JP5241071B2 - Refrigeration air conditioner - Google Patents

Description

The present invention relates to a refrigeration air conditioner applied to a refrigerator or an air conditioner, and more particularly to control of a refrigeration air conditioner having a plurality of heat source side units in the same refrigerant circuit.

  Conventionally, an air conditioner having a plurality of outdoor units (heat source side units) includes a main outdoor unit that performs communication and control with an indoor unit (use side unit), and a sub outdoor unit that outputs in response to a command from the main outdoor unit. It was generally composed of The main outdoor unit and the sub outdoor unit may be the same unit as the case where they are different units, but in the case of the same unit, the main outdoor unit / sub outdoor unit is determined by function setting such as switch setting, The function was switched (for example, refer to Patent Document 1). There is also a method of detecting a difference in transmission line connection method, determining a main outdoor unit / sub outdoor unit, and switching functions. Alternatively, in an air conditioner having a plurality of outdoor units, one outdoor unit of a certain refrigerant circuit system is connected to an outdoor unit controller and a centralized management controller of another refrigerant circuit system via a switch. there were.

JP 2000-18684 A

The conventional air conditioner having a plurality of outdoor units is configured as described above, and the sub outdoor unit receives and outputs a command from the main outdoor unit. In addition, in order for the sub outdoor unit to perform communication and control with the indoor unit as an emergency operation when the main outdoor unit fails, it is necessary to receive information on the indoor unit from the main outdoor unit. For this reason, there has been a problem that normal operation cannot be performed when there is no main outdoor unit or when there are a plurality of main outdoor units due to erroneous setting of the function settings.
Also, if the main outdoor unit has to be turned on when it cannot be turned on due to failure, parts replacement, blown fuse, etc., change the function settings of the other outdoor units to change the main outdoor unit to the main outdoor unit. There was a problem that it could not be operated normally unless it was set. In such an emergency operation, if the transmission line connected to the outdoor unit controller and the central control controller of another refrigerant circuit system is not changed to the newly set main outdoor unit, the central control unit There was a problem that data could not be sent to and received from the controller.
Also, even when the power is turned on normally, if the timing of powering on each outdoor unit deviates, the system will not start up properly if the outdoor unit that is powered on later is not recognized by other outdoor units. There's a problem. In order to prevent this, each outdoor unit has a power receiving circuit for the microcomputer power supply, and there is a method in which power is supplied to the microcomputer by receiving power from other units even when the power-on is delayed. There was a problem of cost increase by addition.

The present invention has been made to solve the above-described problems. A first object of the present invention is to switch the switching between a main heat source side unit and a sub heat source side unit in a refrigeration air conditioner having a plurality of heat source side units. The setting can be automatically changed regardless of the setting and the transmission line connection method.
The second object is to enable operation without changing the function setting if at least one heat source side unit is normal when the heat source side unit fails or when maintenance is performed.
The third purpose is to allow data transmission / reception to / from the centralized controller without changing the transmission line connection if at least one heat source unit is normal when the heat source unit fails or when maintenance is performed. It is to do.
The fourth object is that a refrigeration air conditioner having a plurality of heat source side units does not require a power receiving circuit in the heat source side units, and even when there is a delay in power-on of some heat source side units. It is possible to drive.

In order to achieve the above object, a refrigerating and air-conditioning apparatus according to the present invention includes a use side unit and a plurality of heat source side units in the same refrigerant circuit, and the plurality of heat source side units controls operation of the use side unit. In the refrigerating and air-conditioning apparatus set to be switchable between one main heat source side unit and the sub heat source side unit which is the remaining heat source side unit and is controlled by a command from the main heat source side unit, The side unit relates the unit address data set in each heat source side unit and the data related to the unit air conditioning capacity of each heat source side unit based on the communication with the other heat source side unit to the main heat source side unit selection. Priority data detecting means for detecting as priority data, and priority data detected by the priority data detecting means Zui and, a main heat source unit selecting means for selecting the main heat source unit from among the plurality of heat-source side unit, the main heat source unit selecting means, said unit air-conditioning capacity is largest the heat source side unit Is selected as the main heat source side unit .

Further, in the configuration of claim 1, the main heat source unit selecting means determines that said unit air-conditioning capacity is a plurality of largest the heat source side unit, from among the unit air conditioning capacity is largest multiple heat source unit The heat source side unit having a small unit address is selected as the main heat source side unit.

In each arrangement described above, home to the user side unit in the same refrigerant circuit and a plurality of heat source unit, and connects the heat source unit in which all of the plurality of heat-source-side unit and the other refrigerant circuit Yosuru a transmission line It is characterized by this.

In each arrangement described above, the heat source side unit, based on whether the communication is established, the same further normal judgment means for judging the normality of the heat source side unit in the refrigerant circuit wherein the normality determination unit If there is a heat source unit that is not determined to be normal, the main heat source unit selecting means, which is characterized in that selecting the main heat source unit from the heat source unit is judged to be normal by the normality determination unit It is.

In each of the above-described configurations, each heat source side unit detects a power-on detection unit that detects power-on of another heat-source side unit, and a delay in power-on of a certain heat-source side unit is detected by the power-input detection unit. when, characterized in that the priority data detecting unit and exert the main heat source unit selecting means, further comprising a re-selection means for re-selecting the main heat source unit from all of the heat source side unit having detected the power-on It is what.

According to this invention, in the refrigerating and air-conditioning apparatus having the use side unit and the plurality of heat source side units, the switching setting of the main heat source side unit and the sub heat source side unit can be automatically performed without using the switch setting or the transmission line connection method. Can be done automatically.

Embodiments 1-3.
Embodiments of the present invention will be described below. 1 shows the configuration of a refrigeration air conditioner according to Embodiment 1 of the present invention, FIG. 2 shows the configuration of the refrigeration air conditioner according to Embodiment 2 of the present invention, and FIG. 3 shows the refrigeration according to Embodiment 3 of the present invention. The structure of the air conditioner is shown.
In the refrigerating and air-conditioning apparatus shown in FIG. 1, a plurality of outdoor units (heat source side units) A1, A2, A3 and a plurality of indoor units (use side units) B1, B2, B3 are connected by a refrigerant pipe 1 to form one refrigerant. A circuit system (same refrigerant circuit) is configured. The outdoor units A1, A2, and A3 are controlled by the outdoor unit controllers a1, a2, and a3, and the indoor units B1, B2, and B3 are controlled by the indoor unit controllers b1, b2, and b3. The outdoor unit controllers a1, a2, a3 and the indoor unit controllers b1, b2, b3 are directly connected to each other via transmission lines 2-6 so as to be able to transmit information. The outdoor unit controllers a1, a2, and a3 are connected to the outdoor unit controller of the other refrigerant circuit system and the centralized management controller C1 through the transmission lines 7 to 10 via the switches 11 to 13 so as to be intermittent.

In the refrigerating and air-conditioning apparatus shown in FIG. 2, the outdoor units A1 and A2 and the indoor units B1 and B2 are connected by a refrigerant pipe 1 to constitute one refrigerant circuit system. The outdoor unit A3 and the indoor unit B3 are connected by a refrigerant pipe 14 to constitute another refrigerant circuit system. The plurality of outdoor unit controllers a1 and a2 and the indoor unit controllers b1 and b2 are directly connected to each other via transmission lines 2 to 4, and the outdoor unit controller a3 and the indoor unit controller b3 are directly connected via the transmission line 5. Yes. Further, the plurality of outdoor unit controllers a1 and a2 are connected to the outdoor unit controller a3 and the centralized management controller C1 of other refrigerant circuit systems via the transmission lines 7 to 10 via the switches 11 to 13 so as to be intermittent.

In the refrigerating and air-conditioning apparatus shown in FIG. 3, the outdoor unit A1 and the indoor unit B1 are connected by a refrigerant pipe 1 to constitute one refrigerant circuit system. The outdoor units A2 and A3 and the indoor units B2 and B3 are connected by a refrigerant pipe 14 to constitute another refrigerant circuit system. The outdoor unit controller a1 and the indoor unit controller b1 are directly connected to each other via a transmission line 2, and a plurality of outdoor unit controllers a2, a3 and the indoor unit controllers b2, b3 are directly connected by transmission lines 3-5. Yes. The plurality of outdoor unit controllers a2 and a3 are connected to the outdoor unit controller a1 of the other refrigerant circuit system and the centralized management controller C1 through the transmission lines 7 to 10 via the switches 11 to 13 so as to be intermittent.

As shown in FIG. 4, the outdoor unit controllers a1, a2, and a3 of the outdoor units A1, A2, and A3 store a control unit 15 realized by an MPU or the like, and setting data, detection data, performance data, program data, and the like. Connected to the transmission lines 7, 8, 9, 10 connected to the storage unit 16 and the outdoor unit controllers a1, a2, a3 of the other outdoor units or the centralized controller C1 via the switches 11, 12, 13. Unit 17 and communication unit 18 connected to transmission lines 2, 3, 4, and 5 directly connected to an outdoor unit controller of another outdoor unit or an indoor unit controller of an indoor unit.

As will be described later, the control unit 15 includes an operation control unit 19, a priority order data detection unit 20, a main heat source side unit selection unit 21, a normality determination unit 22, a data transmission / reception unit 23, an incoming detection unit 24, and a reselection. Each function of the means 25 is provided. Each function of these means 19 to 25 is executed by a processing procedure of a program set in the control unit 15. The storage unit 16 includes a ROM, a RAM, and the like, and stores priority order data related to selection of a main outdoor unit described later.

FIG. 5 is a flowchart showing a control operation related to the switches 11 to 13 of the outdoor units A1, A2 and A3 according to the first to third embodiments. The operation of the refrigerating and air-conditioning apparatus configured as described above will be described. In FIG. 5, each control unit 15 of the outdoor unit controllers a1, a2, and a3 in the outdoor units A1, A2, and A3 performs an initial process when the power is turned on, and then proceeds to step S31. In step S31, the switches 11, 12, and 13 are turned OFF, and the process proceeds to step S32. This is because the system startup processing of the self refrigerant circuit system is first performed in the switch OFF state. In the system start-up process, the control unit 15 performs a unit search process by transmitting a communication command, and grasps outdoor units and indoor units that exist in the refrigerant circuit system based on whether or not there is a response.
For example, in the refrigerating and air-conditioning apparatus of FIG. 2, when the outdoor units A1 to A3 and the indoor units B1 to B3 are turned on at the same time, the switches 11 to 13 are all OFF, so the outdoor unit controller a1 of the outdoor unit A1 It can be understood that the outdoor unit A2 and the indoor units B1 and B2 exist in the refrigerant circuit system.

In step S32, the control unit 15 determines whether the system start-up process has been completed. If the system startup has been completed, the process proceeds to step S33. If the system startup has not been completed, the process proceeds to step S38. In step S33, the control unit 15 determines whether or not itself (the outdoor unit) is the main outdoor unit. If it is a main outdoor unit, the process proceeds to step S34, and if it is a sub outdoor unit, the process proceeds to step S38. In step S38, the process returns to step S32 while the switches 11, 12, and 13 are kept in the OFF state.
With these processes, the system startup is completed, and only the outdoor unit that is the main outdoor unit turns on the switch (steps S34 to S37 described in detail later), and thereafter, all the outdoor units and the centralized management controller Data transmission / reception with C1 becomes possible. That is, the function of the normality determination means 22 of the control unit 15 determines the normality of the outdoor units A1, A2, A3. The function of the data transmission / reception means 23 causes the communication unit 17 to perform data transmission / reception between the outdoor unit determined to be normal and the central control controller C1.

However, with only the above-described determination, there is a problem that the system startup is not completed normally when the power of some outdoor units is turned on later.
For example, in the refrigeration air conditioner of FIG. 2, when only the outdoor unit A2 is turned off and all other outdoor units are turned on, the outdoor unit controller a1 of the outdoor unit A1 has the indoor unit B1, It is determined that only B2 exists, the system startup is completed, and the switch 11 is turned on. The outdoor unit controller a3 of the outdoor unit A3 determines that the indoor unit B3 exists, and turns on the switch 13 after the system startup is completed. When the power of the outdoor unit A2 is turned on in this state, communication with the outdoor unit controller a3 and the indoor unit controller b3 is established through the paths of the transmission lines 2, 8, 9, and 5 even when the switch 12 is turned off. Therefore, the outdoor unit controller a2 determines that the outdoor units A1, A3 and the indoor units B1, B2, B3 are present in the own refrigerant circuit system.

For example, in the refrigeration and air-conditioning apparatus of FIG. 3, the outdoor units A1 and A3 are also started up when all the outdoor units A1 and A3 are turned on with only the outdoor unit A2 turned off. When the power to the outdoor unit A2 is turned on after the completion, the communication is established through the transmission lines 3, 9, 8, and 2, so that the outdoor unit controller a2 has the outdoor units A1, A3 and the indoor units B1, B2, B3. It will be determined that it exists in its own refrigerant circuit system.

As described above, in the refrigerating and air-conditioning apparatus of FIGS. 2 and 3, it is determined that the system is a single refrigerant circuit system even though the system includes a plurality of refrigerant circuit systems, or different systems. There arises a problem that they are judged as if they are the same system.

As a countermeasure against such a problem, the control unit 15 of the outdoor unit controller of a certain outdoor unit not only turns off the switch but also sends a communication command (OFF request) to other outdoor units before the system start-up process. The switch is turned off by sending a command. This command reception process is step S34 to step S37 in FIG.
In step S34, a switch OFF request reception determination process is performed. If the switch OFF request has been received, the timer T is cleared to 0 in step S35, and then the process proceeds to step S36. If the switch OFF request has not been received, the process proceeds directly to step S36.
In step S36, the value of timer T is compared with the switch OFF time. When the value of the timer T is equal to or shorter than the switch OFF time, the process proceeds to step S38. When the value of the timer T becomes larger than the switch OFF time, the process proceeds to step S37. In step S37, the switch is turned on and the process returns to step S32.
Note that the switch OFF time is sufficiently longer than the time required for a certain outdoor unit controller to search for another outdoor unit existing in the own refrigerant circuit system or another refrigerant circuit system, and each outdoor unit controller Is set to a time sufficiently shorter than the time for detecting an abnormality due to the communication interruption with the centralized controller C1.

For example, in the refrigerating and air-conditioning apparatus of FIG. 2, only the power of the outdoor unit A2 is turned off and all other units are turned on. After the outdoor units A1 and A3 complete the system startup, the power of the outdoor unit A2 is turned on. When the power is turned on, the outdoor unit controller a2 determines that the outdoor units A1 and A3 exist in the own refrigerant circuit system or the other refrigerant circuit system through the paths of the transmission lines 2, 8, 9, and 5. Here, when the outdoor unit controller a2 transmits a switch OFF request to the outdoor unit controllers a1 and a3, the outdoor unit controllers a1 and a3 turn off the switches 11 and 13.
Thereafter, the outdoor unit controller a2 searches for the unit again. Then, since communication with the outdoor unit A3 and the indoor unit B3 is not established, the outdoor unit controller a2 can grasp that only the outdoor unit A1 and the indoor units B1 and B2 exist in the refrigerant circuit system.

For example, in the refrigerating and air-conditioning apparatus of FIG. 3, only the outdoor unit A2 is turned off and all other outdoor units A1 and A3 are turned on, and the outdoor units A1 and A3 complete the system startup. Turn on the power of the unit A2. Then, the outdoor unit controller a2 determines that the outdoor units A1 and A3 exist in the own refrigerant circuit system or the other refrigerant circuit system through the paths of the transmission lines 3, 9, 8, and 2. Here, when the outdoor unit controller a2 transmits a switch OFF request to the outdoor unit controllers a1 and a3, the outdoor unit controllers a1 and a3 turn off the switches 11 and 13.
Thereafter, when the outdoor unit controller a2 searches for the unit again, communication with the outdoor unit controller a1 and the indoor unit controller b1 is not established. Therefore, the outdoor unit controller a2 includes the outdoor unit A3 and the indoor units B2 and B3 in its refrigerant circuit system. You can know that it exists.

  That is, in the refrigeration and air-conditioning apparatus of FIGS. 2 and 3, the function of the incoming power detection means 24 of the outdoor unit controllers a1, a2, and a3 detects the power-on of each outdoor unit and detects the delay in power-on of a certain outdoor unit. Then, the function of the reselection means 25 of the control unit 15 causes the priority order data detection means 20 and the main heat source side unit selection means 21 to work and reselects the main outdoor unit from all the outdoor units that are turned on.

FIG. 6 is a flowchart showing the control operation of the outdoor units according to the first to third embodiments. In FIG. 6, the outdoor unit controllers a1, a2, and a3 of the outdoor units A1, A2, and A3 perform initial processing when the power is turned on, and then proceed to step S1. In step S1, another outdoor unit existing in the own refrigerant circuit system or the other refrigerant circuit system is searched by transmitting a communication command, and the outdoor unit and its unit address existing by receiving a response command are grasped. Thereafter, after transmitting a switch OFF request to the existing outdoor unit, the outdoor unit is searched again by transmitting a communication command, and the outdoor unit existing in the own refrigerant circuit system and its unit address are grasped. In addition, information on the function, capability, etc. of each outdoor unit is grasped by communication if necessary. After the search is completed, the process proceeds to step S2.
In step S2, the outdoor unit controllers a1, a2, and a3 of the outdoor units A1, A2, and A3 each have a unit address of another outdoor unit that exists in its own refrigerant circuit system, and its own unit address set in advance. Set the unit number by comparing. This unit number is priority order data related to selection of the main outdoor unit (main heat source side unit). The unit number setting method is, for example, a method of setting serial numbers from 1 in ascending order of addresses among the existing outdoor units. After completing the setting of the unit number, the process proceeds to step S3.

For example, in the refrigerating and air-conditioning apparatus of FIG. 1, when the unit address of the outdoor unit A1 is set the youngest and then the address of the outdoor unit A2 is set to the youngest, the unit numbers of the outdoor units A1, A2, and A3 are 1, 2, respectively. The value is 3.
Here, the priority order data held by each outdoor unit is set by comparing unit addresses, but other methods for setting priority order data include comparing unit functions, comparing unit capabilities, or these. There is a method based on a combination of the above.

  In the case of the determination based on the comparison of the unit addresses described above, there is an effect that the main outdoor unit can be determined without using a new setting by using the unit address set manually or automatically for the determination. Further, when the unit address is manually set, there is an effect that any one unit can be selected at the same time to be a main outdoor unit.

In the case of setting by comparison of unit functions, for example, the outdoor units existing in the same refrigerant circuit system are set in order from 1 in order of the highest function, and in the case of similar functions, the unit addresses are assigned in ascending order. It is a method of setting with. Here, the high function means that, for example, external signal input / output is possible and a harmonic countermeasure device is provided.
Regarding the external signal input / output, since the output of the driving state and the input of the driving operation signal are performed, the information needs to be managed by the main outdoor unit. Therefore, when the outdoor unit capable of external signal input / output is a main outdoor unit, there is an effect that smooth control can be realized without causing a delay in information transmission between the main outdoor unit and the sub outdoor unit. can get.
As for harmonic countermeasure devices, harmonic countermeasure machines are often connected only to some of the outdoor units, but it is most effective when connected to the outdoor unit that operates the most. is there. Therefore, when the outdoor unit connected to the harmonic countermeasure device is the main outdoor unit, a high effect of harmonic countermeasures can be obtained.

On the other hand, in the case of determination by comparison of unit capabilities, for example, the existing outdoor units are set in order from 1 in order of increasing air conditioning capability, and in the case of the same capability, the unit addresses are set in ascending order. is there.
In general, outdoor units with higher capacity are equipped with more solenoid valves, expansion valves, sensors, etc., so when an outdoor unit with higher capacity becomes a sub outdoor unit, a large amount of control data is transferred to the main outdoor unit. You will have to send to and receive from. Therefore, when the outdoor unit having the largest capacity is used as the main outdoor unit, there is an effect that smooth control can be realized without causing a delay in information transmission between the main outdoor unit and the sub outdoor unit.

  In step S3, the main outdoor unit / sub outdoor unit is determined based on the unit number. The function of the priority order data detection means 20 of each control unit 15 in the outdoor unit controllers a1, a2, a3 is the unit number held by the storage unit 16 of the outdoor unit controllers a1, a2, a3 of each outdoor unit A1, A2, A3. (Priority data) is detected. Then, the function of the main heat source side unit selecting unit 21 of the control unit 15 selects the main outdoor unit from the plurality of outdoor units A1, A2, A3 based on the unit number detected by the priority order data detecting unit 21. For example, if an outdoor unit controller a1, a2, a3 has its own unit number 1, it determines that it is a main outdoor unit and proceeds to step S4. If the unit number is other than 1, it is determined that the unit is a sub outdoor unit, and the process proceeds to step S7. Taking the refrigeration air conditioner of FIG. 1 as an example, the outdoor unit A1 is set as the main outdoor unit, and the remaining outdoor units A2 and A3 are switched as sub-outdoor units whose operation is controlled by command signals from the outdoor unit controller a1. Set to be possible.

In step S4, the unit setting is transmitted to the outdoor unit controllers a2 and a3 of all the sub outdoor units A2 and A3 existing in the same refrigerant circuit system. The unit setting is a process for causing the sub outdoor unit controllers a2 and a3 to recognize that the main outdoor unit is A1 and to cooperate. After the transmission is completed, the process proceeds to step S5.
In step S5, the outdoor unit controller a1 performs control as the main outdoor unit. The control as the main outdoor unit includes communication with the indoor unit controllers b1, b2, and b3, control, output commands to the sub outdoor units A2 and A3, and the like. After the normal control is completed, the process proceeds to step S6.
In step S6, a unit setting request reception determination process is performed. If a unit setting request has not been received, the process returns to step S5 to execute main outdoor unit control. If a unit setting request has been received, the process returns to step S1, and outdoor unit search processing is executed. This is a restart process for recognizing an outdoor unit that is powered on later and starting a normal system.
On the other hand, in step S7, the outdoor units A2 and A3, which are sub outdoor units, transmit a unit setting request to the main outdoor unit A1. After the completion of the transmission process, the process proceeds to step S8.
In step S8, the outdoor unit controllers a2 and a3 of the outdoor units A2 and A3 perform control as sub outdoor units. The control as the sub outdoor unit is, for example, performing output in response to a command from the main outdoor unit controller a1. The sub outdoor unit controllers a2 and a3 do not perform communication and control with the indoor unit controllers b1, b2 and b3 of the indoor units B1, B2 and B3. Further, after the sub outdoor unit controllers a2 and a3 perform the normal control, the process proceeds to step S9 in order to perform the backup operation determination control in steps S9 to S11.

In step S9, the outdoor unit controllers a2 and a3 determine whether or not scheduled communication with the main outdoor unit controller a1 is established. If the scheduled communication with the main outdoor unit controller a1 is established, the process proceeds to step S10, and if the scheduled communication is not established, the process proceeds to step S11.
In step S10, the timer T is cleared to 0, and then the process proceeds to step S11.
In step S11, the outdoor unit controllers a2 and a3 compare the value of the timer T with the communication interruption determination time with the main outdoor unit controller a1. When the value of the timer T is equal to or shorter than the communication interruption determination time, the process returns to step S8 to perform control as a sub outdoor unit. When the value of the timer T becomes larger than the communication interruption determination time, it is determined that the main outdoor unit A1 has become unable to operate due to failure / power failure or the like, and the process proceeds to step S12 to issue an abnormal report. Then, it returns to step S1 and performs outdoor unit search. The communication interruption determination time is a time sufficiently longer than the regular communication interval, and is a function of the unit number. This is because when there are a plurality of sub outdoor units, the sub outdoor unit having the smallest unit number is selected as the next main outdoor unit.

In the refrigerating and air-conditioning apparatus of FIG. 1, when the main outdoor unit A1 becomes unable to communicate due to a failure, the outdoor unit controller a2 of the sub outdoor unit A2 with unit number 2 is connected to the sub outdoor unit A3 with unit number 3. The inability to operate the main outdoor unit A1 is detected earlier than the outdoor unit controller a3, and the process returns to step S1. Here, it is recognized that only the outdoor units A2 and A3 exist in the same refrigerant circuit system because the main outdoor unit A1 cannot communicate due to failure. Thereafter, the unit numbers of the outdoor units A2 and A3 are changed to values of 1 and 2 and stored in the storage unit 16 in step S2. Thereby, since the unit number of the outdoor unit controller a2 is 1 in step S3, the process proceeds to step S4 and transmits the unit setting to the outdoor unit controller a3, and then proceeds to step S5 to control as the main outdoor unit. I do. The sub outdoor unit controller a3 recognizes the outdoor unit A2 as the main outdoor unit by receiving a unit setting command from the outdoor unit A2 controller a2. Thereafter, by receiving a scheduled communication command from the outdoor unit controller a2, the outdoor unit controller a3 determines that the scheduled communication of the main outdoor unit is established in step S9, and continues the sub outdoor unit control. That is, the function of the normality determination means 22 of the control unit 15 determines the normality of the outdoor units A1, A2, A3, and sets the main outdoor unit from the outdoor units whose function of the main heat source side unit selection means 21 is determined to be normal. Then, the outdoor unit determined to be normal is operated by the function of the operation control means 19.

In the refrigerating and air-conditioning apparatus having a plurality of outdoor units configured as described above, switching between the main outdoor unit and the sub outdoor unit can be automatically executed regardless of the switch setting, the transmission line connection method, and the like. Further, when there is a normal outdoor unit at the time of failure or maintenance of the outdoor unit, it is possible to operate without changing the function setting.
When there is a delay in turning on the power of the outdoor unit that should originally be the sub-outdoor unit, the main outdoor unit starts up normally in a system that includes outdoor units other than the outdoor unit that should be the sub-outdoor unit. Although completed, by receiving a unit setting request from the outdoor unit controller of the outdoor unit whose power is turned on late, the normal startup of the system is completed by performing the restarting process.
Further, when the outdoor unit that should be the main outdoor unit is not turned on, one of the other normal outdoor units becomes the main outdoor unit, and the startup is completed normally and the operation becomes possible. Furthermore, when the outdoor unit that should be the main outdoor unit is turned on late, the outdoor unit that is currently the main outdoor unit performs the restarting process by receiving the unit setting request. The sub outdoor unit. At the same time, the outdoor unit that is turned on later becomes the main outdoor unit, and the normal startup of the system is completed by performing the restarting process.
Therefore, when there is a delay in power-on of some of the outdoor units, it is possible to operate normally even if the outdoor units do not have a power receiving circuit.

  In addition, when some of the outdoor units break down, it is possible to continue the operation with other outdoor units while notifying the outside of the occurrence of the problem by an abnormal alarm. Furthermore, even when repairs are taken by this notification, only the failed outdoor unit can be shut off and replacement of parts can be performed while continuing operation with other outdoor units. Thereafter, the outdoor unit that has been repaired is turned on to restore the normal system.

In the above description, the case where the present invention is used for an air conditioner has been described, but it goes without saying that the invention can also be used for a refrigerator having a plurality of heat source side units in the same refrigerant circuit.

It is a schematic block diagram which shows the refrigerating air conditioning apparatus in Embodiment 1 of this invention. It is a schematic block diagram which shows the refrigerating air conditioning apparatus in Embodiment 2 of this invention. It is a schematic block diagram which shows the refrigerating air conditioning apparatus in Embodiment 3 of this invention. It is a block diagram which shows the outline of the control structure of the outdoor unit controller in Embodiment 1,2,3 of this invention. It is a flowchart which shows the control action regarding the switch of the outdoor unit in Embodiment 1, 2, 3 of this invention. It is a flowchart which shows the control operation of the outdoor unit in Embodiment 1, 2, 3 of this invention.

Explanation of symbols

A1 outdoor unit (heat source side unit), A2 outdoor unit (heat source side unit), A3 outdoor unit (heat source side unit), B1 indoor unit (use side unit), B2 indoor unit (use side unit), B3 indoor unit (use) Side unit), C1 centralized controller, a1 outdoor unit controller, a2 outdoor unit controller, a3 outdoor unit controller, b1 indoor unit controller, b2 indoor unit controller, b3 indoor unit controller, 1 refrigerant piping, 2 transmission line, 3 transmission 4 transmission line 5 transmission line 6 transmission line 7 transmission line 8 transmission line 9 transmission line 10 transmission line 11 switch 12 switch 13 switch 14 refrigerant pipe 15 control unit 16 storage unit , 20 Priority data Detecting means, 21 main heat source side unit selecting means, 22 normal determination unit, 23 data communication means, 24 incoming call detection means, 25 re-selecting means.

Claims (4)

The same refrigerant circuit includes a use side unit and a plurality of heat source side units, and the plurality of heat source side units are one main heat source side unit that controls the operation of the use side unit and the remaining heat source side units. In the refrigerating and air-conditioning apparatus set to be switchable to the sub heat source side unit that is controlled by the command from the main heat source side unit,
Each heat source side unit
Based on communication with other heat source side units, unit address data set in each heat source side unit and data related to the unit air conditioning capability of each heat source side unit are used as priority data related to the main heat source side unit selection. Priority order data detection means for detecting;
A main heat source side unit selecting means for selecting the main heat source side unit from the plurality of heat source side units based on the priority order data detected by the priority order data detecting means ,
The main heat source side unit selecting means selects the heat source side unit having the largest unit air conditioning capability as the main heat source side unit . The main heat source unit selecting means, said unit when the air-conditioning capacity is determined to have more than the largest the heat source side unit, from among the largest plurality of heat source unit is the unit air conditioning capacity, the unit address small the heat source The refrigerating and air-conditioning apparatus according to claim 1, wherein a side unit is selected as the main heat source side unit. 2. The utilization side unit and the plurality of heat source side units are provided in the same refrigerant circuit, and all of the plurality of heat source side units are connected to the heat source side unit possessed by another refrigerant circuit by a transmission line. Or the refrigeration air conditioner of Claim 2. Each heat source side unit further includes normality determination means for determining normality of the heat source side unit in the same refrigerant circuit based on whether or not communication is established,
When there is a heat source side unit that the normality determining means has not determined to be normal, the main heat source side unit selecting means selects the main heat source side unit from the heat source side units determined to be normal by the normality determining means. The refrigeration air conditioner according to any one of claims 1 to 3, wherein

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