of the bypass valve 8 so that the differential pressure ΔP does not decrease (step 205). By controlling the bypass valve 8, that is, by keeping the differential pressure ΔP constant, cold water is supplied to the external load 4 at a flow rate proportional to the opening of the cold water valve 4-1. As the required flow rate of cold water increases, the bypass valve 8 is closed. When the bypass valve 8 is fully closed, the entire amount of cold water sent from the heat source G 1 to the forward header 2 is sent to the external load 4.
[0047]
When the external load 4 further requires cold water (when the cold water valve 4-1 is further opened), no more cold water can be supplied from the heat source G1, so it becomes difficult to maintain the differential pressure ΔP constant. The differential pressure ΔP begins to drop rapidly. In the present embodiment, the control device 13A monitors the differential pressure ΔP and determines that the time when the differential pressure ΔP starts to drop rapidly is the time when it becomes difficult to maintain the differential pressure ΔP constant (step). 206), a command is sent to the inverter INV1 to keep the differential pressure ΔP constant, and 150m until that time. ^Three Control of the discharge flow rate of the heat medium pump P1 which has been set to / h is started (step 207). Thereby, further supply of the heat medium to the external load 4 is performed in a state where the bypass flow rate is zero.
[0048]
Further, when the control of the discharge flow rate of the heat medium pump P1 is started, the control device 13A sets the difference between the current return water temperature TR and the return water temperature TS as the current return temperature difference (actual return temperature difference) ΔT. Obtained (step 208), the return temperature difference ΔT, the design temperature difference ΔTsp (ΔTsp = 14 ° C.−5 ° C. = 9 ° C.), and the design flow rate of the heat source G1 (336 m) ^Three / H), a flow rate Q1 required for the heat source G1 to exhibit its maximum capacity when the actual return temperature difference ΔT is obtained according to the following equation (2) is obtained (step 209).
Q1 = (ΔTsp / ΔT) × (design flow rate of heat source G1 (336 m ^Three / H)) ・ ・ ・ ・ (2)
[0049]
Then, the control device 13A sets the obtained flow rate Q1 as the stage increase threshold value F1u when there is one heat source and heat medium pump in operation. Further, a step-down threshold value F1d (F1d = Q1-0.2 ×) in the case where there are two heat sources and heat medium pumps operating at a value having a hysteresis of 20% with respect to the obtained step-up threshold value F1u. Q1) (step 210).
[0050]
As the flow rate of the heat medium required by the external load 4 increases, the discharge flow rate of the heat medium pump P1 increases and eventually the design flow rate of the heat source G1 (336 m). ^Three / H). In this case, since the conveyance capacity of the heat medium pump P1 is larger than the design flow rate of the heat source G1, (600 m ^Three / H), the discharge flow rate of the heat medium pump P1 can be further increased in response to the demand of the external load 4.
[0051]
Here, if the current return water temperature TR is 14 ° C., the outgoing water temperature TS is 5 ° C., and the actual return temperature difference ΔT is 9 ° C., that is, the return temperature difference is as designed. Q1 at 209 is Q1 = (9 ° C / 9 ° C) x 336m ^Three / H = 336m ^Three / H. In this case, the increase threshold F1u is 336 m ^Three / H, and the step-down threshold F1d is 269 m ^Three / H (see FIG. 3A).
[0052]
Accordingly, the flow rate of the heat medium required by the external load 4 is increased, and the load flow rate F is 336 m. ^Three / H (YES in step 211), that is, the discharge flow rate of the heat medium pump P1 is 336 m. ^Three When reaching / h, the control device 13A activates the second heat source G2 and the heat medium pump P2. In this case, the control device 13A sets the discharge flow rate to a predetermined value (150 m ^Three / H), the heat medium pump P2 is started (step 213).
[0053]
At this time, the heat source G1 is just at its maximum capacity, and the discharge flow rate of the heat medium pump P1 is 336 m. ^Three In this state, the heat source and the heat medium pump are increased. Therefore, after the heat source G1 exhibits its maximum capacity, it is 336 m from the heat medium pump P1. ^Three No return water of / h or more is supplied to the heat source G1, and the heat source G1 does not have insufficient capacity due to an excessive amount of return water supplied at TR = 14 ° C.
[0054]
On the other hand, if the current return water temperature TR is 12 ° C., the outgoing water temperature TS is 5 ° C., and the actual return temperature difference ΔT is 7 ° C., Q1 in step 209 is Q1 = (9 ° C./7 ° C) x 336m ^Three / H = 432m ^Three / H. In this case, the increase threshold F1u is 432 m. ^Three / H, the reduction threshold F1d is 346 m ^Three / H (see FIG. 3B).
[0055]
Accordingly, the flow rate of the heat medium required by the external load 4 is increased, and the load flow rate F is 432 m. ^Three / H (YES in step 211), that is, the discharge flow rate of the heat medium pump P1 is 432 m ^Three When reaching / h, the control device 13A activates the second heat source G2 and the heat medium pump P2 (step 213).
[0056]
At this time, the heat source G1 is at the point where the maximum capacity is exhibited, and the discharge flow rate of the heat medium pump P1 is 432 m. ^Three In this state, the number of heat sources can be increased. Therefore, after the heat source G1 exhibits its maximum capacity, it is 432 m from the heat medium pump P1. ^Three The return water of / h or more is not supplied to the heat source G1, and the heat source G1 does not have insufficient capacity upon receiving an excessive amount of return water at TR = 12 ° C.
[0057]
Further, assuming that the current return water temperature TR is 11 ° C., the outgoing water temperature TS is 5 ° C., and the actual return temperature difference ΔT is 6 ° C., Q1 in Step 209 is Q1 = (9 ° C./6° C.). × 336m ^Three / H = 504m ^Three / H. In this case, the step-up threshold F1u is 504 m. ^Three / H, the step-down threshold F1d is 403 m ^Three / H (see FIG. 3C).
[0058]
Therefore, the flow rate of the heat medium required by the external load 4 is increased, and the load flow rate F is 504 m. ^Three / H (YES in step 211), that is, when the discharge flow rate of the heat medium pump P1 reaches 504, the control device 13A activates the second heat source G2 and the heat medium pump P2 (step 213). ).
[0059]
At this time, the heat source G1 is just at its maximum capacity, and the discharge flow rate of the heat medium pump P1 is 504 m. ^Three In this state, the number of heat sources can be increased. Therefore, after the heat source G1 exhibits its maximum capacity, it is 504 m from the heat medium pump P1. ^Three The return water of / h or more is not supplied to the heat source G1, and the heat source G1 does not have insufficient capacity due to an excessive amount of return water supplied at TR = 11 ° C.
[0060]
Even if the load flow rate F does not reach the step-up threshold F1u, if the going water temperature TS becomes 6 ° C. or higher (YES in step 212), the control device 13A sets the going water temperature TS to the set temperature (5 ° C.). It is determined that it has become difficult to maintain, and the second heat source G2 and the heat medium pump P2 are activated (step 213). That is, if the heat source G1 becomes insufficient in capacity for some reason before the load flow rate F reaches the step-up threshold F1u, the insufficient capacity of the heat source G1 is immediately resolved, and the cold water supplied to the external load 4 is designed. The value will be maintained at 5 ° C.
[0061]
Similarly, the control device 13A controls the opening degree of the bypass valve 8 so that the differential pressure ΔP is constant, and then determines that the differential pressure ΔP is difficult to be constant. When the discharge flow rate of the heat medium pump P2 is controlled to be constant, and the load flow rate F reaches the second step-up threshold F2u obtained as Q2 by the following equation (3), the third heat source G3 and the heat medium pump Start P3.
Q2 = (ΔTsp / ΔT) × (design flow rate of heat source G1 + G2 (672 m / hour) ^Three )) ・ ・ ・ ・ (3)
[0062]
When the flow rate of cold water required by the external load 4 decreases and the load flow rate F falls below the second step-down threshold F2d (F2d = Q2-0.2 × Q2), the operation of the heat source G3 and the heat medium pump P3 is stopped. To do. Further, when the flow rate of cold water required by the external load 4 decreases and the load flow rate F falls below the first step-down threshold F1d (F1d = Q1−0.2 × Q1), the operation of the heat source G2 and the heat medium pump P2 is performed. Stop.
[0063]
Furthermore, when the flow rate of cold water required by the external load 4 is reduced and it becomes difficult to maintain the differential pressure ΔP constant by controlling the discharge flow rate of the heat medium pump P1, the control device 13A causes the bypass valve 8 to The flow rate of the heat medium flowing through the bypass pipe 7 is controlled so that the differential pressure ΔP is constant.
[0064]
In the above description, the case where the actual return temperature difference ΔT is equal to or less than ΔTsp has been described. However, when ΔT> ΔTsp, that is, when the return water temperature TR exceeds 14 ° C., the above (2 ) And Q3 obtained by the equations (3) and (3) are decreased, and the increase threshold F1u and F2u are decreased. Also in this case, when the heat source G1 or the heat source G2 exhibits the maximum capacity, the number of stages is increased and the capacity is not insufficient.
[0065]
Further, the control device 13A monitors the flow rate of the cold water passing through the heat sources G1, G2, and G3 by the flow rates F1, F2, and F3 from the flow meters 14-1, 14-2, and 14-3. The preset minimum heat medium amount Fmin (for example, Fmin = 120 m ^Three / H), the discharge flow rate of the heat medium pumps P1, P2, P3 is increased.
[0066]
In the present embodiment, the heat medium pumps P1, P2, and P3 are initially 150 m. ^Three This is a command value to the heat medium pumps P1, P2, P3, and the discharge flow rate of the heat medium pumps P1, P2, P3 is actually 150 m. ^Three Whether it is / h or not is not certain. The refrigerator may freeze if the heat medium passing therethrough becomes too small. Therefore, in the present embodiment, the flow rate of the cold water passing through the heat sources G1, G2, G3 is monitored so that the heat sources G1, G2, G3 may not freeze below the minimum heat medium amount Fmin that may freeze. The discharge flow rate of the heat medium pumps P1, P2, P3 is controlled.
[0067]
As can be seen from the above description, in the present embodiment, the heat medium pump P (P1, P2, P3) having a transfer capacity (rated flow rate) larger than the design flow rate of the heat source G (G1, G2, G3) is used. Therefore, in response to the demand of the external load 4, the discharge flow rate of the heat medium pump P (P1, P2, P3) is made larger than the design flow rate of the heat source G (G1, G2, G3), and the return water temperature difference Even when the value is lower than the design value, it is possible to cause the heat source G to exhibit the maximum capacity or the capacity close to it (high capacity) which is the state with the highest operating efficiency. As a result, the heat source G1 does not have to be increased to the heat source G2 while leaving a surplus, and the operating efficiency of the heat source is deteriorated and the number of operating auxiliary machines (cooling water pump, cooling tower fan, etc.) is reduced. Excessive energy consumption due to increase is prevented.
[0068]
Further, in the present embodiment, the heat medium pump P (P1, P2, P3) is not always driven at the rated flow rate, but a flow rate that can cover the flow rate of cold water required by the external load 4 at each time point. The heat medium pump P (P1, P2, P3) consumes much less energy than the case where the heat medium pump P (P1, P2, P3) is always driven at the rated flow rate. Thus, the cold water heat source device can be operated more efficiently.
[0069]
Further, in the present embodiment, when the capacity of the heat source G1 (G2) is insufficient and the outgoing water temperature TS decreases, the heat source G2 (G3) is immediately increased to eliminate the insufficient capacity. The cold water heat source device can be operated more efficiently.
[0070]
In the above-described embodiment, the example in which three heat sources are provided has been described, but it goes without saying that the number of heat sources is not limited to three.
In the above-described embodiment, the cold water heat source device has been described as an example. However, the hot water heat source device can be similarly controlled.
[0071]
In the above-described embodiment, the step-up threshold and the step-down threshold are changed according to the actual return temperature difference, but the step-up threshold and the step-down threshold may be fixed values. That is, steps 208, 209, and 210 are omitted in the flowchart shown in FIG. ^Three / H, the reduction threshold F1d is, for example, 480 m ^Three You may make it fix to / h. In this case, for example, when the return water temperature TR is 14 ° C., the load flow rate F is 336 m. ^Three When the heat source G1 reaches the maximum capacity at the time of reaching / h and the return water with a flow rate higher than that is supplied to the heat source G1, the capacity becomes insufficient, but in step 212, the outgoing water temperature TS becomes 6 ° C. or higher. In such a case, by increasing the number of steps, the shortage of ability can be resolved immediately.
[0072]
In the embodiment described above, the discharge flow rate of the heat medium pump P is initially set to 150 m. ^Three / H, and when it becomes difficult to keep the differential pressure ΔP constant by controlling the bypass flow rate, the discharge flow rate of the heat medium pump P is controlled so as to keep the differential pressure ΔP constant. , 600m heat medium pump from the beginning ^Three It may be activated at a discharge flow rate of / h. That is, it is possible to control only the bypass flow rate so as to keep the differential pressure ΔP constant, and not to control the discharge flow rate of the heat medium pump P. However, the control device 13A has a function of increasing the number of operating heat sources and pumps regardless of the load flow rate F when it becomes difficult to maintain the outgoing water temperature TS at the set temperature (5 ° C.). Even in such a control method, if the capacity of the heat source is insufficient and the water temperature TS falls, the capacity shortage can be solved immediately and the lack of capacity can be solved, so the cold water heat source device can be operated efficiently. The purpose of doing can be achieved.
[0073]
【The invention's effect】
As is clear from the above description, according to the first invention, The flow rate of the heat medium supplied to the external load is used while using a variable flow rate heat medium pump having a transfer capacity (rated flow rate) larger than the design value (design flow rate) of the pump heat medium flow rate when the maximum capacity of the heat source is exhibited. To increase the number of operating heat sources and heat medium pumps compared to the increase threshold value determined as a value larger than the design value of the pump heat medium flow rate when the maximum capacity of the heat source is exhibited and less than the transfer capacity of the heat medium pump West, Heat source starting means for starting the heat source with the discharge flow rate of the heat medium pump as a predetermined value, and the discharge flow rate for controlling the discharge flow rate of the heat medium pump so as to make the differential pressure of the heat medium between the forward header and the return header constant A bypass that controls the flow rate of the heat medium that flows through the bypass pipe when it becomes difficult to make the differential pressure constant by the discharge flow rate control means as the flow rate of the heat medium required by the control means and the external load decreases. The flow rate control means is provided, so even if the return temperature difference is lower than the design value, it is possible to increase the stage while the heat source exhibits high capacity, and the operating efficiency of the heat source can be improved. The heat medium pump can be driven only at a flow rate that can meet the flow rate of the heat medium required by the external load at each time point, that is, the heat medium pump is always driven at its rated flow rate. thing As not to reduce the consumption of energy, it is possible to operate more efficiently heat source device.
[0074]
According to the second invention, in the first invention, the flow rate of the heat medium passing through the heat source is monitored, and the discharge of the heat medium pump is performed so that the flow rate of the heat medium does not fall below a preset minimum heat medium amount. A fail-safe means to control the flow rate is provided, so that the flow rate of the heat medium that passes through the heat source is always kept above the minimum heat medium amount so that the heat source does not stop automatically, and the heat medium is supplied stably. Is possible.
[0075]
According to the third invention, the step-up threshold and step-down when the number of operating heat sources and heat-medium pumps is increased or decreased according to the temperature difference between the heat medium sent from the forward header and the heat medium returned to the return water header. Since a threshold value changing means for changing the threshold value is provided, it is possible to increase the number of stages when the heat source just exhibits its maximum capacity, and the number of operating heat sources and heat medium pumps can be suppressed. It becomes possible to drive well, and the operation cost is reduced.
[Brief description of the drawings]
FIG. 1 is an instrumentation diagram of a heat source device showing an embodiment of the present invention.
FIG. 2 is a flowchart for explaining an outline of a processing operation performed by a control device provided in the heat source device.
FIG. 3 is a diagram illustrating a step-down threshold value and a step-up threshold value set in accordance with a current return temperature difference (actual return temperature difference).
FIG. 4 is an instrumentation diagram showing an example of a conventional heat source device.
FIG. 5 is a flowchart for explaining an outline of a processing operation performed by a control device provided in a conventional heat source device.
[Explanation of symbols]
G (G1 to G3) ... Heat source, P (P1 to P3) ... Heat medium pump, GP (GP1 to GP3) ... Cooling water pump, GF (GF1 to GF3) ... Cooling tower fan, 2 ... Out header, 3 ... Out Water pipe, 4 ... external load, 5 ... return water pipe, 6 ... return header, 7 ... bypass pipe, 8 ... bypass valve, 9 ... differential pressure gauge, 10 ... outgoing water temperature sensor, 11 ... return water temperature sensor, 12 ... Flow meter, 13A ... Control device, 14-1 to 14-3 ... Flow meter.

Claims (3)

A heat source that generates a heat medium, a variable flow rate heat medium pump having a transfer capacity larger than a design value of a pump heat medium flow rate when the maximum capacity of the heat source that conveys the heat medium generated by the heat source is exhibited, and A forward header that receives the heat medium from the heat source, an external load that receives supply of the heat medium sent from the forward header, a return header that returns the heat medium heat-exchanged in the external load to the heat source, and the forward header And a bypass pipe line that communicates with the return header, and compares the flow rate of the heat medium supplied to the external load with a step-up threshold and the number of operating heat sources and heat medium pumps. A control device for increasing the number of steps ,
Heat source starting means for starting the heat source with a discharge flow rate of the heat medium pump as a predetermined value;
Discharge flow rate control means for controlling the discharge flow rate of the heat medium pump so as to make the differential pressure of the heat medium between the forward header and the return header constant, and to reduce the flow rate of the heat medium required by the external load Accordingly, when it becomes difficult to make the differential pressure constant by the discharge flow rate control means, the flow rate control means includes a bypass flow rate control means for controlling the flow rate of the heat medium flowing through the bypass pipe line,
The controller is characterized in that the step-up threshold value is determined as a value that is larger than a design value of a pump heat medium flow rate when the maximum capacity of the heat source is exhibited and is equal to or less than a conveyance capacity of the heat medium pump . The control device according to claim 1,
The flow rate of the heat medium passing through the heat source is monitored, and a fail-safe means for controlling the discharge flow rate of the heat medium pump is provided so that the flow rate of the heat medium does not fall below a preset minimum heat medium amount. A control device characterized by that. Design value of the pump heat medium flow rate when the first to Nth (N ≧ 2) heat sources that generate the heat medium and the maximum capacity of the heat source that conveys the heat medium generated by the first to Nth heat sources are exhibited. First to Nth variable flow rate heat medium pumps having a larger transport capacity, a forward header for mixing the heat mediums from the first to Nth heat sources, and a heat medium fed from the forward header An external load that receives the supply, a return header that returns the heat medium exchanged in the external load to the first to Nth heat sources, and a bypass pipe that communicates the forward header and the return header. Control for increasing or decreasing the number of operating heat sources and heat medium pumps by comparing the flow rate of the heat medium supplied to the external load with predetermined increase and decrease thresholds A device,
Change the stage increase threshold and stage decrease threshold when increasing or decreasing the number of operating heat sources and heat medium pumps according to the temperature difference between the heat medium sent from the forward header and the heat medium returned to the return header A control device comprising a threshold value changing means.

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