KR101943170B1 - Heat source control device, heat source system, and heat source control method - Google Patents

Abstract

In this heat source control device, the heat source system and the heat source control method, there are provided heat source groups 10 and 20, a plurality of group control units 11 and 21 and an algebraic control unit 30, , The first operation range output section and the second operation range output section. The logarithmic control section (30) increases the start number of the heat source groups (10, 20) when the demand load exceeds the first proper operation range And controls the group controllers 11 and 21 so that the starting number of the heat source units 12 and 22 becomes a predetermined number.

Description

TECHNICAL FIELD [0001] The present invention relates to a heat source control device, a heat source system, and a heat source control method,

The present invention relates to a heat source control device, a heat source system, and a heat source control method.

The present application claims priority based on Japanese Patent Application No. 2013-228348 filed on November 1, 2013, the contents of which are incorporated herein by reference.

In a large-scale building or the like, a cold / hot water system in which a plurality of cold / hot heat sources are installed in parallel and a secondary heat source such as an air conditioner is connected to these cold / heat sources is used. Each cold / hot heat source unit is provided with a cold / hot water pump for circulating cold / hot water generated by each cold / heat source.

In such a cold / hot water system, the flow rate of the cold / hot water required to cope with the thermal load changes depending on the secondary load. Therefore, in such a cold / hot water system, the flow rate of the cold / hot water supplied to the secondary side heat load source must be controlled.

As such cold / hot water control method, there is known a method of controlling the bypass flow rate of the secondary side heat source and performing the logarithmic control of the cold / heat source. In this logarithmic control method, the number of drives is selected by a method that considers both the flow rate, the heat quantity, and the flow rate and the heat quantity.

In this case, the cold / hot water pump in the cold / hot heat source used circulates the cold / hot water by changing the flow rate according to the load.

Various technologies related to this background are known (see, for example, Patent Document 1).

For example, Patent Document 1 discloses a cold / hot water generator output distribution of a cold / hot water system composed of a cold / hot water source unit in which a plurality of units are arranged in parallel, a cold / hot water pump provided in each cold / heat source unit, and a secondary side heat source unit connected to a plurality of cold / A control method is described. More specifically, in this cold / hot heat source output distribution control method, the number of cold / hot heat sources to be used is selected according to the heat load of the secondary heat source. The cold / hot heat source output distribution control method is a system in which a plurality of cold / hot heat sources are used and the cold / hot heat source to be used is divided into two groups, one to one or a plurality of groups, The ratio of the cold / hot water flow rates of both groups of cold / hot heat sources to the cold / hot water flow rates supplied to the secondary side heat and cold source is changed so that the COP becomes the maximum. Further, the system COP is computed and compared with the system COP before change. In addition, when the system COP is increased, the system COP is further changed in the same direction. When the system COP is decreased , And changes it in the reverse direction. In this manner, with this cold / hot heat source output distribution control method, it is possible to reduce the power consumption by operating the cold / warm heat source according to the maximum efficiency as a whole system.

Japanese Patent No. 4435651

According to the invention described in Patent Document 1, when the number of cold / hot heat sources increases, the control period is extended, and there is a possibility that the state of the load to be handled may change. Therefore, according to the invention described in Patent Document 1, there is a possibility that the search result does not always become optimal.

According to the invention described in Patent Document 1, when the same function as that of the logarithmic control function mounted on the higher-level control device is implemented in the control of the group, a load range applicable to one group is one It is wider than the load range that can be supported by the unit. Therefore, according to the invention disclosed in Patent Document 1, for example, when another group is newly activated with respect to a state in which ten units are operating in a driving group, the number of unit steering wheels in the driving group is ten And the number of unit steering wheels of the newly activated group is controlled to be changed from zero to five in a sudden change. This makes it impossible to perform control that does not abruptly change the number of units connected to the group.

According to a first aspect of the present invention, there is provided a heat source control device comprising: a plurality of group controllers for performing startup and stop of a heat source unit corresponding to a heat source group of a plurality of heat source units; And an algebraic control unit for performing the operation. The first control unit outputs the load range in which one of the characteristic values corresponding to the number of the heat source units during operation to the predetermined range is set as the first proper operation range to the logarithmic control unit based on the characteristic value of each heat source unit And a second operation range outputting section for outputting the range of the other of the characteristic values to the logarithmic control section in a second suitable operation range. The logarithmic control unit increases the number of maneuvers of the heat source group when the demand load exceeds the first proper operation range.

According to the second aspect of the present invention, in the heat source control device according to the first aspect, the first operation range output section sets the COP information indicating the relationship between the performance coefficient and the load factor as the characteristic value, The load range in which one of the corresponding characteristic values becomes equal to or greater than the predetermined value may be output to the logarithmic control section as the first proper operation range. The second operation range output section may output the load range in which the other one of the characteristic values is equal to or greater than the predetermined value as the second proper operation range to the logarithmic control section.

According to the third aspect of the present invention, in the heat source control device according to the first aspect, the first operation range output section sets the inverter input information as the characteristic value, and one of the characteristic values corresponding to the number of the heat source units during operation The load range that falls below the predetermined value may be output to the logarithmic control unit as the first proper operation range. The second operation range output section may output the load range in which the other one of the characteristic values becomes a predetermined value or less as the second proper operation range to the logarithmic control section.

According to a fourth aspect of the present invention, in the heat source control device according to any one of the first to third aspects, the group control unit is configured to select, from among the connected heat source units, The operation loadable range corresponding to the logarithm +1 can be used as the transmission data from the group control unit.

According to a fifth aspect of the present invention, there is provided a heat source control apparatus according to any one of the first to fourth aspects, wherein the load distribution to the heat source group from the logarithmic control unit is larger than the operable load range with respect to the number of heat source units during operation It is possible to increase the number of heat source unit operations in the heat source group and update the optimum load range and the operable load range, respectively.

According to a sixth aspect of the present invention, there is provided a heat source control apparatus according to any one of the first to fifth aspects, wherein the load distribution to the heat source group from the logarithmic control unit is larger than the operable load range with respect to the number of heat source units during operation It is possible to reduce the number of heat source unit operations in the heat source group and update the optimum load range and the operable load range, respectively.

According to a seventh aspect of the present invention, a heat source system includes a heat source control device according to any one of the first to sixth aspects, and a heat source group of a plurality of heat source units.

According to an eighth aspect of the present invention, there is provided a method of controlling a heat source, the method comprising: a plurality of group control steps for starting and stopping a heat source unit corresponding to a heat source group of a plurality of heat source units; And a group control step of controlling the plurality of heat source units based on the characteristic values of the respective heat source units so that a load range in which one of the characteristic values corresponding to the number of the heat source units during operation is within a predetermined range is referred to as a first proper operation A second operation range output step of outputting a load range in which the other one of the characteristic values is in a predetermined range to the logarithmic control step in a second proper operation range; And the logarithmic control step increases the number of maneuvers of the heat source group when the demand load exceeds the first proper operation range.

In addition, the outlines of the first to eighth aspects of the invention do not list all necessary features of the present invention. In addition, subcombinations of these feature groups may also be in the form of the invention.

According to the heat source control device, the heat source system and the heat source control method described above, it is possible to control the number of the heat source units included in the plurality of heat source groups so as not to be accompanied by abrupt change.

1 is a diagram showing an example of the system configuration of the heat source system 100 according to the first embodiment.
Fig. 2 is a block diagram of each of the group controllers 11 and 21. Fig.
3 is a diagram showing COP characteristics applied to the heat source system 100. FIG.
FIG. 4 is a graph showing the power consumption characteristics applied to the heat source system 100. FIG.
5 is a flow chart illustrating the basic control operation of the heat source system 100. As shown in FIG.
6 is a flowchart illustrating a specific control operation of the heat source system 100. As shown in FIG.
FIG. 7 is a flowchart for explaining a concrete control operation of the heat source system 100. FIG.
8 is a flowchart for explaining the basic control operation of the heat source system 100 of the second embodiment.
9 is a flowchart for explaining the basic control operation of the heat source system 100 of the third embodiment.

The present invention will now be described with reference to the embodiments of the invention. However, the following embodiments are not intended to limit the scope of the invention claimed in the claims, Can not be said.

Fig. 1 shows an example of the system configuration of the heat source system 100 according to the first embodiment. Here, the heat source system 100 is a system for controlling a plurality of heat sources.

The heat source system 100 includes a first heat source group 10, a first group control device 11, a second heat source group 20, a second group control device 21 and a logarithmic control device 30 .

The first heat source group (10) includes a plurality of heat source units (12). Here, the heat source unit 12 is a unit including a heat source device and a unit bulk substrate 13. [ The input side of each heat source unit 12 is connected to the water inlet port 41 and the output side is connected to the water outlet port 42 in communication. The output side of each heat source unit 12 is connected to the first group control device 11 and the logarithmic control device 30.

The first group control device 11 receives necessary data from the unit batch board 13 and transmits control data to the unit batch board 13 in controlling the heat source unit 12. [ Then, the first-group control device 11 performs start-up stopping and load allocation of the respective heat source units 12.

The second heat source group 20 is connected in parallel to the first heat source group 10 and includes a plurality of heat source units 22. [ Here, the heat source unit 22 is a unit including a heat source device and a unit bulk substrate 23. The input side of each heat source unit 22 is connected to the water inlet 41 and the output side is connected to the water outlet 42 in communication. The output side of each heat source unit 22 is connected to the second group control device 21 and the logarithmic control device 30. The second group control device 21 receives necessary data from the unit batch board 23 and controls the unit batch board 23 to control the heat source unit 22. [ Here, the data received from the unit common substrate 23 also includes COP information indicating the relationship between the load coefficient and the coefficient of performance of each heat source unit 12, 22.

Then, the first-group control device 11 performs start-up stopping and load assignment of the respective heat source units 22.

The logarithmic control device 30 performs startup stop and load allocation of the first heat source group 10 and the second heat source group 20. From the view of the logarithmic control device 30, the first heat source group 10 and the second heat source group 20 are handled in the same way as the large capacity refrigerator.

Fig. 2 shows a block diagram of each of the group controllers 11 and 21. As shown in Fig. As shown in Fig. 2, each of the group controllers 11 and 21 is configured to control the operation of the heat source units 12 (or 12) in operation based on the COP information as a characteristic value indicating the relationship between the load factor and the coefficient of performance of each heat source unit 12 (22, 22) to a logarithmic control device (30) with a load range in which the coefficient of performance corresponding to the logarithm of the number of logarithms of the load is greater than or equal to a predetermined value.

Each of the group control devices 11 and 21 sets the load range in which the coefficient of performance corresponding to a predetermined number larger than the number of the heat source units 12 and 22 during operation is equal to or greater than a predetermined value, And outputting it to the logarithmic control unit 30 in the range of the second operation range output unit 15, 25.

The logarithmic control device 30 increases the number of starts of the heat source groups 10 and 20 when the demand load exceeds the first proper operation range.

The heat source system 100 is a system in which the heat source units 12 and 22 connected to the respective group controllers 11 and 21 are provided with an optimum load range corresponding to the number of operation during operation, The range is set as data to be transmitted from each of the group control devices 11 and 21 to the logarithmic control device 30. [

More specifically, for example, in a case where ten heat source units 12 are connected to the first group control device 11 and one operation state is selected, the optimum load range for one unit and the operation for two units The load range is set as the optimum load range and the operable load range of the whole group.

In the heat source system 100, when all the units of the heat source units 12 and 22 connected to the respective group control devices 11 and 21 are stationary, the optimum load range for one unit and the operable load The range is set as data to be transmitted from each of the group control devices 11 and 21 to the logarithmic control device 30. [

The logarithmic control device 30 calculates the optimum load range and the operable load range of each of the heat source groups 10 and 20 in the following equations (1) to (12).

In the equations (1) to (6), the optimum load range Hi side of each heat source group 10, 20 is Loh_gi, the Lo side is Lol_gi, the operable load range Hi side is Lh_gi, the Lo side is Ll_gi, The optimum load range Hi side of each of the heat source units 12 and 22 is Loh_gkui, Lo side is Lol_gkui, and the operation loadable range Hi (Hi) is Loh_gi, (K = 1 to 6, i = 1 to 20), and the number of drives is m.

In the equations (7) to (12), the optimal load range Hi side of each heat source group 10, 20 is Loh_gi, the Lo side is Lol_gi, the operable load range Hi side is Lh_gi, 1 to 20), the optimum load range Hi side of each of the heat source units 12 and 22 is Loh_gkui, Lo side is Lol_gkui, Lh_gkui is the side of Hi range of the operable load range, and Ll_gkui is Lo side = 1 to 20), and the number of drives is zero.

3 is a diagram showing COP characteristics applied to the heat source system 100. FIG. The information on the COP characteristics indicates the relationship between the load coefficient and the coefficient of performance of each of the heat source units 12 and 22 and is included in the data received from the unit common substrate 23. [ In Fig. 3, the horizontal axis represents the freezing capacity, and the vertical axis represents the COP value. As shown in FIG. 3, the COP characteristic has a parabolic shape in accordance with an increase in freezing capacity when the outdoor air temperature is, for example, 15 ° C, 25 ° C, and 32 ° C. At this time, the proper operation range is a load range that is equal to or larger than a predetermined value.

FIG. 4 is a graph showing the power consumption characteristics applied to the heat source system 100. FIG. In Fig. 4, the horizontal axis represents the freezing capacity and the inverter input represents the vertical axis. As shown in Fig. 4, the power consumption characteristic has a characteristic that it increases in direct proportion to the increase of the freezing capacity when the outside air temperature is, for example, 15 deg. C, 25 deg. C, and 32 deg. At this time, the proper operation range is a load range in which the value falls below a predetermined value.

Fig. 5 shows a flowchart for explaining the basic control operation of the heat source system 100. Fig. As shown in Fig. 5, by starting the control, first, the logarithmic control device 30 discriminates whether or not there is a heat source unit in operation among the heat source groups 10 and 20 (S101).

The logarithmic control device 30 calculates the optimum load range and the operable load range of each of the heat source groups 10 and 20 in the above-described equations (1) to (6) (S102).

The logarithmic control device 30 calculates the optimal load range and the operable load range of each of the heat source groups 10 and 20 in the absence of the unit under operation among the heat source groups 10 and 20 by using the equations (7) to (Step S103).

Figs. 6 and 7 show flowcharts for explaining the specific control operation of the heat source system 100. Fig. 6 shows a case in which the first heat source group 10 is operated first. As shown in Fig. 6, by starting the control, first, the logarithmic control device 30 starts operation and issues a group operation command (S111). Since the group operation command is transmitted to the first group control device 11, the first group control device 11 starts operation (S112).

The first group control device 11 transmits the optimum load range and the operable load range calculated by the equations (1) to (6) to the logarithmic control device 30 (S113). The optimum load range and the operable load range are periodically transmitted to the logarithmic control device 30. [

At this time, the second group control device 21 transmits the optimum load range and the operable load range calculated by the equations (7) to (12) to the logarithmic control device 30 (S114). The optimum load range and the operable load range are periodically transmitted to the logarithmic control device 30. [

The logarithmic control device 30 determines whether the demand load is larger than the optimum load range during operation (S115). When the logarithmic control device 30 determines that the required load is larger than the optimum load range during operation, the second group control device 21 starts the operation (S116).

Thereafter, the first group control device 11 periodically transmits the optimum load range and the operable load range calculated by the equations (1) to (6) to the logarithmic control device 30 (S117).

The second group control device 21 periodically transmits the optimum load range and the operable load range calculated by the equations (1) to (6) (S118).

Next, the logarithmic control device 30 transmits the load assignment to the first group control device 11 and the second group control device 21. [ The first-group control device 11 determines whether or not the allocated load is larger than the load range that can be supported by the logarithm number during operation (S119). When it is determined that the allocation load by the logarithmic control device 30 is larger than the load range that can be supported by the logarithm number during operation, the first group control device 11 increases the number of units in the heat source group (S120). The first group control device 11 does not change the unit operation number when it is determined that the assigned load by the logarithmic control device 30 is not larger than the load range that can be supported by the logarithm number during operation.

The second group control device 21 determines whether or not the allocation load is larger than the load range that can be supported by the logarithm number during operation (S121). The second-group control device 21 increases the number of units in the heat source group (S122) when it is determined that the allocation load by the logarithmic control device 30 is larger than the load range that can be supported by the logarithm number during operation. The second group control device 21 does not change the unit operation number when the assignment load by the logarithmic control device 30 is not larger than the load range that can be supported by the logarithm number during operation.

Subsequently, the first-group control device 11 determines whether or not the allocated load is smaller than the load range that can be supported by the logarithm number during operation (S123). The first-group control device 11 decreases the number of unit operations in the heat source group (S124) when it is determined that the allocation load by the logarithmic control device 30 is smaller than the load range that can be supported by the logarithm number during operation. The first group control device 11 does not change the unit operation number when the assignment load by the logarithmic control device 30 is not smaller than the load range that can be supported by the logarithm number during operation.

The second group control device 21 determines whether or not the allocation load is smaller than the load range that can be supported by the logarithm number during operation (S125). The second-group control device 21 decreases the number of unit operations in the heat source group (S126) when it is determined that the assigned load by the logarithmic control device 30 is smaller than the allowable load range in operation. The second group control device 21 does not change the unit operation number when it is determined that the assignment load by the logarithmic control device 30 is not smaller than the load range that can be supported by the logarithm number during operation.

The logarithmic control device 30 determines whether the required load is smaller than the optimum load range during operation (S127). When it is determined that the demand load is smaller than the optimum load range during operation, the logarithmic control device 30 issues a stop command to the first group control device 11, so that the first group control device 11, The operation is terminated (S128). At this time, when only one of the first heat source groups 10 is in operation, the stop command is not issued.

When it is determined that the required load is not smaller than the optimum load range during operation, the logarithmic control device 30 determines whether only the second heat source group 20 is in operation (S129). When it is determined that only the second heat source group 20 is in operation, the logarithmic control device 30 proceeds to step S145 shown in Fig. When it is determined that only the second heat source group 20 is not in operation, the logarithmic control device 30 determines whether only the first heat source group 10 is in operation (S130). When it is determined that only the first heat source group 10 is in operation, the logarithmic control device 30 proceeds to S115, and the logarithmic control device 30 determines that only the first heat source group 10 is in operation , The routine is shifted to (S117), and the routine is repeated.

7 shows a case in which the second heat source group 20 is operated first. As shown in Fig. 7, by starting the control, first, the logarithmic control device 30 starts operation and issues a group operation command (S141). Since the group operation command is transmitted to the second group control device 21, the second group control device 21 starts operation (S142).

The second group control device 21 transmits the optimum load range and the operable load range calculated by the equations (1) to (6) to the logarithmic control device 30 (S143). The optimum load range and the operable load range are periodically transmitted to the logarithmic control device 30. [

At this time, the first group control device 11 transmits the optimum load range and the operable load range calculated by the equations (7) to (12) to the logarithmic control device 30 (S144). The optimum load range and the operable load range are periodically transmitted to the logarithmic control device 30. [

The logarithmic control device 30 determines whether the demand load is larger than the optimum load range during operation (S145). When the logarithmic control device 30 determines that the required load is larger than the optimum load range during operation, the first group control device 11 starts the operation (S146).

Thereafter, the first group control device 11 periodically transmits the optimum load range and the operable load range calculated by the equations (1) to (6) to the logarithmic control device 30 (S147).

The second group control device 21 periodically transmits the optimum load range and the operable load range calculated by the equations (1) to (6) (S148).

Next, the logarithmic control device 30 transmits the load assignment to the first group control device 11 and the second group control device 21. [ The first group control device 11 determines whether or not the allocation load is larger than the load range that can be supported by the logarithm number during operation (S149). When it is determined that the load to be assigned by the logarithmic control device 30 is larger than the allowable load range during operation, the first-group control device 11 increases the number of units in the heat source group (S150). The first group control device 11 does not change the unit operation number when it is determined that the assigned load by the logarithmic control device 30 is not larger than the load range that can be supported by the logarithm number during operation.

The second group control device 21 determines whether or not the allocation load is larger than the load range that can be supported by the logarithm number during operation (S151). The second-group control device 21 increases the number of unit drives in the heat source group (S152) when it is determined that the allocation load by the logarithmic control device 30 is larger than the load range that can be supported by the logarithm number during operation. The second group control device 21 does not change the number of unit operations when it is determined that the assigned load by the logarithmic control device 30 is not larger than the load range that can be supported by the logarithm number during operation.

Subsequently, the first-group control device 11 determines whether or not the allocated load is smaller than the loadable range that can be supported by the logarithm number during operation (S153). When it is determined that the assigned load by the logarithmic control device 30 is smaller than the loadable range that can be supported by the logarithm number during operation, the first-group control device 11 reduces the number of units in the heat source group (S154). The first group control device 11 does not change the number of unit operations when it is determined that the assigned load by the logarithmic control device 30 is not smaller than the load range that can be supported by the logarithm number during operation.

The second group control device 21 determines whether or not the allocation load is smaller than the load range that can be supported by the logarithm number during operation (S155). The second-group control device 21 decreases the number of unit operations in the heat source group (S156) when it is determined that the allocation load by the logarithmic control device 30 is smaller than the load range that can be supported by the logarithm number during operation. The second group control device 21 does not change the unit operation number when it is determined that the assignment load by the logarithmic control device 30 is not smaller than the load range that can be supported by the logarithm number during operation.

The logarithmic control device 30 determines whether the demand load is smaller than the optimum load range during operation (S157). When it is determined that the demand load is smaller than the optimal load range during operation, the logarithmic control device 30 issues a stop command to the second group control device 21, so that the second group control device 21, The operation is terminated (S158). At this time, when it is determined that only one of the second heat source groups 20 is in operation, the logarithmic control device 30 does not issue a stop command.

When it is determined that the required load is not smaller than the optimum load range during operation, the logarithmic control unit 30 determines whether only the first heat source group 10 is in operation (S159). When it is determined that only the first heat source group 10 is in operation, the logarithmic control device 30 proceeds to step S115 shown in Fig. When it is determined that only the first heat source group 10 is not in operation, the logarithmic control device 30 determines whether only the second heat source group 20 is in operation (S160). When it is determined that only the second heat source group 20 is in operation, the logarithmic control device 30 proceeds to step S145, and the logarithmic control device 30 determines that only the second heat source group 20 is in operation , The routine proceeds to step S147, and the routine is repeated.

As described above, in the heat source system 100 of the present embodiment, when it is desired to deviate from the optimum load range, the operation of increasing the heat source group is performed first. It is therefore possible to first increase the number of heat source groups to be operated in a state in which only one of the heat source units 12 and 22 connected to the heat source system 100 and each of the heat source groups 10 and 20 is in operation The number of operation of each of the heat source units 12 and 22 connected to the heat source groups 10 and 20 is rapidly changed even when the load distribution is uniformly distributed to the heat source groups 10 and 20 .

The heat source system 100 according to the present embodiment can be applied to a plurality of heat source groups 10 and 20 without significantly changing the number of heat source units 12 and 22 connected to the heat source groups 10 and 20 And the optimum operation state in which the power consumption is small as the operation state of each of the heat source units 12 and 22 can be maintained.

Next, the second embodiment will be described with reference to Fig. 8, but the same parts as those of the first embodiment are denoted by the same reference numerals, and a description thereof will be omitted, and only different points will be described. Fig. 8 shows a flow chart for explaining the basic control operation of the heat source system 100 of the second embodiment.

When the load distribution to the heat source groups 10 and 20 from the logarithmic control device 30 is larger than the operable load range for the number of heat source units during operation, each heat source group 10, 20 ), And updates the optimum load range and the operable load range, respectively. Specifically, in the heat source system 100, for example, ten heat source units 12 are connected to the first group control device 11 (the load range capable of corresponding to the entire heat source group is 100%), When the load distribution from the logarithmic control device 30 is made larger than 10% in the case of one operation state (the operation loadable range corresponding to the operation state is 10%), the number of drives is updated from 1 to 2 , The optimum load range for the two heat source units and the operable load range for the three heat source units are set as the optimum load range and the operable load range of the entire heat source group.

As shown in Fig. 8, when the control is started, first, the first group control device 11 and the second group control device 21 determine whether there is a load distribution larger than the operation load range Hi side of the heat source unit during operation (S201).

The first group control device 11 and the second group control device 21 increase the number of operation of the heat source unit when there is a load distribution larger than the operation load range Hi side of the heat source unit during operation, The optimum load range and the operable load range of the whole units (10, 20) are updated.

At this time, the first group control device 11 and the second group control device 21 terminate the process when there is no load distribution larger than the operation load range Hi side of the heat source unit during operation.

The heat source system 100 of the present embodiment increases the load allocation after all the heat source groups 10 and 20 under management become the one heat source unit operation state as viewed from the logarithmic control device 30, It is possible to automatically increase the number of heat source unit operations in the heat source units 10 and 20.

Next, the third embodiment will be described with reference to Fig. 9, but the same parts as those of the first embodiment are denoted by the same reference numerals, and a description thereof will be omitted, and only different points will be described. Fig. 9 shows a flowchart for explaining the basic control operation of the heat source system 100 of the third embodiment.

When the load distribution to the heat source group from the logarithmic control device 30 is smaller than the operable load range for the number of heat source units during operation, the heat source system 100 performs the heat source unit operation in the heat source groups 10 and 20 Thereby reducing the logarithm and updating the optimum load range and the operable load range, respectively. More specifically, for example, ten heat source units are connected to each of the group controllers 11 and 21 (a load range capable of corresponding to the entire heat source group is set to 100%), and two operation states 20%), the number of drives is updated from two to one when the load distribution from the logarithmic control device 30 is made less than 20%, and the optimum load for one heat source unit Range and the operating load range of the two heat source units as the optimum load range and the operable load range of the whole group.

As shown in Fig. 9, when the control is started, first, the first group control device 11 and the second group control device 21 determine whether there is a load distribution smaller than the operable load range Lo side of the heat source unit during operation (S301).

The first group control device 11 and the second group control device 21 reduce the number of operation of the heat source unit when there is a load distribution smaller than the operation load range Lo side of the heat source unit during operation, The optimum load range and the operable load range of all the units 10 and 20 are updated (S302).

At this time, the first group control device 11 and the second group control device 21 terminate the process when there is no load distribution smaller than the operable load range Lo side of the heat source unit during operation.

The heat source system 100 of the present embodiment can reduce the load allocation after all of the groups under management are in the plural unit operation state as viewed from the logarithmic control device 30, The number of unit operations can be automatically reduced.

Further, the heat source system and the heat source control method are not limited to the above-described embodiments, but can be appropriately modified or improved.

It is possible to control the number of movable units of the heat source units included in the plurality of heat source groups so as not to cause a sudden change.

100: Heat source system
10: First heat source group
11: First group control device
12, 22: heat source unit
13, 23: Unit integrated substrate
14, 24: First operation range output section
15, 25: Second operation range output section
20: second heat source group
21: Second group control device
30: Algebraic control device
41: Water inlet
42: Water outlet

Claims (8)

A plurality of heat source groups including a plurality of heat source units,
A group controller for starting and stopping the plurality of heat source units included in each of the heat source groups and assigning a load,
And an algebraic control unit for stopping the heat source group and assigning a load,
The group control unit,
And an optimum load range output section for outputting, to the logarithmic control section, an optimum load range in which the characteristic values corresponding to the number of the heat source units during operation are within a predetermined range, based on characteristic values of the respective heat source units,
The logarithmic control section increases the number of maneuvers of the heat source group before changing the number of operations of the heat source unit by the group control section in each heat source group in response to the demand load exceeding the optimum load range The load of each of the heat source groups is allocated,
Wherein the group control unit increases the number of heat source units included in the heat source group and updates the optimum load range when the load allocated by the logarithmic control unit is larger than the optimum load range,
Wherein the group control unit decreases the number of operation of the heat source units included in the heat source group and updates the optimum load range when the load allocated by the logarithmic control unit is smaller than the optimum load range, . The method according to claim 1,
A first operation for outputting to the logarithmic control unit a load range in which one of the characteristic values corresponding to the number of the heat source units during operation is in a predetermined range as a first proper operation range on the basis of characteristic values of the respective heat source units A range output unit,
And a second operating range outputting section for outputting a load range in which the other one of the characteristic values falls within the predetermined range to a second suitable operating range and outputting the second operating range to the logarithmic control section
Lt; / RTI >
Wherein the first operation range output unit sets the COP information indicating the relationship between the load coefficient and the load coefficient as the characteristic value and sets the load range in which one of the characteristic values corresponding to the number of the heat source units during operation is equal to or greater than a predetermined value 1 < / RTI > suitable operating range,
And the second operation range output unit outputs the load range in which the other one of the characteristic values is equal to or greater than a predetermined value as the second proper operation range to the logarithmic control unit. 3. The apparatus according to claim 2, wherein the first operating range outputting section sets the inverter input information as the characteristic value and sets the load range in which one of the characteristic values corresponding to the number of the heat source units during operation to be equal to or less than a predetermined value, And outputs it to the logarithmic control unit as an appropriate operation range,
And the second operation range output section outputs the load range in which the other one of the characteristic values is equal to or less than a predetermined value as the second proper operation range to the logarithmic control section. 4. The heat pump unit according to any one of claims 1 to 3, wherein the group control unit is operable to set an optimum load range corresponding to the number during operation and an operable load range corresponding to the logarithm + As the transmission data from the group control unit. delete delete The heat source control device according to claim 1,
And a heat source group of the plurality of heat source units. A group control step of starting and stopping a plurality of heat source units included in each of the heat source groups and assigning a load in a plurality of heat source groups including a plurality of heat source units,
And an algebraic control step of stopping the heat source and assigning a load,
The group control step includes:
And an optimum load range output step of outputting an optimum load range in which the characteristic value corresponding to the number of the heat source units during operation is within a predetermined range, based on the characteristic values of the respective heat source units,
Wherein the logarithmic control step increases the number of maneuvers of the heat source group before changing the number of operations of the heat source unit in each heat source group in response to the demand load exceeding the optimum load range, Of the load,
Wherein the group control step increases the number of heat source units included in the heat source group and updates the optimum load range when the load allocated in the logarithmic control step is larger than the optimum load range,
Wherein the group control step includes the steps of: when the load allocated in the logarithmic control step is smaller than the optimum load range, the number of operations of the heat source units included in the heat source group is decreased, Control method.

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