JP2013160397A - Chiller control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To lengthen a service life while securing a load following characteristic at start as the entire system.SOLUTION: A chiller control system (10) includes a family control unit (12) which allows one group having less operation time than the other groups to preferentially operate, from among first to third groups (Gr 1 to Gr 3) corresponding to one load, while first to third group control units (13 to 15) corresponding to the first to third groups (Gr 1 to Gr 3) which are operated with the family control unit (12) are so configured as to operate corresponding heat pump chillers (D1 to D4, D5, D6, D7, D8) simultaneously.

Description

    The present invention relates to a chiller control system, and particularly relates to operation control of a plurality of chillers.

    Conventionally, as shown in Patent Document 1, a large chiller device disposed on the roof of a building such as a building is known. This chiller device is composed of a plurality of heat pump chiller outdoor units. In the chiller device (a) shown in FIG. 24, the outdoor units (b) of a plurality of heat pump chillers are divided into a large number of groups (c, d, e). The chiller device (a) is controlled for each group (c, d, e) so as to cool or heat the air-conditioning water supplied to the building.

JP 2008-202857 A

    However, in the chiller device (a), the outdoor unit (b) of a specific group (for example, group (c)) always operates at the time of activation. For this reason, there is a high risk that only a specific group of outdoor units (b) will malfunction early. That is, there is a problem that the life of the chiller device (a) cannot be extended as a whole.

    The present invention has been made in view of such a point, and an object thereof is to extend the life of the entire system.

    The first invention corresponds to a plurality of control units (Gr1 to Gr3) each having at least one chiller (D1 to D4, D5, D6, D7, D8) and each control unit (Gr1 to Gr3). A chiller control system comprising a unit controller (13-15) for controlling the chillers (D1 to D4, D5, D6, D7, D8), and a plurality of the control units (Gr1) corresponding to one load To Gr3), the unit control unit (13 to 15) includes the overall control unit (12) that operates with priority given to one control unit having a shorter operation time than other control units. It is configured to control the chillers (D1 to D4, D5, D6, D7, and D8) of the control units (Gr1 to Gr3) operated by the unit (12).

    In the first invention, the overall control unit (12) controls a plurality of control units (Gr1 to Gr3) corresponding to one load (for example, the water temperature of a common water piping for air conditioning water). Specifically, the overall control unit (12) preferentially operates one control unit having a shorter operation time than the other control units among the plurality of control units (Gr1 to Gr3). By doing so, the operation times of the plurality of control units (Gr1 to Gr3) are leveled.

    Each control unit (Gr1 to Gr3) is configured to have at least one chiller (D1 to D4, D5, D6, D7, D8). The unit control unit (13-15) corresponding to the control unit (Gr1-Gr3) operated by the general control unit (12) operates the corresponding chiller (D1-D4, D5, D6, D7, D8) .

    In a second aspect based on the first aspect, each of the control units (Gr1 to Gr3) has a plurality of the chillers (D1 to D4, D5, D6, D7, D8).

    In the second invention, each control unit (Gr1 to Gr3) is configured to have a plurality of chillers (D1 to D4, D5, D6, D7, D8). The unit controllers (13 to 15) control a plurality of chillers (D1 to D4, D5, D6, D7, and D8) of the control units (Gr1 to Gr3) operated by the overall controller (12).

    According to a third aspect, in the second aspect, the unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) include a plurality of corresponding units. The chillers (D1 to D4, D5, D6, D7, D8) are configured to operate simultaneously.

    In the third invention, each control unit (Gr1 to Gr3) is configured to have a plurality of chillers (D1 to D4, D5, D6, D7, D8). The unit control units (13-15) corresponding to the control units (Gr1-Gr3) operated by the general control unit (12) are connected to the corresponding chillers (D1-D4, D5, D6, D7, D8). Drive at the same time. The unit controller (13-15) operates multiple chillers (D1 to D4, D5, D6, D7, D8) of each control unit (Gr1 to Gr3) at the same time, thereby improving the ability to follow sudden load fluctuations. .

    In a fourth aspect based on the second aspect, the unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) include a plurality of corresponding chillers. Among (D1 to D4, D5, D6, D7, D8), one chiller having a shorter operation time than other chillers is configured to be operated with priority.

    In the fourth invention, each control unit (Gr1 to Gr3) has a plurality of chillers (D1 to D4, D5, D6, D7, D8), and the unit control units (13 to 15) correspond to the corresponding controls. Controls the chillers (D1 to D4, D5, D6, D7, and D8) of the units (Gr1 to Gr3). The overall control unit (12) controls a plurality of control units (Gr1 to Gr3) corresponding to one load (for example, the water temperature of a common water pipe for air conditioning water). Specifically, the overall control unit (12) preferentially operates one control unit having a shorter operation time than the other control units among the plurality of control units (Gr1 to Gr3). By doing so, the operation time between the plurality of control units (Gr1 to Gr3) can be leveled, and fine load fluctuations can be dealt with.

    The unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) are connected to a plurality of chillers (D1 to D4, D5, D6) of the control units (Gr1 to Gr3). , D7, D8), the one chiller with a shorter operation time than other chillers is operated with priority. By doing so, the operation time of the plurality of chillers (D1 to D4, D5, D6, D7, D8) can be leveled and a fine load fluctuation can be dealt with.

    According to a fifth invention, in the first or second invention, the unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) The chiller (D1 to D4, D5, D6, D7, D8) is configured to be limited to an operation with a predetermined load or less.

    In the fifth invention, each control unit (Gr1 to Gr3) has at least one chiller (D1 to D4, D5, D6, D7, D8), and the unit controllers (13 to 15) correspond to each other. Controls the chillers (D1 to D4, D5, D6, D7, and D8) of the control units (Gr1 to Gr3). The overall control unit (12) controls a plurality of control units (Gr1 to Gr3) corresponding to one load (for example, the water temperature of a common water pipe for air conditioning water). Specifically, the overall control unit (12) preferentially operates one control unit having a shorter operation time than the other control units among the plurality of control units (Gr1 to Gr3). By doing so, the operation time between the plurality of control units (Gr1 to Gr3) is leveled.

    The unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) send the corresponding chillers (D1 to D4, D5, D6, D7, and D8) to a predetermined level. Operate by limiting the load. For this reason, the corresponding chillers (D1 to D4, D5, D6, D7, and D8) of each control unit (Gr1 to Gr3) can be operated with an efficient load.

    In a sixth aspect based on the second aspect, the unit control units (13 to 15) are provided with a plurality of chillers (D1 to D4) of the control unit (Gr1) operated by the overall control unit (12). Of the chillers (D5, D6, D7, D8) of the control unit (Gr2, Gr3) operated by the first unit controller (13) and the general controller (12) operated simultaneously, other chillers And a second unit control unit (14, 15) for preferentially operating the one chiller having a shorter operation time.

    In the sixth invention, each control unit (Gr1 to Gr3) has a plurality of chillers (D1 to D4, D5, D6, D7, D8), and the unit control units (13 to 15) correspond to the corresponding controls. Controls the chillers (D1 to D4, D5, D6, D7, and D8) of the units (Gr1 to Gr3). The overall control unit (12) controls a plurality of control units (Gr1 to Gr3) corresponding to one load (for example, the water temperature of a common water pipe for air conditioning water). Specifically, the overall control unit (12) preferentially operates one control unit having a shorter operation time than the other control units among the plurality of control units (Gr1 to Gr3). By doing so, the operation time between the plurality of control units (Gr1 to Gr3) is leveled.

    The unit controller (13-15) includes a first unit controller (13) and a second unit controller (14, 15). The first unit controller (13) simultaneously operates the chillers (D1 to D4) of the corresponding control unit (Gr1). By simultaneously operating a plurality of chillers (D1 to D4) of the control unit (Gr1), followability to a sudden load is enhanced.

    In addition, the second unit control unit (14, 15) is configured to give priority to the operation of one chiller having a shorter operating time than the other chillers among the plurality of chillers (D5, D6, D7, D8). Yes. By doing so, the followability to fine load fluctuations is enhanced.

    According to the first aspect, since the control units (Gr1 to Gr3) having a short operation time are operated with priority, the operation times of all the control units (Gr1 to Gr3) can be leveled. For this reason, since it can prevent that a specific control unit (Gr1-Gr3) always operates, the lifetime improvement of the whole chiller control system can be aimed at.

    According to the second aspect, each control unit (Gr1 to Gr3) has a plurality of chillers (D1 to D4, D5, D6, D7, and D8), and thus a plurality of chillers (D1 to D4, D5). , D6, D7, D8) can be controlled for each control unit (Gr1 to Gr3). Therefore, a large number of chillers (D1 to D4, D5, D6, D7, D8) can be controlled with a simple configuration.

    According to the third invention, a plurality of chillers (D1 to D4, D5, D6, D7, and D8) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) are operated simultaneously. As a result, it is possible to improve the follow-up performance against a sudden load fluctuation. As a result, as a whole chiller control system, it is possible to extend the life while ensuring followability to load fluctuations at the time of startup and the like.

    According to the fourth aspect of the invention, since the general control unit (12) operates the control units (Gr1 to Gr3) having a short operation time with priority, the operation time of all the control units (Gr1 to Gr3) is reduced. Can be leveled. For this reason, since it can prevent that a specific control unit (Gr1-Gr3) always operates, the lifetime improvement of the whole chiller control system can be aimed at.

    In addition, the unit control units (13-15) corresponding to the control units (Gr1-Gr3) operated by the general control unit (12) have chillers (D1-D4, D5, D6, D7, D8) with a short operation time. As a result, the operation time of the plurality of chillers (D1 to D4, D5, D6, D7, and D8) of each control unit (Gr1 to Gr3) can be leveled. Also, while operating each control unit (Gr1 to Gr3) in order, multiple chillers (D1 to D4, D5, D6, D7, D8) are operated in order, so that followability to fine load fluctuations can be improved. it can.

    As a result, as a whole chiller control system, it is possible to extend the life while keeping track of fine load fluctuations.

    According to the fifth aspect of the invention, since the general control unit (12) operates the control units (Gr1 to Gr3) having a short operation time with priority, the operation time of all the control units (Gr1 to Gr3) is reduced. Can be leveled. For this reason, since it can prevent that a specific control unit (Gr1-Gr3) always operates, the lifetime improvement of the whole chiller control system can be aimed at.

    In addition, the unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) specify the corresponding chillers (D1 to D4, D5, D6, D7, and D8). Therefore, the chillers (D1 to D4, D5, D6, D7, D8) can be operated at an efficient load. Thereby, a chiller (D1-D4, D5, D6, D7, D8) can be drive | operated by energy saving.

    As a result, as a whole chiller control system, it is possible to achieve energy-saving operation while ensuring followability to fine load fluctuations.

    According to the sixth invention, the overall control unit (12) operates the control units (Gr1 to Gr3) having a short operation time with priority, so the operation time of all the control units (Gr1 to Gr3) is reduced. Can be leveled. For this reason, since it can prevent that a specific control unit (Gr1-Gr3) always operates, the lifetime improvement of the whole chiller control system can be aimed at.

    In addition, since the second unit control unit (14, 15) is operated with priority on the chillers (D5, D6, D7, D8) with a short operation time, a plurality of chillers of each control unit (Gr2, Gr3) The operating time of (D5, D6, D7, D8) can be leveled. In addition, since the plurality of chillers (D5, D6, D7, D8) of each control unit (Gr2, Gr3) are operated in order, it is possible to improve the followability to a fine load fluctuation.

    Furthermore, since the chillers (D1 to D4) corresponding to the control unit (Gr1) are operated simultaneously, the followability to a sudden load change can be enhanced.

    As a result, as a whole chiller control system, it is possible to maintain followability to a rapid load fluctuation at the time of start-up, maintain followability to a fine load change after start-up, and extend the life.

It is the schematic which shows the structure of the chiller control system which concerns on this Embodiment 1-4. It is a figure which shows the control content which concerns on this Embodiment 1. FIG. It is a figure which shows the control action which concerns on this Embodiment 1. FIG. It is a figure which shows the control action which concerns on this Embodiment 1. FIG. It is a figure which shows the control action which concerns on this Embodiment 1. FIG. It is a figure which shows the control action which concerns on this Embodiment 1. FIG. It is a graph which shows the relationship between the operation time of the chiller control system which concerns on this Embodiment 1, and load. It is a figure which shows the control content which concerns on this Embodiment 2. FIG. It is a figure which shows the control action which concerns on this Embodiment 2. FIG. It is a figure which shows the control action which concerns on this Embodiment 2. FIG. It is a figure which shows the control action which concerns on this Embodiment 2. FIG. It is a graph which shows the relationship between the driving time of the chiller control system which concerns on this Embodiment 2, and load. It is a figure which shows the control content which concerns on this Embodiment 3. FIG. It is a figure which shows the control action which concerns on this Embodiment 3. It is a figure which shows the control action which concerns on this Embodiment 3. It is a figure which shows the control action which concerns on this Embodiment 3. It is a figure which shows the control action which concerns on this Embodiment 3. It is a graph which shows the relationship between the operation time of the chiller control system which concerns on this Embodiment 3, and load. It is a figure which shows the control content which concerns on this Embodiment 4. It is a figure which shows the control action which concerns on this Embodiment 4. It is a figure which shows the control action which concerns on this Embodiment 4. It is a figure which shows the control action which concerns on this Embodiment 4. It is a graph which shows the relationship between the operation time of the chiller control system which concerns on this Embodiment 4, and load. It is a figure which shows the structure of the chiller apparatus which concerns on a prior art example. It is a graph which shows the relationship between the operation time and load of the chiller apparatus which concerns on a prior art example.

<Embodiment 1>
Hereinafter, Embodiment 1 of the present invention will be described in detail with reference to the drawings.

    FIG. 1 shows a chiller control system (10) according to Embodiment 1 of the present invention. The chiller control system (10) includes a controller (11) that controls the operation of the first to third groups (Gr1 to Gr3) each having a plurality of heat pump chillers (D1 to D8) and the heat pump chillers (D1 to D8). ).

    The heat pump chillers (D1 to D8) are installed on the roof of a building or the like for cooling or heating water for air conditioning supplied into the building, and constitute the chiller according to the present invention. Yes. The heat pump chillers (D1 to D8) include a casing having a heat exchanger and a blower fan, and are configured to blow out the air taken into the casing through the heat exchanger to the outside of the casing by the blower fan. . The air taken in the casing is heat-exchanged when passing through the heat exchanger.

    The first group (Gr1) is composed of four heat pump chillers (D1 to D4), the second group (Gr2) is composed of two heat pump chillers (D5, D6), and the third group (Gr3 ) Is composed of two heat pump chillers (D7, D8). The heat pump chillers (D1 to D8) are connected to the same water pipe (16). The temperature load of air conditioning water flowing through the water pipe (16) refers to the load according to the present embodiment and the present invention. Each of the groups (Gr1 to Gr3) constitutes a control unit according to the present invention.

    The controller (11) includes a first group controller (13) that controls the first group (Gr1), a second group controller (14) that controls the second group (Gr2), and a third group (Gr3 ) And a family control unit (12) that controls the first to third groups (Gr1 to Gr3) in an integrated manner.

    As shown in FIG. 2, each group control part (13-15) performs group control with respect to the heat pump chillers (D1-D8) of each corresponding group (Gr1-Gr3), and this invention The unit control part which concerns on this is comprised. Specifically, the first group controller (13) is connected to the first group (Gr1), the second group controller (14) is connected to the second group (Gr2), and the third group controller (15) is connected to the third group (Gr3). This group control is set in advance, for example, at the time of installation of the heat pump chillers (D1 to D8) according to the user's request.

    In this Embodiment 1, each group control part (13-15) performs simultaneous control as group control with respect to each group (Gr1-Gr3) which each respond | corresponds. Specifically, in the simultaneous control in the first group (Gr1), when the first group control unit (13) receives the operation signal, the four heat pump chillers (D1 to D4) constituting the first group (Gr1) Give all 100% load operation commands. On the other hand, when the first group control unit (13) receives the operation stop signal, it stops all the heat pump chillers (D1 to D4). In the simultaneous control of the second group (Gr2), similarly to the first group (Gr1), the two heat pump chillers (D5, D6) that make up the second group (Gr2) are activated at 100% load simultaneously. Repeat the stop. In addition, in the simultaneous control of the third group (Gr3), the two heat pump chillers (D7, D8) constituting the third group (Gr3) are simultaneously at 100% load as in the first group (Gr1). Repeat starting and stopping.

    The family control unit (12) performs family control on the first to third group control units (13 to 15), and constitutes an overall control unit according to the present invention. This family control is set in advance, for example, at the time of installation of each heat pump chiller (D1 to D8) according to the user's request.

    This family control part (12) performs rotation control as family control with respect to each of the first to third group control parts (13 to 15). That is, the first to third groups (Gr1 to Gr3) constitute one family. In the rotation control of the family control unit (12), the operation of each group (Gr1 to Gr3) in the family is controlled so as to equalize the total operation time for each group (Gr1 to Gr3). This total operation time constitutes the operation time according to the present invention. Specifically, when receiving an operation signal, the family control unit (12) determines a higher priority in the order of the group with the shortest total operation time within the family to be controlled. And a family control part (12) starts a driving | operation in order from the group (namely, group with the shortest total operation time) with the highest priority. Then, when the group that starts operation and performs water temperature control reaches 100% load, the operation of the next highest priority group is started. For this reason, in the rotation control, variations in the total operation time for each group (Gr1 to Gr3) are reduced.

    Further, in this rotation control, control is performed so that the group with the lowest priority among the groups in operation (that is, the group with a long total operation time) performs fine adjustment of the water temperature. In the first embodiment, it is assumed that the priority is higher in the order of the first group (Gr1), the second group (Gr2), and the third group (Gr3).

    In the family control unit (12), after 24 hours of continuous operation, the priority of the first group (Gr1) with the first priority is changed to the last priority, and the groups with the second or lower rank (Gr2, Gr3) ) Goes up one by one. In other words, the operation time is leveled by changing the priority order every 24 hours.

    In the family control unit (12), the priority order may be determined in ascending order of the average value of the number of times of start / stop of each group (Gr1 to Gr3), not the total operation time of each group (Gr1 to Gr3). Good.

-Driving action-
Next, operation control of the chiller control system (10) according to the first embodiment will be described. In the chiller control system (10), as shown in FIG. 3, first, the family control unit (12) has the first group (Gr1) having the shortest total operation time among the first to third groups (Gr1 to Gr3). ) Is started. In the first group (Gr1), the four heat pump chillers (D1 to D4) in the group are activated at 100% load at the same time. When all the heat pump chillers (D1 to D4) are started at 100% load at the same time, as shown in FIG. 7 (a), a sudden load increase (400%) at the start of the chiller control system (10) Can follow.

    Next, as shown in FIG. 4, the family control unit (12) starts the operation of the second group (Gr2) with the second shortest total operation time in response to the sudden increase in load (200%). . In the second group (Gr2), the two heat pump chillers (D5, D6) in the group are activated at 100% load at the same time. By starting all the heat pump chillers (D5, D6) at 100% load at the same time, as shown in FIG. 7 (b), it is possible to follow a sudden load increase (200%).

    Thereafter, as shown in FIG. 5, the family control unit (12) starts the operation of the remaining third group (Gr3) in response to a rapid load increase (200%). In the third group (Gr3), the two heat pump chillers (D7, D8) in the group are activated at 100% load at the same time. By starting all the heat pump chillers (D7, D8) at 100% load at the same time, it is possible to follow a sudden increase in load (200%) as shown in FIG.

    Next, as shown in FIG. 6, the family control unit (12) stops the operation of the third group (Gr3) in response to a rapid load decrease (200%). In the third group (Gr3), the two heat pump chillers (D7, D8) in the group stop simultaneously. By stopping all the heat pump chillers (D7, D8) at the same time, it is possible to follow a rapid load drop (200%) as shown in FIG.

-Effect of Embodiment 1-
According to the first embodiment, the rotation control is performed in the family control, while the simultaneous control is performed in each group control. Therefore, the start / stop can be performed for each group (Gr1 to Gr3). For this reason, the followability with respect to load fluctuation | variation can be made high. As a result, the water temperature can be quickly brought close to the target temperature even at a high load when the chiller control system (10) is started. In addition, the water temperature can be quickly brought close to the target temperature even in a sudden load fluctuation during operation of the chiller control system (10).

    Moreover, since rotation control is performed in the family control, the group (Gr1 to Gr3) to be operated can be determined based on the total operation time for each group (Gr1 to Gr3). Thereby, the total operation time of each group (Gr1-Gr3) can be equalized.

    As a result, as a whole chiller control system (10), it is possible to extend the service life while ensuring followability to load fluctuations at the time of startup or the like.

    Here, the conventional chiller device (a) may be installed in a property having a wide space such as a concert hall or a gymnasium. In the case of such a property, there is a feature that the cooling or heating load at the time of starting the chiller device (a) becomes large. For this reason, in the chiller device (a), by performing simultaneous control to start and stop all the outdoor units (b) in the group (c, d, e) at the same time, it corresponds to the load fluctuation at the time of startup.

    However, in the chiller device (a), the outdoor unit (b) of a specific group (for example, group (c)) always operates at the time of activation. For this reason, there is a high risk that only a specific group of outdoor units (b) will malfunction early. That is, as a whole chiller device (a), there is a problem that it is not possible to extend the life while ensuring followability to load fluctuations at the time of start-up.

    On the other hand, the chiller control system (10) according to the first embodiment is suitable for such a property because it can improve followability to load fluctuations at the time of start-up and the like and can extend the life. .

<Embodiment 2 of the invention>
Next, Embodiment 2 of the present invention will be described. The chiller control system (10) according to the second embodiment is different from that according to the first embodiment in the configuration of the group control units (13 to 15) of the controller (11).

    FIG. 1 shows a chiller control system (10) according to Embodiment 2 of the present invention. The chiller control system (10) includes a controller (11) that controls the operation of the first to third groups (Gr1 to Gr3) each having a plurality of heat pump chillers (D1 to D8) and the heat pump chillers (D1 to D8). ).

    The heat pump chillers (D1 to D8) are installed on the roof of a building or the like for cooling or heating water for air conditioning supplied into the building, and constitute the chiller according to the present invention. Yes. The heat pump chillers (D1 to D8) include a casing having a heat exchanger and a blower fan, and are configured to blow out the air taken into the casing through the heat exchanger to the outside of the casing by the blower fan. . The air taken in the casing is heat-exchanged when passing through the heat exchanger.

    The first group (Gr1) is composed of four heat pump chillers (D1 to D4), the second group (Gr2) is composed of two heat pump chillers (D5, D6), and the third group (Gr3 ) Is composed of two heat pump chillers (D7, D8). The heat pump chillers (D1 to D8) are connected to the same water pipe (16). The temperature load of the air conditioning water flowing through the water pipe (16) refers to the load according to the second embodiment and the present invention. Each of the groups (Gr1 to Gr3) constitutes a control unit according to the present invention.

    The controller (11) includes a first group controller (13) that controls the first group (Gr1), a second group controller (14) that controls the second group (Gr2), and a third group (Gr3 ) And a family control unit (12) that controls the first to third groups (Gr1 to Gr3) in an integrated manner.

    As shown in FIG. 8, each group control part (13-15) performs group control with respect to the heat pump chiller (D1-D8) of each corresponding group (Gr1-Gr3), and this invention The unit control part which concerns on this is comprised. Specifically, the first group controller (13) is connected to the first group (Gr1), the second group controller (14) is connected to the second group (Gr2), and the third group controller (15) is connected to the third group (Gr3). This group control is set in advance, for example, at the time of installation of the heat pump chillers (D1 to D8) according to the user's request.

    Specifically, each group control part (13-15) which concerns on this Embodiment 2 performs rotation control as group control with respect to each corresponding group (Gr1-Gr3).

    In the rotation control in the first group (Gr1), the operation of each heat pump chiller (D1 to D4) is controlled so that the total operation time for each of the four heat pump chillers (D1 to D4) in the group is leveled. Specifically, in the first group control unit (13), when an operation signal is received, a higher priority order is determined in the order of heat pump chillers with less total operation time within the group. And a 1st group control part (13) starts an operation | movement in an order from the heat pump chiller with the highest priority (namely, heat pump chiller with the shortest total operation time). When the operation starts and the heat pump chiller that controls the water temperature reaches a predetermined load, the operation of the heat pump chiller with the next highest priority is started. For this reason, in rotation control, dispersion | variation decreases in the total operation time for each heat pump chiller (D1-D4) in a group.

    In this rotation control, the heat pump chiller with the lowest priority among the operating heat pump chillers (D1 to D4) (that is, the heat pump chiller with a long total operation time) performs fine adjustment of the water temperature. And when load falls, a driving | operation is stopped in order with a low priority. Further, when receiving the stop signal, the first group control unit (13) simultaneously stops all the heat pump chillers (D1 to D4) in the group. In the first group (Gr1), as shown in FIG. 10, heat pump chiller (D4) (280 hours), heat pump chiller (D3) (300 hours), heat pump chiller (D1) (350 hours), heat pump chiller ( D2) It is assumed that the priority is higher in the order of (370 hours).

    In the first group control unit (13), after 24 hours of continuous operation, the priority order of the heat pump chiller with the first priority is changed to the last priority, and the heat pump chillers with the second or lower priority are repeated one by one. Go up. In other words, the operation time is leveled by changing the priority order every 24 hours.

    In the first group control unit (13), the priority order is determined not in the total operation time of the heat pump chillers (D1 to D4) but in the order of the number of start / stop times of the heat pump chillers (D1 to D4). Also good. In this case, since the activation does not concentrate on specific heat pump chillers (D1 to D4), the number of times of starting and stopping of each heat pump chiller (D1 to D4) can be leveled.

    In the rotation control in the second group (Gr2), the operation of each heat pump chiller (D5, D6) is controlled so as to equalize the total operation time for each of the two heat pump chillers (D5, D6) in the group. Since the specific control content is the same as that of the first group (Gr1), the description is omitted. In the second group (Gr2), as shown in FIG. 9, the heat pump chiller (D6) (310 hours) and the heat pump chiller (D5) (340 hours) are in order of priority.

    In the rotation control in the third group (Gr3), the operation of each heat pump chiller (D7, D8) is controlled so as to equalize the total operation time for each of the two heat pump chillers (D7, D8) in the group. Since the specific control content is the same as that of the first group (Gr1), the description is omitted.

    The family control unit (12) performs family control on the first to third group control units (13 to 15), and constitutes an overall control unit according to the present invention. This family control is set in advance, for example, at the time of installation of each heat pump chiller (D1 to D8) according to the user's request.

    This family control part (12) performs rotation control as family control with respect to each of the first to third group control parts (13 to 15). That is, the first to third groups (Gr1 to Gr3) form one family. In the rotation control of the family control unit (12), the operation of each group (Gr1 to Gr3) in the family is controlled so as to equalize the total operation time for each group (Gr1 to Gr3). This total operation time constitutes the operation time according to the present invention. Specifically, when receiving an operation signal, the family control unit (12) determines a higher priority in the order of the group with the shortest total operation time within the family to be controlled. And a family control part (12) starts a driving | operation in order from the group (namely, group with the shortest total operation time) with the highest priority. Then, when the operation starts and the group that performs water temperature control reaches 100% load, the operation of the next highest priority group is started. For this reason, in the rotation control, variations in the total operation time for each group (Gr1 to Gr3) are reduced.

    Further, in this rotation control, control is performed so that the group with the lowest priority among the groups in operation (that is, the group with a long total operation time) performs fine adjustment of the water temperature. In the second embodiment, it is assumed that the priority order is higher in the order of the second group (Gr2), the first group (Gr1), and the third group (Gr3).

    In the family control unit (12), after 24 hours of continuous operation, the priority of the group with the first priority is changed to the last priority, and the groups with the second or lower priority are moved up one by one. In other words, the operation time is leveled by changing the priority order every 24 hours.

    In the family control unit (12), the priority order may be determined in ascending order of the average value of the number of times of start / stop of each group (Gr1 to Gr3), not the total operation time of each group (Gr1 to Gr3). Good.

-Driving action-
Next, operation control of the chiller control system (10) according to the second embodiment will be described. In the chiller control system (10), as shown in FIG. 9, the family control unit (12) includes the second group (Gr2) of the first to third groups (Gr1 to Gr3) having the shortest total operation time. Start driving. In the second group (Gr2), of the two heat pump chillers (D5, D6) in the group, start the operation of the heat pump chiller (D6) with a short total operation time. Start chiller (D5) operation. By doing so, as shown in FIG. 12, it is possible to follow fine load fluctuations.

    Next, the family control unit (12) starts the operation of the first group (Gr1) with the second total operation time being the second smallest. In the first group (Gr1), as shown in FIG. 10, among the four heat pump chillers (D1 to D4) in the group, the operation of the heat pump chiller (D4) with the least total operation time is started, and 100% When the load is reached, the operation is started in the order of heat pump chiller (D3), heat pump chiller (D1), and heat pump chiller (D2). By doing so, as shown in FIG. 12, it is possible to follow fine load fluctuations.

    Thereafter, the family control unit (12) starts the operation of the third group (Gr3) with a short total operation time. In the third group (Gr3), as shown in FIG. 11, the operation is started in order from the heat pump chiller having the shortest total operation time among the two heat pump chillers (D7, D8) in the group. By doing so, as shown in FIG. 12, it is possible to follow fine load fluctuations.

    When the water temperature of the heat pump chillers (D1 to D8) reaches the target temperature, the family control unit (12) performs rotation control of each group (Gr1 to Gr3) so as to maintain the water temperature.

-Effect of Embodiment 2-
According to the second embodiment, since the family control unit (12) performs the rotation control, the group to be operated can be determined based on the total operation time for each group (Gr1 to Gr3). Thereby, the total operation time of each group (Gr1-Gr3) can be equalized. For this reason, since it can prevent that a specific group (Gr1-Gr3) always works, the lifetime improvement of the whole chiller control system (10) can be aimed at. Moreover, since each group (Gr1-Gr3) is rotated and started, the followable | trackability with respect to a fine load fluctuation | variation can be improved.

    In addition, since the group control unit (13-15) performs rotation control, it is based on the total operation time for each heat pump chiller (D1-D4, D5, D6, D7, D8) in each group (Gr1-Gr3). The heat pump chillers (D1 to D4, D5, D6, D7, D8) to be operated can be determined. Thereby, the total operation time of the heat pump chillers (D1-D4, D5, D6, D7, D8) of each group (Gr1-Gr3) can be equalized. Moreover, since each group (Gr1-Gr3) and each heat pump chiller (D1-D4, D5, D6, D7, D8) are rotated and started, the followability with respect to a fine load fluctuation | variation can be improved.

    As a result, as a whole chiller control system (10), it is possible to extend the life while maintaining the ability to follow fine load fluctuations.

    Here, the conventional chiller device (a) may be installed in a property mainly composed of a single room air conditioner such as a hospital or a dormitory. In the case of such an article, the cooling or heating load at the start-up of the chiller device (a) increases stepwise, and after the start-up, the fluctuation is small, but a long time operation is required. . For this reason, in the chiller device (a), the outdoor unit (b) in each group (c, d, e) is activated with priority given to the one with the shortest operation time. The operation time of each outdoor unit (b) is leveled, and the load with little fluctuation is dealt with finely.

    However, in the chiller device (a), the operating time of each outdoor unit (b) is leveled in each group (c, d, e), but a specific group always operates at startup. It will be. For this reason, there is a high risk that only a specific group of outdoor units (b) will malfunction early. That is, as a whole chiller device (a), there is a problem that it is not possible to extend the life while maintaining the ability to follow fine load fluctuations.

    In the chiller control system (10) according to the second embodiment, as a whole, it is possible to extend the life while maintaining the ability to follow fine load fluctuations. Other forms, operations and effects are the same as those in the first embodiment.

Embodiment 3 of the Invention
Next, a third embodiment of the present invention will be described. The chiller control system (10) according to the third embodiment is different from that according to the first and second embodiments in the configuration of the group control units (13 to 15) of the controller (11).

    FIG. 1 shows a chiller control system (10) according to Embodiment 3 of the present invention. The chiller control system (10) includes a controller (11) that controls the operation of the first to third groups (Gr1 to Gr3) each having a plurality of heat pump chillers (D1 to D8) and the heat pump chillers (D1 to D8). ).

    The heat pump chillers (D1 to D8) are installed on the roof of a building or the like for cooling or heating water for air conditioning supplied into the building, and constitute the chiller according to the present invention. Yes. The heat pump chillers (D1 to D8) include a casing having a heat exchanger and a blower fan, and are configured to blow out the air taken into the casing through the heat exchanger to the outside of the casing by the blower fan. . The air taken in the casing is heat-exchanged when passing through the heat exchanger.

    The first group (Gr1) is composed of four heat pump chillers (D1 to D4), the second group (Gr2) is composed of two heat pump chillers (D5, D6), and the third group (Gr3 ) Is composed of two heat pump chillers (D7, D8). The heat pump chillers (D1 to D8) are connected to the same water pipe (16). The temperature load of the air conditioning water flowing through the water pipe (16) refers to the load according to the third embodiment and the present invention. Each of the groups (Gr1 to Gr3) constitutes a control unit according to the present invention.

    The controller (11) includes a first group controller (13) that controls the first group (Gr1), a second group controller (14) that controls the second group (Gr2), and a third group (Gr3 ) And a family control unit (12) that controls the first to third groups (Gr1 to Gr3) in an integrated manner.

    Each group control part (13-15) performs group control with respect to the heat pump chillers (D1-D8) of each corresponding group (Gr1-Gr3), as shown in FIG. The unit control part which concerns on this is comprised. Specifically, the first group controller (13) is connected to the first group (Gr1), the second group controller (14) is connected to the second group (Gr2), and the third group controller (15) is connected to the third group (Gr3). This group control is set in advance, for example, at the time of installation of the heat pump chillers (D1 to D8) according to the user's request.

    Specifically, each group control part (13-15) which concerns on this Embodiment 3 carries out driving efficiency priority control (henceforth efficiency control) as group control with respect to each corresponding group (Gr1-Gr3). Is what you do.

    In the efficiency control in the first group (Gr1), the operation is controlled in consideration of the operation efficiency of the two heat pump chillers (D1 to D4) in the group. Specifically, when the operation signal is received, the first group control unit (13) determines a higher priority in the order of the heat pump chillers with the shortest total operation time within the group. And a 1st group control part (13) starts an operation | movement in an order from the heat pump chiller with the highest priority (namely, heat pump chiller with the shortest total operation time). When the operation starts and the heat pump chiller that controls the water temperature reaches a predetermined load, the operation of the heat pump chiller with the next highest priority is started. For this reason, in efficiency control, dispersion | variation decreases in the total operation time for each heat pump chiller (D1-D4) in a group.

    Here, in the first group (Gr1), each heat pump chiller (D1 to D4) operates at a load (hereinafter referred to as efficiency% load) at which the maximum operation efficiency is achieved. This efficiency% load means, for example, a 40% load as shown in FIG. For this reason, in the efficiency control, it is possible to perform operation with good operation efficiency for the entire first group (Gr1).

    Further, in this efficiency control, the heat pump chiller with the lowest priority among the heat pump chillers (D1 to D4) in operation (that is, the heat pump chiller with a long total operation time) performs fine adjustment of the water temperature. And when load falls, a driving | operation is stopped in order of a heat pump chiller with a low priority. Further, when receiving the stop signal, the first group control unit (13) simultaneously stops all the heat pump chillers (D1 to D4) in the group.

    In the first group control unit (13), after 24 hours of continuous operation, the priority order of the heat pump chiller with the first priority is changed to the last priority, and the heat pump chillers with the second or lower priority are repeated one by one. Go up. In other words, the operation time is leveled by changing the priority order every 24 hours.

    In the first group control unit (13), the priority order is determined not in the total operation time of the heat pump chillers (D1 to D4) but in the order of the number of start / stop times of the heat pump chillers (D1 to D4). Also good. In this case, since activation does not concentrate on a specific heat pump chiller, the number of times of starting and stopping of each heat pump chiller (D1 to D4) can be leveled.

    In the efficiency control in the second group (Gr2), the operation is controlled in consideration of the operation efficiency of the two heat pump chillers (D5, D6) in the group. Since the specific control content is the same as that of the first group (Gr1), the description is omitted. In the second group (Gr2), as shown in FIG. 14, the heat pump chiller (D6) (310 hours) and the heat pump chiller (D5) (340 hours) are in order of priority.

    In the efficiency control in the third group (Gr3), the operation is controlled in consideration of the operation efficiency of the two heat pump chillers (D7, D8) in the group. Since the specific control content is the same as that of the first group (Gr1), the description is omitted.

    The family control unit (12) performs family control on the first to third group control units (13 to 15), and constitutes an overall control unit according to the present invention. This family control is set in advance, for example, at the time of installation of each heat pump chiller (D1 to D8) according to the user's request.

    This family control part (12) performs rotation control as family control with respect to each of the first to third group control parts (13 to 15). That is, the first group (Gr1 to Gr3) constitutes one family. In the rotation control of the family control unit (12), the operation of each group (Gr1 to Gr3) in the family is controlled so as to equalize the total operation time for each group (Gr1 to Gr3). This total operation time constitutes the operation time according to the present invention. Specifically, when receiving an operation signal, the family control unit (12) determines a higher priority in the order of the group with the shortest total operation time within the family to be controlled. And a family control part (12) starts a driving | operation in order from the group (namely, group with the shortest total operation time) with the highest priority. And when the group which starts operation and performs water temperature control reaches 100% load, the operation of the group with the next highest priority is started. For this reason, in the rotation control, variations in the total operation time for each group (Gr1 to Gr3) are reduced.

    Further, in this rotation control, the group having the lowest priority among the groups in operation (that is, the group having a long total operation time) performs control for fine adjustment of the water temperature. In the third embodiment, as shown in FIG. 14, it is assumed that the priority order is higher in the order of the second group (Gr2), the first group (Gr1), and the third group (Gr3).

    In the family control unit (12), after 24 hours of continuous operation, the priority of the group with the first priority is changed to the last priority, and the groups with the second or lower priority are moved up one by one. In other words, the operation time is leveled by changing the priority order every 24 hours.

    In the family control unit (12), the priority order may be determined in ascending order of the average value of the number of times of start / stop of each group (Gr1 to Gr3), not the total operation time of each group (Gr1 to Gr3). Good.

-Driving action-
Next, operation control of the chiller control system (10) according to the third embodiment will be described. In the chiller control system (10), as shown in FIG. 14, the family control unit (12) includes the second group (Gr2) of the first to third groups (Gr1 to Gr3) having the shortest total operation time. Start driving. In the second group (Gr2), of the two heat pump chillers (D5, D6) in the group, start the operation of the heat pump chiller (D6) with less total operation time, and when the efficiency% load is reached, As shown in FIG. 15, the operation of the heat pump chiller (D5) is started. By doing so, as shown in FIG. 18, it is possible to follow fine load fluctuations.

    Next, the family control unit (12) starts operation in the order of the first group (Gr1) and the third group (Gr3) with the second smallest total operation time. At this time, in each group (Gr1, Gr3), the operation of the heat pump chiller with the highest priority within the group is started, and when this heat pump chiller reaches the efficiency% load, the operation is performed in order from the heat pump chiller with the next highest priority. Let's start. By doing so, as shown in FIG. 18, it is possible to follow fine load fluctuations.

    After that, as shown in FIG. 16, when all the heat pump chillers (D1 to D8) are operated at the efficiency% load, the family control unit (12) operates the second group (Gr2) having a high priority at the high load. Control to do. The second group control unit (14) switches the heat pump chiller (D6) having higher priority to 100% load operation, and when the heat pump chiller (D6) reaches 100% load, the heat pump chiller (D5) Switch to 100% load operation.

    Subsequently, the family control unit (12) starts operation in the order of the first group (Gr1) and the third group (Gr3) having the highest priority. At this time, in each group (Gr1, Gr3), switch the heat pump chiller with the highest priority in the group to 100% load operation, and when this heat pump chiller reaches 100% load, the heat pump with the next highest priority The operation is switched to 100% load operation in order from the chiller (see FIG. 17). By doing so, as shown in FIG. 18, it is possible to follow fine load fluctuations.

-Effect of Embodiment 3-
According to the said Embodiment 3, since the family control part (12) performed rotation control, the group made to drive | work based on the total operation time for every group (Gr1-Gr3) can be determined. For this reason, the total operation time of each group (Gr1-Gr3) can be equalized. Therefore, since it is possible to prevent the specific group (Gr1 to Gr3) from operating at all times, it is possible to extend the entire life of the chiller control system (10).

    In addition, in each group (Gr1 to Gr3), priority is given to the operation at the efficiency% load of the heat pump chillers (D1 to D4, D5, D6, D7, D8) in the group, so that the operation with power saving can be performed. .

    As a result, as a whole chiller control system (10), it is possible to realize an operation with energy saving while extending the life.

    Moreover, since efficiency control is performed in each group (Gr1 to Gr3), the heat pump chiller (D1 to G1 to Gr3) is operated based on the total operation time for each heat pump chiller (D1 to D8) in each group (Gr1 to Gr3). D8) can be determined. Thereby, the total operation time of the heat pump chillers (D1 to D8) of each group (Gr1 to Gr3) can be leveled. In addition, since the heat pump chillers (D1 to D4, D5, D6, D7, and D8) in each group (Gr1 to Gr3) are activated in order, it is possible to improve followability with respect to fine load fluctuations.

    Moreover, since each group (Gr1 to Gr3) has a plurality of heat pump chillers (D1 to D4, D5, D6, D7, D8), a plurality of heat pump chillers (D1 to D4, D5, D6, D7, D8) ) For each group (Gr1 to Gr3) having. For this reason, a large number of heat pump chillers (D1 to D4, D5, D6, D7, D8) can be controlled with a simple configuration.

    Here, the conventional chiller device (a) may be installed in a property mainly composed of a single room air conditioner such as a hospital or a dormitory. In the case of such an article, the cooling or heating load at the start-up of the chiller device (a) increases stepwise, and after the start-up, the fluctuation is small, but a long-time operation is required. . For this reason, in the chiller device (a), the outdoor unit (b) in each group (c, d, e) is started with priority given to the one with a short operating time, so that it can follow the fine load fluctuations. It had been. However, in the chiller device (a), since the outdoor unit (b) operating in each group (c, d, e) operates at 100% load, the operation becomes inefficient and power consumption increases. (FIG. 25). That is, as a whole chiller device (a), there is a problem that it is impossible to realize an operation with energy saving while ensuring followability to a fine load fluctuation.

    The chiller control system (10) according to the third embodiment is suitable for such a property because it can improve followability with respect to fine load fluctuations and can be operated with energy saving. Other forms, operations and effects are the same as those in the first embodiment.

<Embodiment 4 of the Invention>
Next, a fourth embodiment of the present invention will be described. The chiller control system (10) according to the fourth embodiment is different from that according to the first to third embodiments in the configuration of the group control units (13 to 15) of the controller (11).

    FIG. 1 shows a chiller control system (10) according to Embodiment 1 of the present invention. The chiller control system (10) includes a controller (11) that controls the operation of the first to third groups (Gr1 to Gr3) each having a plurality of heat pump chillers (D1 to D8) and the heat pump chillers (D1 to D8). ).

    The heat pump chillers (D1 to D8) are installed on the roof of a building or the like for cooling or heating water for air conditioning supplied into the building, and constitute the chiller according to the present invention. Yes. The heat pump chillers (D1 to D8) include a casing having a heat exchanger and a blower fan, and are configured to blow out the air taken into the casing through the heat exchanger to the outside of the casing by the blower fan. . The air taken in the casing is heat-exchanged when passing through the heat exchanger.

    The first group (Gr1) is composed of four heat pump chillers (D1 to D4), the second group (Gr2) is composed of two heat pump chillers (D5, D6), and the third group (Gr3 ) Is composed of two heat pump chillers (D7, D8). The heat pump chillers (D1 to D8) are connected to the same water pipe (16). The temperature load of air conditioning water flowing through the water pipe (16) refers to the load according to the present embodiment and the present invention. Each of the groups (Gr1 to Gr3) constitutes a control unit according to the present invention.

    The controller (11) includes a first group controller (13) that controls the first group (Gr1), a second group controller (14) that controls the second group (Gr2), and a third group (Gr3 ) And a family control unit (12) that controls the first to third groups (Gr1 to Gr3) in an integrated manner.

    Each group control part (13-15) performs group control with respect to the heat pump chillers (D1-D8) of each corresponding group (Gr1-Gr3), as shown in FIG. The unit control part which concerns on this is comprised. Specifically, the first group controller (13) is connected to the first group (Gr1), the second group controller (14) is connected to the second group (Gr2), and the third group controller (15) is connected to the third group (Gr3). This group control is set in advance, for example, at the time of installation of the heat pump chillers (D1 to D8) according to the user's request.

    The first group control unit (13) performs simultaneous control as group control on the first group (Gr1), and constitutes a first unit control unit according to the present invention. Specifically, in the simultaneous control in the first group (Gr1), when the first group control unit (13) receives the operation signal, the four heat pump chillers (D1 to D4) constituting the first group (Gr1). The operation command at 100% load is issued to all of the above. On the other hand, when the first group control unit (13) receives the operation stop signal, it stops all the heat pump chillers (D1 to D4).

    The second group control unit (14) operates each heat pump chiller (D5, D6) so that the total operation time of each of the two heat pump chillers (D5, D6) in the second group (Gr2) is leveled. The second unit control unit according to the present invention is configured. Specifically, in the second group control unit (14), when an operation signal is received, a higher priority order is determined in the order of heat pump chillers with less total operation time within the group. And a 2nd group control part (14) starts an operation | movement in an order from the heat pump chiller with the highest priority (namely, heat pump chiller with the shortest total operation time). When the operation starts and the heat pump chiller that controls the water temperature reaches a predetermined load, the operation of the heat pump chiller with the next highest priority is started. For this reason, in the rotation control, the total operation time for each heat pump chiller (D5, D6) in the group is less varied.

    In this rotation control, the heat pump chiller having the lowest priority among the operating heat pump chillers (D5, D6) (that is, the heat pump chiller with a long total operation time) performs fine adjustment of the water temperature. And when load falls, a driving | operation is stopped in order with a low priority. When receiving the stop signal, the second group control unit (14) stops all the heat pump chillers (D5, D6) in the group at the same time.

    In the second group (Gr2), as shown in FIG. 21, the heat pump chiller (D6) (310 hours) and the heat pump chiller (D5) (340 hours) are in order of priority.

    In the second group control unit (14), when 24 hours have elapsed, the priority order of the heat pump chiller with the first priority is changed to the last priority, and the heat pump chillers with the second or lower priority are repeated one by one. Go up. In other words, the operation time is leveled by changing the priority order every 24 hours.

    In the second group control unit (14), the priority order is determined not in the total operation time of each heat pump chiller (D5, D6) but in the order of the number of start / stop times of each heat pump chiller (D5, D6). Also good. In this case, since the activation does not concentrate on a specific heat pump chiller, the number of times of starting / stopping each heat pump chiller (D5, D6) can be leveled.

    The third group control unit (15) operates each heat pump chiller (D7, D8) so as to level the total operation time for each of the two heat pump chillers (D7, D8) in the third group (Gr3). The second unit control unit according to the present invention is configured. Since the specific control content is the same as that of the second group (Gr2), description thereof is omitted.

    The family control unit (12) performs family control on the first to third group control units (13 to 15), and constitutes an overall control unit according to the present invention. This family control is set in advance, for example, at the time of installation of each heat pump chiller (D1 to D8) according to the user's request.

    This family control part (12) performs rotation control as family control with respect to each of the first to third group control parts (13 to 15). That is, the first group (Gr1 to Gr3) constitutes one family. In the rotation control of the family control unit (12), the operation of each group (Gr1 to Gr3) in the family is controlled so as to equalize the total operation time for each group (Gr1 to Gr3). This total operation time constitutes the operation time according to the present invention. Specifically, when receiving an operation signal, the family control unit (12) determines a higher priority in the order of the group with the shortest total operation time within the family to be controlled. And a family control part (12) starts a driving | operation in order from the group (namely, group with the shortest total operation time) with the highest priority. And when the group which starts operation and performs water temperature control reaches 100% load, the operation of the group with the next highest priority is started. For this reason, in the rotation control, variations in the total operation time for each group (Gr1 to Gr3) are reduced.

    Further, in this rotation control, the group having the lowest priority among the groups in operation (that is, the group having a long total operation time) performs control for fine adjustment of the water temperature. In the fourth embodiment, as shown in FIG. 21, it is assumed that the priority order is higher in the order of the second group (Gr2) and the third group (Gr3).

    In the family control unit (12), after 24 hours of continuous operation, the priority of the group with the first priority is changed to the last priority, and the groups with the second or lower priority are moved up one by one. In other words, the operation time is leveled by changing the priority order every 24 hours.

    In the family control unit (12), the priority order may be determined in ascending order of the average value of the number of times of start / stop of each group (Gr1 to Gr3), not the total operation time of each group (Gr1 to Gr3). Good.

-Driving action-
Next, operation control of the chiller control system (10) according to the fourth embodiment will be described. In the chiller control system (10), as shown in FIG. 20, first, the family control unit (12) preferentially starts the operation of the first group (Gr1) in which simultaneous control is performed within the group. In the first group (Gr1), the four heat pump chillers (D1 to D4) in the group are activated at 100% load at the same time. By starting all heat pump chillers (D1 to D4) at 100% load at the same time, it follows the sudden load increase (400%) when the chiller control system (10) is started, as shown in FIG. can do.

    Next, as shown in FIG. 21, the family control unit (12) starts the operation of the second group (Gr2) with a short total operation time. In the second group (Gr2), of the two heat pump chillers (D5, D6) in the group, start the operation of the heat pump chiller (D6) with a short total operation time. Start chiller (D5) operation. By doing so, as shown in FIG. 23, it is possible to follow fine load fluctuations.

    Thereafter, the family control unit (12) starts the operation of the third group (Gr3) having a long total operation time. In the third group (Gr3), among the two heat pump chillers (D7, D8) in the group, the operation is started in order from the heat pump chiller having a short total operation time. By doing so, as shown in FIG. 23, it is possible to follow fine load fluctuations. Finally, as shown in FIG. 22, all the heat pump chillers (D1 to D8) are operated at 100% load.

-Effect of Embodiment 4-
According to the said Embodiment 4, since the family control part (12) performed rotation control, the group made to drive | work based on the total operation time for every group (Gr1-Gr3) can be determined. Thereby, the total operation time of each group (Gr1-Gr3) can be equalized. For this reason, since it can prevent that a specific group (Gr1-Gr3) always works, the lifetime improvement of the whole chiller control system (10) can be aimed at.

    In addition, since the second and third group control units (14, 15) perform rotation control, each heat pump chiller (D5, D6, D7, D8) in the second and third groups (Gr2, Gr3) The heat pump chiller (D5, D6, D7, D8) to be operated can be determined based on the total operation time. Thereby, the total operation time of the heat pump chillers (D5, D6, D7, D8) of the second and third groups (Gr2, Gr3) can be leveled. In addition, since the heat pump chillers (D5, D6, D7, D8) of the second and third groups (Gr2, Gr3) are operated in order, it is possible to improve followability to fine load fluctuations.

    Furthermore, since the heat pump chillers (D1 to D4) corresponding to the first group (Gr1) are operated at the same time, it is possible to improve the followability to a sudden load fluctuation.

    As a result, the chiller control system (10) as a whole can maintain follow-up to sudden load fluctuations at start-up, maintain follow-up to fine load fluctuations after start-up, and extend the service life. it can.

    Here, the conventional chiller device (a) may be installed in a property mainly composed of a single room air conditioner such as an office. In the case of such a property, the start time of the chiller device (a) is substantially constant and the load fluctuation after the start is small. For this reason, in the conventional chiller device (a), the outdoor unit (b) in the group (c, d, e) is started with priority given to the one having a short operating time, so that the group (c, d, e) The operation time of each outdoor unit (b) is leveled, and small load fluctuations are dealt with.

    However, the chiller device (a) cannot follow a rapid load fluctuation at the time of startup.

    On the other hand, the chiller control system (10) according to the fourth embodiment can improve the followability to both fine load fluctuations and sudden load fluctuations, and can extend the service life. Suitable for Other forms, operations and effects are the same as those in the first embodiment.

<Other embodiments>
This invention is good also as following structures about the said Embodiment 1-4. The number and grouping of the heat pump chillers in the chiller control systems (10) according to the first to fourth embodiments are examples, and are not limited thereto.

    In the first to fourth embodiments, the heat pump chillers (D1 to D8) are used as the chillers according to the present invention. However, the present invention is not limited to this, and can be applied to various types of chillers.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a plurality of heat pump chiller control means.

10 chiller control system 11 controller 12 family control unit 13 first group control unit 14 second group control unit 15 third group control units D1 to D8 heat pump chiller Gr1 first group Gr2 second group Gr3 third group

Claims (6)

A plurality of control units (Gr1 to Gr3) each having at least one chiller (D1 to D4, D5, D6, D7, D8) and the chillers (D1 to D4) corresponding to each control unit (Gr1 to Gr3) , D5, D6, D7, D8) and a unit control unit (13-15) for controlling the chiller control system,
While having a general control unit (12) for preferentially operating one control unit having a shorter operation time than other control units among the plurality of control units (Gr1 to Gr3) corresponding to one load,
The unit control unit (13 to 15) is configured to control the chillers (D1 to D4, D5, D6, D7, and D8) of the control unit (Gr1 to Gr3) operated by the overall control unit (12). The chiller control system characterized by being. In claim 1,
Each of the control units (Gr1 to Gr3) has a plurality of the chillers (D1 to D4, D5, D6, D7, and D8), respectively. In claim 2,
The unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) include a plurality of corresponding chillers (D1 to D4, D5, D6, D7, D8). ) Is operated at the same time. In claim 2,
The unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) have a plurality of corresponding chillers (D1 to D4, D5, D6, D7, D8). Among them, a chiller control system is configured such that one chiller having a shorter operation time than other chillers is operated with priority. In claim 1 or 2,
The unit control units (13 to 15) corresponding to the control units (Gr1 to Gr3) operated by the overall control unit (12) are connected to the corresponding chillers (D1 to D4, D5, D6, D7, D8). A chiller control system configured to limit operation to a predetermined load or less. In claim 2,
The unit control unit (13 to 15) includes a first unit control unit (13) that simultaneously operates a plurality of chillers (D1 to D4) of the control unit (Gr1) operated by the overall control unit (12).
Priority is given to one chiller with less operating time than other chillers among the multiple chillers (D5, D6, D7, D8) of the control unit (Gr2, Gr3) operated by the general control unit (12) A chiller control system comprising a second unit controller (14, 15) to be operated.

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