JP6943266B2 - Outdoor air conditioning system - Google Patents

Description

Outdoor air conditioner placed outdoors

Conventionally, there is an air conditioner that performs local cooling (air conditioning). As such an air conditioner, as shown in Patent Document 1 (Japanese Unexamined Patent Publication No. 2006-242510), a compressor, a condenser (heat source side heat exchanger), a condenser fan (heat source side fan), and evaporation are provided in a casing. Some have a device (utility side heat exchanger) and an evaporator fan (user side fan).

In the conventional air conditioner, an operation unit for issuing a command such as operation or stop is provided in the casing. An operator such as a user goes to the place where the air conditioner is arranged and operates the air conditioner.

Further, in recent years, the number of outdoor events has increased, and there is an increasing demand for arranging an air conditioner (outdoor air conditioner) at an outdoor event venue, a terrace seat of a restaurant, or the like. In response to such a demand, it is conceivable to arrange the conventional air conditioner outdoors as an outdoor air conditioner. If the outdoor space is large, it may be necessary to arrange multiple outdoor air conditioners outdoors.

However, when arranging a plurality of outdoor air conditioners in a large outdoor space, the operator needs to go to the respective arrangement locations of the plurality of outdoor air conditioners and operate each outdoor air conditioner. It takes time to operate the outdoor air conditioner.

The outdoor air conditioning system according to the first aspect includes a plurality of outdoor air conditioning devices arranged outdoors and one remote controller. Each outdoor air conditioner includes a casing, a compressor housed in the casing, a heat source side heat exchanger, a heat source side fan that creates an air flow through the heat source side heat exchanger, a utilization side heat exchanger, and utilization. It has a utilization side fan that creates an air flow through the side heat exchanger. The remote controller is communicably connected to a plurality of outdoor air conditioners to operate the plurality of outdoor air conditioners.

The outdoor air conditioning system according to the first aspect adopts a configuration in which a plurality of outdoor air conditioning devices are operated by one remote controller as described above. With this configuration, the operator can operate the plurality of outdoor air conditioners without going to the respective arrangement locations of the plurality of outdoor air conditioners, so that the time and effort for operating the outdoor air conditioners can be reduced. can.

In the outdoor air conditioning system according to the second aspect, in the outdoor air conditioning system according to the first aspect, a plurality of outdoor air conditioning devices are connected in series to the remote controller by a communication line.

In the outdoor air conditioning system according to the third aspect, in the outdoor air conditioning system according to the first aspect, a plurality of outdoor air conditioning devices are connected in parallel to the remote controller by a communication line.

The outdoor air conditioning system according to the second and third viewpoints adopts a configuration in which the remote controller and a plurality of outdoor air conditioning devices are connected by wire as described above. With this configuration, good communication can be performed even when, for example, an outdoor air conditioner located away from the remote controller exists (when it is disadvantageous for communication).

In the outdoor air conditioning system according to the fourth aspect, in the outdoor air conditioning system according to the first aspect, a plurality of outdoor air conditioning devices are wirelessly connected to the remote controller.

The outdoor air-conditioning system according to the fourth aspect adopts a configuration in which the remote controller and a plurality of outdoor air-conditioning devices are wirelessly connected as described above, thereby connecting the remote controller and the plurality of outdoor air-conditioning devices. You can eliminate the communication line to connect.

In the outdoor air conditioning system according to the fifth aspect, in the outdoor air conditioning system according to any one of the first to fourth aspects, the remote controller operates a plurality of outdoor air conditioning devices at once.

As described above, the outdoor air-conditioning system according to the fifth aspect adopts a configuration in which the remote controller operates a plurality of outdoor air-conditioning devices at once, so that all the outdoor air-conditioning devices are collectively operated or stopped. Etc. can be issued.

In the outdoor air conditioning system according to the sixth aspect, in the outdoor air conditioning system according to any one of the first to fourth aspects, the remote controller operates a plurality of outdoor air conditioning devices individually.

As described above, the outdoor air-conditioning system according to the sixth aspect adopts a configuration in which the remote controller individually operates a plurality of outdoor air-conditioning devices, so that each outdoor air-conditioning device is instructed to start or stop. It can be performed.

The outdoor air conditioning system according to the seventh aspect is the outdoor air conditioning system according to any one of the first to sixth aspects, wherein a light emitting portion is provided on the outer surface of the casing. The remote controller illuminates the light emitting part of the outdoor air conditioner to be operated among the plurality of outdoor air conditioners.

As described above, the outdoor air-conditioning system according to the seventh aspect adopts a configuration in which the light emitting portion of the outdoor air-conditioning device to be operated is illuminated, and after confirming the outdoor air-conditioning device to be operated, it is outdoors. Can operate the air conditioner.

In the outdoor air conditioning system according to the eighth aspect, in the outdoor air conditioning system according to the seventh aspect, the light emitting portion is arranged on the side surface of the outer surface of the casing.

As described above, the outdoor air conditioning system according to the eighth aspect can easily confirm the outdoor air conditioning device to be operated by adopting the configuration in which the light emitting portion is provided on the side surface of the casing.

The outdoor air conditioning system according to the ninth aspect is used in the outdoor air conditioning system according to any one of the first to sixth aspects, in which the air flow that has passed through the heat exchanger on the utilization side is blown out to the outside of the casing. A side outlet is formed. The user-side outlet is provided with a flap that changes the direction of the air flow blown out from the user-side outlet. The remote controller operates the flap of the outdoor air conditioner to be operated among the plurality of outdoor air conditioners.

The outdoor air-conditioning system according to the ninth aspect adopts a configuration in which the flap of the outdoor air-conditioning device to be operated is operated as described above, and after confirming the outdoor air-conditioning device to be operated, it is outdoors. Can operate the air conditioner.

In the outdoor air conditioning system according to the tenth aspect, the heat source side outlet and the utilization side outlet are formed in the casing in the outdoor air conditioning system according to any one of the first to sixth aspects. The heat source side outlet blows the air flow that has passed through the heat source side heat exchanger to the outside of the casing. The user-side outlet blows the air flow that has passed through the user-side heat exchanger to the outside of the casing. The remote controller operates the heat source side fan and / or the user side fan of the outdoor air conditioner to be operated among the plurality of outdoor air conditioners.

The outdoor air-conditioning system according to the tenth aspect adopts a configuration in which the fan of the outdoor air-conditioning device to be operated is operated as described above, and after confirming the outdoor air-conditioning device to be operated, it is outdoors. Can operate the air conditioner.

In the outdoor air conditioning system according to the eleventh aspect, the remote controller has a display unit in the outdoor air conditioning system according to any one of the first to tenth aspects. When an abnormality occurs in a plurality of outdoor air conditioners, the remote controller displays the abnormality information having the highest degree of severity of the abnormality on the display unit as the first abnormality information.

By adopting the above-mentioned abnormality information display configuration, the outdoor air-conditioning system according to the eleventh viewpoint can confirm the existence of the outdoor air-conditioning device in which a serious abnormality has occurred through the display unit of the remote controller. ..

The outdoor air conditioning system according to the twelfth viewpoint is the next when the abnormality displayed on the display unit as the first abnormality information by the remote controller is resolved in the outdoor air conditioning system according to the eleventh viewpoint. Abnormal information with a high degree of seriousness is displayed on the display unit as the first abnormal information.

By adopting the above-mentioned abnormality information display configuration, the outdoor air-conditioning system according to the twelfth viewpoint can confirm the existence of the outdoor air-conditioning device in which a serious abnormality has occurred in descending order of severity. ..

It is a schematic block diagram of an outdoor air conditioning system. It is a schematic block diagram of an outdoor air conditioner. It is an external perspective view of an outdoor air conditioner. It is a schematic vertical sectional view which shows the inside of the outdoor air conditioner. It is a control block diagram of an outdoor air conditioning system. It is a schematic block diagram of the outdoor air conditioning system which concerns on modification A. It is a schematic block diagram of the outdoor air conditioning system which concerns on modification B. FIG. 5 is an external perspective view of an outdoor air conditioner according to a modified example D. It is a control block diagram of the outdoor air conditioning system concerning the modification D. FIG. 5 is a schematic vertical sectional view showing the inside of the outdoor air conditioner according to the modified example E. It is a control block diagram of the outdoor air conditioning system which concerns on modification E. It is a classification table of the abnormality information of the outdoor air conditioning system concerning the modification G. It is a flowchart of abnormality information display of the outdoor air conditioning system which concerns on modification G.

Hereinafter, the outdoor air conditioning system will be described with reference to the drawings.

(1) Equipment Configuration FIG. 1 is a schematic configuration diagram of the outdoor air conditioning system 1. FIG. 2 is a schematic configuration diagram of outdoor air conditioners 2A to 2I. FIG. 3 is an external perspective view of the outdoor air conditioners 2A to 2I. FIG. 4 is a schematic vertical sectional view showing the inside of the outdoor air conditioners 2A to 2I.

<Overall>
The outdoor air conditioning system 1 has a plurality of outdoor air conditioning devices 2A to 2I arranged in the outdoor OS. Here, the outdoor OS means a space exposed to the outside air. For example, it may be a place without a roof such as a park or an outdoor stadium, an outdoor space with a roof, a place such as an eastern house or a veranda, or an outdoor seat in a restaurant. Further, FIG. 1 shows an example in which nine outdoor air conditioners 2A to 2I are arranged in the outdoor OS, but the number of outdoor air conditioners corresponding to the size of the space of the outdoor OS may be arranged. Just do it. The outdoor air conditioners 2A to 2I are devices that cool and heat the outdoor OS by a vapor compression refrigeration cycle, respectively. Further, the outdoor air conditioning system 1 is communicably connected to a plurality of outdoor air conditioning devices 2A to 2I, and has one remote controller 4 for operating the plurality of outdoor air conditioning devices 2A to 2I. The remote controller 4 is arranged in an outdoor OS in which a plurality of outdoor air conditioners 2A to 2I are arranged, or in a building adjacent to the outdoor OS. A plurality of outdoor air conditioners 2A to 2I are connected in series to the remote controller 4 by a communication line 5. Specifically, the remote controller 4, the outdoor air conditioner 2A ... The outdoor air conditioner 2I are connected in order by the communication line 5.

<Outdoor air conditioner>
Each of the outdoor air conditioners 2A to 2I has a refrigerant circuit 10 that forms a vapor compression refrigeration cycle. Then, the refrigerant is filled in the refrigerant circuit 10. Here, as the refrigerant filled in the refrigerant circuit 10, for example, there are R32 alone and a mixed refrigerant containing R32. Examples of the mixed refrigerant containing R32 include R452B, R410A, and R454B. In R452B, R32 is 67.0 wt%, R125 is 7.0 wt%, and R1234yf is 26.0%. R410A has 50 wt% of R32 and 50 wt% of R125. In R454B, R32 is 72.5 wt% and R1234yf is 27.5 wt%.

The refrigerant circuit 10 includes a compressor 11, a flow path switching mechanism 12, a heat source side heat exchanger 13, an expansion mechanism 14, a user side heat exchanger 15, and a pipe connecting these devices. doing.

The compressor 11 is a device that compresses the low-pressure refrigerant in the refrigeration cycle until it reaches a high pressure. The compressor 11 is a compressor having a closed structure in which a positive displacement compression element (not shown) such as a rotary type or a scroll type is rotationally driven by a compressor motor (not shown).

The flow path switching mechanism 12 is a switching valve for switching the direction of the flow of the refrigerant in the refrigerant circuit 10. The flow path switching mechanism 12 causes the heat source side heat exchanger 13 to function as a radiator of the refrigerant compressed in the compressor 11 during cooling, and dissipates heat from the user side heat exchanger 15 in the heat source side heat exchanger 13. Switching to the cooling cycle state that functions as a refrigerant evaporator is performed (see the solid line of the flow path switching mechanism 12 in FIG. 2). The flow path switching mechanism 12 causes the heat source side heat exchanger 13 to function as an evaporator of the refrigerant dissipated in the utilization side heat exchanger 15 during heating, and the utilization side heat exchanger 15 is compressed in the compressor 11. It switches to a heating cycle state that functions as a radiator of the refrigerant (see the broken line of the flow path switching mechanism 12 in FIG. 2). Here, a four-way switching valve is used as the flow path switching mechanism 12. The flow path switching mechanism 12 is not limited to the four-way switching valve, and may be configured to perform the same function as the four-way switching valve by using a plurality of valves.

The heat source side heat exchanger 13 is a heat exchanger that functions as a radiator of a refrigerant that uses outdoor air as a cooling source during cooling and functions as an evaporator of a refrigerant that uses outdoor air as a heating source during heating.

The expansion mechanism 14 decompresses the high-pressure refrigerant in the refrigeration cycle dissipated in the heat source side heat exchanger 13 during cooling to the low pressure in the refrigeration cycle, and freezes the high-pressure refrigerant in the refrigeration cycle dissipated in the utilization side heat exchanger 15 during heating. It is a mechanism that reduces the pressure to low pressure in the cycle. Here, an expansion valve is used as the expansion mechanism 14. The expansion mechanism 14 is not limited to the expansion valve, and may be a capillary tube.

The user-side heat exchanger 15 is a heat exchanger that functions as a refrigerant evaporator to cool the outdoor air during cooling and functions as a refrigerant radiator during heating to heat the outdoor air.

Further, the outdoor air conditioners 2A to 2I each include a heat source side fan 16 and a user side fan 17 in addition to the equipment and piping (hereinafter referred to as refrigerant circuit component parts) constituting the above-mentioned refrigerant circuit 10. Have.

The heat source side fan 16 is a fan that creates an air flow that passes through the heat source side heat exchanger 13. Specifically, the heat source side fan 16 is a fan that sucks outdoor air into the device, exchanges heat with the refrigerant in the heat source side heat exchanger 13, and then discharges the outdoor air to the outdoor OS. Here, as the heat source side fan 16, a propeller fan that is rotationally driven by a heat source side fan motor is used. The heat source side fan 16 is not limited to the propeller fan, and may be a fan of another type.

The user-side fan 17 is a fan that creates an air flow that passes through the user-side heat exchanger 15. Specifically, the user-side fan 17 is a fan that sucks outdoor air into the device, exchanges heat with the refrigerant in the user-side heat exchanger 15, and then supplies the outdoor air to the outdoor OS. Here, as the user-side fan 17, a turbo fan that is rotationally driven by the user-side fan motor is used. The user side fan 17 is not limited to the turbo fan, and may be a fan of another type.

The refrigerant circuit components and fans 16 and 17 are housed in the casing 20. In other words, the outdoor air conditioners 2A to 2I are the casing 20, the compressor 11 housed in the casing 20, the heat source side heat exchanger 13, the heat source side fan 16, the user side heat exchanger 15, and the user side fan 17, respectively. And so on. The structure and equipment arrangement of the casing 20 will be described below, but the structure and equipment arrangement of the casing 20 are not limited to those described below.

The casing 20 has a rectangular parallelepiped shape having a substantially square horizontal cross section. The horizontal cross section may be polygonal or rectangular. It may be circular. The casing 20 has a plurality of columns 21a to 21d, a bottom plate 22, and a top plate 23. The bottom plate 22 constitutes the lower surface of the casing 20. The top plate 23 constitutes the upper surface of the casing 20. A heat source side outlet 23a is formed on the top plate 23. The internal space of the casing 20 is partitioned by intermediate plates 24 to 26. The intermediate plates 24 to 26 also contribute to reinforcing the structure of the casing 20. The intermediate plates 24 to 26 are arranged in an appropriate number and at an appropriate position according to the design. The columns 21a to 21d are vertically arranged at the four corners of a square that is horizontal when viewed from above. The bottom plate 22, the top plate 23, and the intermediate plates 24 to 26 are fixed to the columns 21a to 21d. Decorative members 27a to 27d are provided on the four side surfaces 20a to 20d of the casing 20 sandwiched between the columns 21a to 21d. Heat source side suction ports 28a to 28d are formed in portions of the decorative members 27a to 27d (side surfaces 20a to 20d of the casing 20) facing the heat source side heat exchanger 13. Further, the user-side suction ports 29a to 29d are formed in the portions of the decorative members 27a to 27d (side surfaces 20a to 20d of the casing 20) facing the user-side heat exchanger 15. Further, the use side outlets 30a to 30d are located between the heat source side suction ports 28a to 28d and the use side suction ports 29a to 29d of the decorative members 27a to 27d (side surfaces 20a to 20d of the casing 20) in the vertical direction. It is formed. The user-side outlets 30a to 30d face a portion of the internal space of the casing 20 between the intermediate plate 24 and the intermediate plate 25 in the vertical direction. The decorative members 27a to 27d are appropriately divided into upper and lower parts and left and right parts.

In the internal space of the casing 20, a heat source side fan 16, a heat source side heat exchanger 13, a user side fan 17, a user side heat exchanger 15, and a compressor 11 are arranged in this order from the top. The heat source side fan 16 is arranged so as to face the heat source side air outlet 23a on the upper surface (top plate 23) of the casing 20. The heat source side heat exchanger 13 is arranged on the intermediate plate 24 so as to face the side surfaces 20a to 20d (heat source side suction ports 28a to 28d) of the casing 20. The user-side fan 17 is arranged between the intermediate plate 24 and the intermediate plate 25 in the vertical direction. The outlet portion of the user-side fan 17 faces the user-side outlets 30a to 30d. The intermediate plate 25 is formed with an opening 25a facing the suction portion of the user-side fan 17. The user-side heat exchanger 15 is arranged on the intermediate plate 26 so as to face the side surfaces 20a to 20d (utilization-side suction ports 29a to 29d) of the casing 20. The compressor 11 is arranged on the bottom plate 22. A caster 31 is attached to the bottom plate 22. Therefore, the outdoor air conditioners 2A to 2I are movable.

(2) Control configuration FIG. 5 is a control block diagram of the outdoor air conditioning system 1.

<Overall>
As described above, the control unit of the outdoor air conditioning system 1 is configured by communicating and connecting a plurality of outdoor air conditioning devices 2A to 2I to one remote controller 4. Specifically, the outdoor air conditioners 2A to 2I have device-side control units 32A to 32I for controlling the compressor 11, the switching mechanism 12, the expansion mechanism 14, the fans 15, 17, and the like, respectively. The device control units 32A to 32I are provided in the casing 20 (see FIG. 4).

<Device side control unit>
The device-side control units 32A to 32I are provided in the outdoor air conditioners 2A to 2I, respectively, as described above. The device-side control units 32A to 32I have device-side CPUs 33A to 33I, device-side communication units 34A to 34I, and device-side storage units 35A to 35I, respectively.

The device-side CPUs 33A to 33I are connected to the device-side communication units 34A to 34I and the device-side storage units 35A to 35I, respectively. The device-side communication units 34A to 34I each communicate control data and the like with the remote controller 4. The device-side storage units 35A to 35I store control data and the like, respectively. Then, the device-side CPUs 33A to 33I form the outdoor air-conditioning devices 2A to 2I while communicating and reading / writing control data and the like via the device-side communication units 34A to 34I and the device-side storage units 35A to 35I, respectively. It controls devices 11, 12, 14, 15, 17, and the like.

<Remote controller>
The remote controller 4 includes a remote control CPU 41, a remote control communication unit 42, a remote control storage unit 43, a remote control operation unit 44, and a remote control display unit 45.

The remote control CPU 41 is connected to the remote control communication unit 42, the remote control storage unit 43, the remote control operation unit 44, and the remote control display unit 45. The remote control communication unit 42 communicates control data and the like with the device-side control units 32A to 32I. The remote control storage unit 43 stores control data and the like. The remote control operation unit 44 receives an input such as a control command from the operator. The remote control display unit 45 displays the operation and the like. Then, the remote controller CPU 41 receives an input such as a control command via the remote controller operation unit 44, and while reading and writing control data and the like to the remote controller storage unit 43, the device side control units 32A to via the remote controller communication unit 42. A control command or the like is given to 32I. In addition, the remote controller display unit 45 displays the operation and the like.

(3) Operation Next, the operation of the outdoor air conditioning system 1 will be described with reference to FIGS. 1, 2, 4 and 5. The outdoor air conditioners 2A to 2I can perform cooling and heating as basic operations, respectively.

<Cooling>
Upon receiving a cooling operation command, the device-side control units 32A to 32I set the operation mode of the outdoor air conditioners 2A to 2I to cooling. Then, the device-side control units 32A to 32I switch the flow path switching mechanism 12 to the cooling cycle state (the state shown by the solid line in FIG. 2), drive the compressor 11 and the fans 16 and 17, and drive the expansion mechanism 14. Open.

Then, the low-pressure refrigerant in the refrigeration cycle in the refrigerant circuit 10 is sucked into the compressor 11, compressed to a high pressure in the refrigeration cycle, and then discharged. The high-pressure gas refrigerant discharged from the compressor 11 is sent to the heat source side heat exchanger 13 through the flow path switching mechanism 12.

The high-pressure gas refrigerant sent to the heat source-side heat exchanger 13 exchanges heat with the outdoor air supplied as a cooling source by the heat-source-side fan 16 in the heat-source-side heat exchanger 13 to dissipate heat and dissipate the high-pressure liquid. Becomes a refrigerant. At this time, the outdoor air is sucked into the casing 20 by the heat source side fan 16 through the heat source side suction ports 28a to 28d, passes through the heat source side heat exchanger 13, and then discharged to the outdoor OS through the heat source side outlet 23a. Will be done.

The high-pressure liquid refrigerant dissipated in the heat source side heat exchanger 13 is sent to the expansion mechanism 14. The high-pressure liquid refrigerant sent to the expansion mechanism 14 is depressurized to the low pressure in the refrigeration cycle by the expansion mechanism 14. The low-pressure refrigerant decompressed by the expansion mechanism 14 is sent to the user-side heat exchanger 15.

The low-pressure refrigerant sent to the user-side heat exchanger 15 evaporates by exchanging heat with the outdoor air supplied as a heating source by the user-side fan 17 in the user-side heat exchanger 15. At this time, the outdoor air is sucked into the casing 20 by the user side fan 17 through the user side suction ports 29a to 29d, passes through the user side heat exchanger 15, and then passes through the user side outlets 30a to 30d to the outdoor OS. Is supplied to. As a result, the outdoor air is cooled and the outdoor OS is cooled.

The low-pressure refrigerant evaporated in the user-side heat exchanger 15 is sent to the compressor 11 through the flow path switching mechanism 12, and is sucked into the compressor 11 again.

<Heating>
Upon receiving the heating operation command, the device-side control units 32A to 32I set the operation mode of the outdoor air conditioners 2A to 2I to heating. Then, the device-side control units 32A to 32I switch the flow path switching mechanism 12 to the heating cycle state (the state shown by the broken line in FIG. 2), drive the compressor 11 and the fans 16 and 17, and drive the expansion mechanism 14. Open.

Then, the low-pressure refrigerant in the refrigeration cycle in the refrigerant circuit 10 is sucked into the compressor 11, compressed to a high pressure in the refrigeration cycle, and then discharged. The high-pressure gas refrigerant discharged from the compressor 11 is sent to the user-side heat exchanger 15 through the flow path switching mechanism 12.

The high-pressure gas refrigerant sent to the user-side heat exchanger 15 exchanges heat with the outdoor air supplied as a cooling source by the user-side fan 17 in the user-side heat exchanger 15 to dissipate heat and dissipate the high-pressure liquid. Becomes a refrigerant. At this time, the outdoor air is sucked into the casing 20 by the user side fan 17 through the user side suction ports 29a to 29d, passes through the user side heat exchanger 15, and then passes through the user side outlets 30a to 30d to the outdoor OS. Is supplied to. As a result, the outdoor air is heated to heat the outdoor OS.

The high-pressure liquid refrigerant radiated by the user-side heat exchanger 15 is sent to the expansion mechanism 14. The high-pressure liquid refrigerant sent to the expansion mechanism 14 is depressurized to the low pressure in the refrigeration cycle by the expansion mechanism 14. The low-pressure refrigerant decompressed by the expansion mechanism 14 is sent to the heat source side heat exchanger 13.

The low-pressure refrigerant sent to the heat source side heat exchanger 13 evaporates by exchanging heat with the outdoor air supplied as a heat source by the heat source side fan 16 in the heat source side heat exchanger 13. At this time, the outdoor air is sucked into the casing 20 by the heat source side fan 16 through the heat source side suction ports 28a to 28d, passes through the heat source side heat exchanger 13, and then discharged to the outdoor OS through the heat source side outlet 23a. Will be done.

The low-pressure refrigerant evaporated in the heat source side heat exchanger 13 is sent to the compressor 11 through the flow path switching mechanism 12, and is sucked into the compressor 11 again.

<Batch control>
The outdoor air conditioning system 1 employs a configuration in which a plurality of outdoor air conditioning devices 2A to 2I are operated by one remote controller 4.

Specifically, the remote controller 4 operates a plurality of outdoor air conditioners 2A to 2I at once. An example of batch operation of a plurality of outdoor air conditioners 2A to 2I by the remote controller 4 will be described below.

When the operator inputs a cooling operation command to the remote controller 4 while the outdoor air conditioners 2A to 2I are stopped, the cooling operation command is transmitted to all the device side control units 32A to 32I. Then, the device-side control units 32A to 32I, which have received the cooling operation command, cool the outdoor air conditioners 2A to 2I, respectively. Further, when the operator inputs a heating operation command to the remote controller 4 while the outdoor air conditioners 2A to 2I are stopped, the heating operation command is transmitted to all the device side control units 32A to 32I. .. Then, the device-side control units 32A to 32I that have received the heating operation command heat the outdoor air conditioners 2A to 2I, respectively.

When the operator inputs a heating operation command to the remote controller 4 while the outdoor air conditioners 2A to 2I are cooling, the heating operation command is transmitted to all the device side control units 32A to 32I. Then, the device-side control units 32A to 32I, which have received the heating operation command, switch the outdoor air conditioners 2A to 2I from cooling to heating, respectively. Further, when the operator inputs a cooling operation command to the remote controller 4 while the outdoor air conditioners 2A to 2I are heating, the cooling operation command is transmitted to all the device side control units 32A to 32I. .. Then, the device-side control units 32A to 32I, which have received the cooling operation command, switch the outdoor air conditioners 2A to 2I from heating to cooling, respectively.

When the operator inputs a stop command to the remote controller 4 while the outdoor air conditioners 2A to 2I are operating (cooling or heating), the stop command is transmitted to all the device side control units 32A to 32I. Then, the device-side control units 32A to 32I that have received the stop command stop the operation of the outdoor air conditioners 2A to 2I, respectively. Further, when it is desired to stop the operation (cooling or heating) of the outdoor air conditioners 2A to 2I at a desired time, the operator causes the remote controller 4 to operate the outdoor air conditioners 2A to 2I (cooling or heating). Enter the set time of the stop timer. Then, when the time reaches the set time of the stop timer, the stop command is transmitted to all the device side control units 32A to 32I, and the operation of all the outdoor air conditioners 2A to 2I can be stopped. On the contrary, when it is desired to start the operation (cooling or heating) of the outdoor air conditioners 2A to 2I at a desired time, the operator sets the operation start timer of the outdoor air conditioners 2A to 2I on the remote controller 4. Enter. Then, when the time reaches the set time of the start timer, the operation command is transmitted to all the device side control units 32A to 32I, and the operation of all the outdoor air conditioners 2A to 2I can be started.

When the operator inputs a command to change the air volume setting of the user side fan 17 to the remote controller 4 while the outdoor air conditioners 2A to 2I are operating (cooling or heating), the command to change the air volume setting is all devices. It is transmitted to the side control units 32A to 32I. Then, the device-side control units 32A to 32I, which have received the command to change the air volume setting, change the air volume of the user-side fan 17 of the outdoor air conditioners 2A to 2I, respectively.

When the outdoor air conditioners 2A to 2I are operating (cooling or heating) and the operator inputs a command to change the strength setting of the air conditioning capacity (cooling capacity or heating capacity) to the remote controller 4, the strength of the air conditioning capacity is strong or weak. The setting change command is transmitted to all the device side control units 32A to 32I. Then, the device-side control units 32A to 32I, which have received the command to change the strength setting of the air conditioning capacity, change the operating capacity of the compressor 11 of the outdoor air conditioners 2A to 2I and the opening degree of the expansion mechanism 14, respectively.

In this way, in the outdoor air conditioning system 1, when the operator inputs a control command or the like to the remote controller 4, the same control command or the like is transmitted to all the outdoor air conditioning devices 2A to 2I, and all the outdoor air conditioning devices 2A It is configured so that the same operation is performed in ~ 2I.

(4) Features Next, the features of the outdoor air conditioning system 1 will be described.

<A>
As described above, the outdoor air conditioning system 1 employs a configuration in which a plurality of outdoor air conditioning devices 2A to 2I are operated by one remote controller 4. With this configuration, the operator can operate the plurality of outdoor air conditioners 2A to 2I without going to the respective arrangement locations of the plurality of outdoor air conditioners 2A to 2I. The time and effort required to operate the 2I can be reduced.

<B>
As described above, the outdoor air conditioning system 1 employs a configuration in which the remote controller 4 and the plurality of outdoor air conditioning devices 2A to 2I are connected by a communication line 5 (wired). With this configuration, for example, as shown in FIG. 1, good communication can be performed even when there is an outdoor air conditioner 2I or the like arranged at a location away from the remote controller 4 (when it is disadvantageous for communication). It can be carried out.

Moreover, since the plurality of outdoor air conditioners 2A to 2I are connected in series to the remote controller 4 by the communication line 5, the wiring system of the communication line 5 can be simplified.

<C>
As described above, the outdoor air conditioning system 1 is operated collectively by all the outdoor air conditioning devices 2A to 2I by adopting a configuration in which the remote controller 4 operates a plurality of outdoor air conditioning devices 2A to 2I at once. It is possible to issue commands such as stop and stop.

(5) Modification example <A>
In the outdoor air conditioning system 1 of the above embodiment, a plurality of outdoor air conditioning devices 2A to 2I are connected in series to the remote controller 4 by a communication line 5 (see FIG. 1).

However, the configuration in which the remote controller 4 and the plurality of outdoor air conditioners 2A to 2I are connected by the communication line 5 (wired) is not limited to this.

For example, as shown in FIG. 6, a plurality of outdoor air conditioners 2A to 2I may be connected to the remote controller 4 in parallel by a communication line 5. Specifically, the remote controller 4 and each of the outdoor air conditioners 2A to 2I are connected by a communication line 5.

Even in this parallel connection configuration, as in the above embodiment, even when there is an outdoor air conditioner 2I or the like arranged at a location away from the remote controller 4 (when it is disadvantageous for communication), it is good. Can communicate. Further, in this parallel connection configuration, for example, even if a communication abnormality occurs between one of the plurality of outdoor air conditioners 2A to 2I and the remote controller 4, communication between the other outdoor air conditioner and the remote controller 4 occurs. As for, the normal state can be maintained. However, since the wiring system of the communication line 5 is slightly more complicated than the series connection, the series connection is more advantageous from the viewpoint of simplifying the wiring system.

<B>
In the outdoor air conditioning system 1 of the above embodiment and the modified example A, a plurality of outdoor air conditioning devices 2A to 2I are connected to the remote controller 4 by a communication line 5 (wired) (see FIGS. 1 and 6).

However, the configuration for communicating and connecting the remote controller 4 and the plurality of outdoor air conditioners 2A to 2I is not limited to this.

For example, as shown in FIG. 7, a plurality of outdoor air conditioners 2A to 2I may be wirelessly connected to the remote controller 4. Specifically, the device-side communication units 34A to 34I of the device-side control units 32A to 32I and the remote controller communication unit 42 (see FIG. 5) of the remote controller 4 are configured to enable wireless communication.

This wireless connection configuration eliminates the communication line connecting the remote controller 4 and the plurality of outdoor air conditioners 2A to 2I. Therefore, the wiring work of the communication line becomes unnecessary. Further, the arrangement of the outdoor air conditioners 2A to 2I can be easily changed.

<C>
The outdoor air conditioning system 1 of the above-described embodiments and modifications A and B employs a configuration in which the remote controller 4 operates a plurality of outdoor air conditioning devices 2A to 2I at once.

However, the configuration in which a plurality of outdoor air conditioners 2A to 2I are operated by one remote controller 4 is not limited to the configuration in which the outdoor air conditioners 2A to 2I are operated collectively.

For example, a configuration may be adopted in which the remote controller 4 individually operates a plurality of outdoor air conditioners 2A to 2I. Specifically, the remote controller operation unit 44 and the remote controller display unit 45 of the remote controller 4 select and control the outdoor air conditioner 2A to 2I to be operated from the outdoor air conditioners 2A to 2I that are communication-connected to the remote controller 4. It is configured so that commands etc. can be input. Then, when the operator inputs a control command or the like to the outdoor air conditioner to be operated, the control command or the like is transmitted to the device side control unit of the outdoor air conditioner to be operated. Then, the device-side control unit that receives the control command or the like operates the outdoor air conditioner to be operated according to the control command or the like. Since the control commands and their operations are the same as the control commands and their operations when operating the plurality of outdoor air conditioners 2A to 2I at once, the description thereof will be omitted here.

As described above, the outdoor air conditioning system 1 of this modification adopts a configuration in which the remote controller 4 individually operates a plurality of outdoor air conditioning devices 2A to 2I, so that each of the outdoor air conditioning devices 2A to 2I is operated. It is possible to issue commands such as start and stop.

<D>
In the outdoor air-conditioning system 1 of the above-described embodiments and modifications A to C, the operator operates the outdoor air-conditioning devices 2A to 2I from a location away from the outdoor air-conditioning devices 2A to 2I by the remote controller 4, so that the operation target is It may be difficult to check the outdoor air conditioner. In particular, when operating a plurality of outdoor air conditioners 2A to 2I individually, it is desirable to confirm the outdoor air conditioners to be operated before performing the operation. However, the arrangement of the outdoor air conditioners 2A to 2I in the outdoor OS may be changed due to a layout change or the like. In such a case, the actual arrangement of the outdoor air conditioners 2A to 2I may not match the arrangement of the outdoor air conditioners 2A to 2I recognized by the operator by the remote controller 4.

Therefore, the outdoor air conditioning system 1 of this modification adopts a configuration in which a light emitting unit 36 is provided on the outer surface of the casing 20 of the outdoor air conditioning devices 2A to 2I to illuminate the light emitting unit 36 of the outdoor air conditioning device to be operated. ing.

Specifically, as shown in FIG. 8, the outdoor air conditioners 2A to 2I have a light emitting unit 36 on the outer surface of the casing 20. The light emitting unit 36 includes an LED and the like, and is connected to the device side control units 32A to 32I of the outdoor air conditioners 2A to 2I as shown in FIG. The light emitting portion 36 is arranged on the upper portion (the portion above the heat source side suction ports 28a to 28d) of the support columns 21d forming the side surface of the casing 20 on the outer surface of the casing 20. The arrangement of the light emitting unit 36 is not limited to the support column 21d, and may be a portion (side surfaces 20a to 20d and other support columns 21a to 21c) constituting the side surface of the casing 20.

Then, when the operator selects the outdoor air conditioner to be operated from the outdoor air conditioners 2A to 2I, the signal is transmitted to the device side control unit of the outdoor air conditioner to be operated. Then, the device-side control unit that receives the signal illuminates the light emitting unit 36 of the outdoor air conditioner to be operated. Here, the mode of illuminating the light emitting unit 36 may be simply lit or blinking. In short, the light emitting unit 36 of the outdoor air conditioner to be operated may be illuminated in a manner that can be distinguished from the state of the light emitting unit 36 of the outdoor air conditioner other than the operation target. As a result, the operator can confirm the outdoor air conditioner selected by the remote controller 4. Then, if the selected outdoor air conditioner is the outdoor air conditioner to be operated, the operator can input a desired control command or the like to operate the outdoor air conditioner to be operated.

As described above, the outdoor air-conditioning system 1 of the present modification confirms the outdoor air-conditioning device to be operated by adopting the configuration in which the light emitting unit 36 of the outdoor air-conditioning device to be operated is illuminated as described above. Above, you can operate the outdoor air conditioner. Further, when operating a plurality of outdoor air conditioners 2A to 2I at once, it can be confirmed whether or not all the outdoor air conditioners 2A to 2I are correctly connected.

Further, the outdoor air conditioning system 1 of this modification can easily confirm the outdoor air conditioning device to be operated by adopting a configuration in which the light emitting unit 36 is provided on the side surface of the casing 20. At this time, the arrangement direction of the outdoor air conditioner to be operated can also be confirmed.

<E>
The outdoor air conditioning system 1 of the above modification D adopts a configuration in which a light emitting unit 36 is provided on the outer surface of the casing 20 of the outdoor air conditioning devices 2A to 2I to illuminate the light emitting unit 36 of the outdoor air conditioning device to be operated. There is.

However, the configuration for confirming the outdoor air conditioner to be operated is not limited to the configuration for illuminating the light emitting unit 36 of the outdoor air conditioner to be operated.

For example, when the flaps 37 are provided at the outlets 30a to 30d on the utilization side of the outdoor air conditioners 2A to 2I, a configuration may be adopted in which the flaps 37 of the outdoor air conditioner to be operated are operated.

Specifically, as shown in FIG. 10, the outdoor air conditioners 2A to 2I provide flaps 37 to the user side outlets 30a to 30d to change the direction of the air flow blown from the user side outlets 30a to 30d. Have. The flap 37 may change the vertical direction of the air flow, or may change the left / right direction of the air flow. As shown in FIG. 11, the flap 37 is connected to the device-side control units 32A to 32I of the outdoor air conditioners 2A to 2I.

Then, when the operator selects the outdoor air conditioner to be operated from the outdoor air conditioners 2A to 2I, the signal is transmitted to the device side control unit of the outdoor air conditioner to be operated. Then, the device-side control unit that receives the signal operates the flap 37 of the outdoor air conditioner to be operated. Here, as a mode for operating the flap 37, for example, there is a swing operation or the like. As a result, the operator can confirm the outdoor air conditioner selected by the remote controller 4. Then, if the selected outdoor air conditioner is the outdoor air conditioner to be operated, the operator can input a desired control command or the like to operate the outdoor air conditioner to be operated.

As described above, the outdoor air-conditioning system 1 of the present modification confirms the outdoor air-conditioning device to be operated by adopting the configuration in which the flap 37 of the outdoor air-conditioning device to be operated is operated as described above. Above, you can operate the outdoor air conditioner. Further, when operating a plurality of outdoor air conditioners 2A to 2I at once, it can be confirmed whether or not all the outdoor air conditioners 2A to 2I are correctly connected.

<F>
The outdoor air conditioning system 1 of the modified examples D and E employs a configuration in which the light emitting unit 36 of the outdoor air conditioning device to be operated is illuminated and a configuration in which the flap 37 of the outdoor air conditioning device to be operated is operated.

However, the configuration for confirming the outdoor air conditioner to be operated is limited to the configuration for illuminating the light emitting unit 36 of the outdoor air conditioner to be operated and the configuration for operating the flap 37 of the outdoor air conditioner to be operated. It's not a thing.

For example, the heat source side fan 16 and / or the user side fan 17 of the outdoor air conditioners 2A to 2I may be used to operate the heat source side fan 16 and / or the user side fan 17 of the outdoor air conditioner to be operated. It may be adopted.

Specifically, when the operator selects the outdoor air conditioner to be operated from the outdoor air conditioners 2A to 2I, the signal is transmitted to the device side control unit of the outdoor air conditioner to be operated. Then, the device-side control unit that receives the signal operates the heat source-side fan 16 and / or the user-side fan 17 of the outdoor air conditioner to be operated. Here, both fans 16 and 17 may be operated, or only one of the fans 16 and 17 may be operated. As a result, the operator can confirm the outdoor air conditioner selected by the remote controller 4. Then, if the selected outdoor air conditioner is the outdoor air conditioner to be operated, the operator can input a desired control command or the like to operate the outdoor air conditioner to be operated.

As described above, the outdoor air conditioning system 1 of the present modification is operated by adopting a configuration in which the heat source side fan 16 and / or the user side fan 17 of the outdoor air conditioning device to be operated is operated as described above. After confirming the target outdoor air conditioner, the outdoor air conditioner can be operated. Further, when operating a plurality of outdoor air conditioners 2A to 2I at once, it can be confirmed whether or not all the outdoor air conditioners 2A to 2I are correctly connected.

<G>
In the outdoor air conditioning system 1 of the above-described embodiment and modifications A to F, various abnormalities may occur in the plurality of outdoor air conditioning devices 2A to 2I. Examples of the abnormality of the outdoor air conditioners 2A to 2I are as shown in FIG. Here, abnormalities that require measures to stop the outdoor air conditioner, such as abnormalities of the compressor 11 and fans 16 and 17, are classified into abnormality rank A having the highest degree of severity of the abnormality. In addition, abnormalities that do not require measures to stop the outdoor air conditioner, such as an alarm that notifies the replacement time of the crankcase heater attached to the compressor 11, are classified into abnormality rank B, which has the second highest degree of seriousness after abnormality rank A. Has been done. Further, an abnormality having a lower severity than the abnormality rank B, such as a warning notifying that the device IDs of the outdoor air conditioners 2A to 2I are duplicated, is classified into the abnormality rank C. Then, when various abnormalities occur in the plurality of outdoor air conditioners 2A to 2I, it is preferable that the remote controller 4 displays the abnormality information on the remote controller display unit 45.

Therefore, in the outdoor air conditioning system 1 of this modified example, the remote controller 4 adopts a configuration in which the abnormality information is displayed on the remote controller display unit 45. Hereinafter, the abnormality information display in the outdoor air conditioning system 1 of this modified example will be described with reference to the flowchart of FIG. 13 while showing an example of occurrence of an abnormality.

First, it is assumed that one abnormality occurs in any one of the plurality of outdoor air conditioners 2A to 2I (for example, the outdoor air conditioner 2A). In this case, the device-side control unit 32A of the outdoor air conditioner 2A in which the abnormality has occurred transmits the generated abnormality information (control signal corresponding to the abnormality code) to the remote controller 4, and transmits the abnormality information of the outdoor air conditioner 2A. Received by the remote controller 4 (step ST1). The remote controller 4 that has received the abnormality information stores the abnormality information of the outdoor air conditioner 2A in the remote controller storage unit 43 together with the device ID and the reception time of the outdoor air conditioner 2A. Here, the device ID is assigned to each of the outdoor air conditioners 2A to 2I by the remote controller 4 when, for example, a communication connection is made between the plurality of outdoor air conditioners 2A to 2I and the remote controller 4. Identification number. Further, the remote controller 4 determines whether or not there is other abnormality information received together with the abnormality information of the outdoor air conditioner 2A, in other words, whether or not there is a plurality of abnormality information (step ST2). Here, since the received abnormality information is only one (only one abnormality information of the outdoor air conditioner 2A), the remote controller 4 determines that there is no plurality of abnormality information. Then, the remote controller 4 displays the received abnormality information (first abnormality information) of the outdoor air conditioner 2A on the remote controller display unit 45 (step ST3), and returns to the process of step ST1. In step ST3, the remote controller 4 may display the abnormality rank (or information indicating the abnormality rank) as the abnormality information of the outdoor air conditioner 2A, or the abnormality code (or the abnormality corresponding to the abnormality code). Contents) may be displayed. At this time, the remote controller 4 may also display the device ID of the outdoor air conditioner 2A in which the abnormality has occurred.

Next, in addition to one abnormality in the outdoor air conditioner 2A, one abnormality also occurs in any of the outdoor air conditioners 2B to 2I other than the outdoor air conditioner 2A (for example, the outdoor air conditioner 2B). Imagine the case. In other words, it is assumed that a plurality of abnormalities have occurred in the plurality of outdoor air conditioners 2A to 2I. In this case, not only the device-side control unit 32A of the outdoor air-conditioning device 2A in which the abnormality has already occurred, but also the device-side control unit 32B of the outdoor air-conditioning device 2B in which the abnormality has newly occurred remote the generated abnormality information. It is transmitted to the controller 4. Therefore, the remote controller 4 receives the abnormality information of the outdoor air conditioners 2A and 2B (step ST1). The remote controller 4 that has received the abnormality information stores the abnormality information of the outdoor air conditioners 2A and 2B in the remote controller storage unit 43 together with the device IDs and reception times of the outdoor air conditioners 2A and 2B. Further, the remote controller 4 determines whether or not there is a plurality of abnormality information (step ST2). Here, since there are two received abnormality information (abnormal information of the outdoor air conditioners 2A and 2B), it is determined that there are a plurality of abnormality information of the outdoor air conditioners 2A and 2B. Then, the remote controller 4 displays the abnormality information (first abnormality information) having the highest degree of abnormality among the received abnormality information of the outdoor air conditioners 2A and 2B on the remote controller display unit 45 (step ST4). , Return to the process of step ST1. For example, when the rank of the abnormality occurring in the outdoor air conditioner 2A is A and the rank of the abnormality occurring in the outdoor air conditioner 2B is B, the remote controller 4 sets the outdoor air conditioner 4. The abnormality information of the device 2A is displayed on the remote controller display unit 45 as the first abnormality information. On the contrary, when the rank of the abnormality occurring in the outdoor air conditioner 2A is B and the rank of the abnormality occurring in the outdoor air conditioner 2B is A, the remote controller 4 uses the outdoor air. The abnormality information of the harmonizing device 2B is displayed on the remote controller display unit 45 as the first abnormality information. Further, when the ranks of the abnormalities occurring in the outdoor air conditioner 2A and 2B are the same, the remote controller 4 uses the abnormality information of the outdoor air conditioner 2A already displayed as the first abnormality information in the remote controller display unit 45. Continue to display.

Further, it is assumed that an abnormality other than the abnormality that occurred earlier in the outdoor air conditioner 2A further occurs. In other words, it is assumed that a plurality of abnormalities have occurred in any one of the outdoor air conditioners 2A to 2I. In this case, the device-side control unit 32A of the outdoor air conditioner 2A transmits the newly generated abnormality information together with the already generated abnormality information to the remote controller 4, and remotely transmits the two abnormality information of the outdoor air conditioner 2A. Received by the controller 4 (step ST1). Therefore, the remote controller 4 receives the two abnormality information of the outdoor air conditioner 2A (step ST1). The remote controller 4 that has received the abnormality information stores the two abnormality information of the outdoor air conditioner 2A in the remote controller storage unit 43 together with the device ID and the reception time of the outdoor air conditioner 2A. Further, the remote controller 4 determines whether or not there is a plurality of abnormality information (step ST2). Here, since the received abnormality information is two (two abnormality information of the outdoor air conditioner 2A), it is determined that a plurality of abnormality information of the outdoor air conditioner 2A exists. Then, the remote controller 4 displays the abnormality information (first abnormality information) having the highest degree of abnormality among the two abnormality information of the received outdoor air conditioner 2A on the remote controller display unit 45 (step ST4). , Return to the process of step ST1. For example, if the rank of the abnormality that occurred earlier in the outdoor air conditioner 2A is B and the rank of the abnormality that occurred later in the outdoor air conditioner 2A is A, the remote controller 4 occurs later. The abnormal information of the abnormal abnormality is displayed on the remote controller display unit 45 as the first abnormal information. On the contrary, when the rank of the abnormality that occurred earlier in the outdoor air conditioner 2A is A and the rank of the abnormality that occurred later in the outdoor air conditioner 2A is B, the remote controller 4 moves first. The abnormality information of the abnormality generated in is displayed on the remote controller display unit 45 as the first abnormality information. Further, when the ranks of the two abnormalities occurring in the outdoor air conditioner 2A are the same, the remote controller 4 uses the abnormality information previously generated in the outdoor air conditioner 2A that is already displayed as the first abnormality information. It is continuously displayed on the remote control display unit 45.

Further, it is assumed that the abnormality displayed as the first abnormality information is resolved from the state in which a plurality of abnormalities have occurred in the plurality of outdoor air conditioners 2A to 2I. In this case, the remote controller 4 does not receive the abnormality information displayed as the first abnormality information in step ST1. Therefore, the remote controller 4 stores the abnormality information other than the abnormality information displayed as the first abnormality information in the remote controller storage unit 43 together with the device ID and the reception time. The timing of storing the abnormality information in the remote control storage unit 43 may be the timing of displaying the abnormality information as the first abnormality information or the timing of receiving the abnormality information. Further, the remote controller 4 displays the abnormality information having the next highest abnormality rank on the remote controller display unit 45 as the first abnormality information (steps ST2 to ST4). For example, when the abnormality of rank A is resolved from the state in which the abnormality of rank A and the abnormality of rank B have occurred, the remote controller 4 displays the first abnormality information displayed on the remote controller display unit 45. , The abnormal information of rank A is changed to the abnormal information of rank B.

As described above, the outdoor air conditioning system 1 of the present modification has the highest degree of seriousness of the abnormality when the remote controller 4 causes an abnormality in the plurality of outdoor air conditioning devices 2A to 2I as described above. The abnormality information is displayed on the remote controller display unit 45 as the first abnormality information. Therefore, in the outdoor air conditioning system 1 of this modification, the existence of the outdoor air conditioning device in which a serious abnormality has occurred can be confirmed through the remote controller display 45 of the remote controller 4, and appropriate measures are taken for the occurring abnormality. Can be taken. In particular, when only the first abnormality information is displayed on the remote controller display unit 45, it becomes easy to confirm the abnormality information having the highest degree of severity of the abnormality.

Further, in the outdoor air conditioning system 1 of this modified example, when the remote controller 4 resolves the abnormality displayed on the remote controller display 45 as the first abnormality information, the abnormality information having the next highest degree of seriousness is transmitted. It is displayed on the remote controller display unit 45 as the first abnormality information. Therefore, in the outdoor air conditioning system 1 of this modified example, the existence of the outdoor air conditioning device in which a serious abnormality has occurred can be confirmed in descending order of severity, and appropriate measures are taken in order from the abnormality having the highest degree of seriousness. Can be taken.

<H>
In the outdoor air conditioning system 1 of the above modification G, when an abnormality occurs in a plurality of outdoor air conditioning devices 2A to 2I, the remote controller 4 uses the abnormality information having the highest degree of abnormality as the first abnormality information. It is displayed on the remote control display unit 45.

However, the remote controller 4 may display not only the first abnormality information having the highest degree of seriousness but also other abnormality information on the remote controller display unit 45. In this case, it is preferable that the remote controller 4 devises a display in order to make it easier to recognize the first abnormality information. For example, the remote controller 4 displays a plurality of abnormality information in order of increasing severity of abnormality on the remote controller display unit 45, or changes the character size and color according to the degree of severity of abnormality to display the remote controller. It can be displayed on the unit 45.

Further, when the remote controller 4 has a light emitting unit such as an LED, the remote controller 4 may display the abnormality information on the remote controller display unit 45 and make the light emitting unit illuminate. Here, the mode of illuminating the light emitting portion of the remote controller 4 may be blinking or illuminating with a special light color. In short, the light emitting unit of the remote controller 4 may be illuminated in a manner that can be distinguished from the state of the light emitting unit of the remote controller 4 when the abnormality information is not displayed. As a result, the operator can confirm the existence of the outdoor air conditioner in which a serious abnormality has occurred by the light emitting unit of the remote controller 4 without checking the remote controller display unit 45 of the remote controller 4.

Further, when a plurality of outdoor air conditioners 2A to 2I have a light emitting unit 36 as in the outdoor air conditioner system 1 of the modified example D, the device side control unit of the outdoor air conditioner in which an abnormality has occurred is a light emitting unit. The 36 may be illuminated in a manner indicating that an abnormality has occurred.

Further, the remote controller 4 may be able to display the history of the abnormality information stored in the remote controller storage unit 43 on the remote controller display unit 45.

Further, in the outdoor air conditioning system 1 of the modified example G, when a plurality of abnormalities occur in one outdoor air conditioning device, the device side control unit transmits a plurality of abnormality information to the remote controller 4. Then, the remote controller 4 selects the abnormality information having the highest degree of severity of the abnormality from the plurality of abnormality information including these abnormality information, and displays the selected abnormality information as the first abnormality information on the remote controller display unit 45. doing. However, the exchange of abnormality information between the device-side control unit and the remote controller is not limited to this. For example, when a plurality of abnormalities occur in one outdoor air conditioner, the device side control unit selects the abnormality information having the highest degree of abnormality from the plurality of abnormality information and sets the remote controller 4 to the abnormality information. You may send it. In this case, since the received abnormality information is limited to the one selected by the device side control unit, the remote controller 4 does not have to perform the process of selecting the abnormality information having the highest degree of abnormality. be able to. Also, even if the abnormality information is received from another outdoor air conditioner (when the abnormality information is received from multiple outdoor air conditioners), the abnormality information with the highest degree of severity of the abnormality is also received. It is possible to reduce the process of selecting.

<I>
The outdoor air conditioners 2A to 2I constituting the outdoor air conditioner 1 of the above-described embodiments and modifications A to F are outdoor air conditioners of a type in which cooling and heating are switched, but the type of the outdoor air conditioner is Is not limited to this. For example, the outdoor air conditioner may be of a type that dehumidifies in addition to cooling and heating, or may be of a type that performs only cooling or a type that performs only heating.

Although the embodiments of the present disclosure have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the present disclosure described in the claims. ..

The present disclosure is widely applicable to outdoor air conditioners arranged outdoors.

1 Outdoor air conditioning system 2A to 2I Outdoor air conditioning device 4 Remote controller 11 Compressor 13 Heat source side heat exchanger 15 User side heat exchanger 16 Heat source side fan 17 User side fan 20 Casing 23a Heat source side outlet 30a to 30d User side Air outlet 36 Light emitting unit 37 Flap 45 Remote control display unit (display unit)

Japanese Unexamined Patent Publication No. 2006-242510

Claims (11)

A plurality of outdoor air conditioners (2A to 2I) arranged outdoors apart from each other , wherein each of the outdoor air conditioners includes a casing (20), a compressor (11) housed in the casing, and a heat source. Side heat exchanger (13), heat source side fan (16) that creates an air flow through the heat source side heat exchanger, user side heat exchanger (15), and air passing through the user side heat exchanger. Those that have a user fan (17) that creates a flow, and
A remote controller (4) that is communicably connected to the plurality of outdoor air conditioners and operates the plurality of outdoor air conditioners, and a remote controller (4).
With
In the casing, a heat source side suction port (28a to 28d) for sucking an air flow passing through the heat source side heat exchanger into the inside of the casing and an air flow passing through the utilization side heat exchanger of the casing are provided. A user-side suction port (29a to 29d) for sucking inside is formed.
A light emitting portion (36) is provided on the outer surface of the casing above the heat source side suction port and the user side suction port.
The remote controller illuminates the light emitting unit of the outdoor air conditioner to be operated among the plurality of outdoor air conditioners.
Outdoor air conditioning system (1). The plurality of outdoor air conditioners are connected in series to the remote controller by a communication line.
The outdoor air conditioning system according to claim 1. The plurality of outdoor air conditioners are connected to the remote controller in parallel by a communication line.
The outdoor air conditioning system according to claim 1. The plurality of outdoor air conditioners are wirelessly connected to the remote controller.
The outdoor air conditioning system according to claim 1. The remote controller collectively operates the plurality of outdoor air conditioners.
The outdoor air conditioning system according to any one of claims 1 to 4. The remote controller individually operates the plurality of outdoor air conditioners.
The outdoor air conditioning system according to any one of claims 1 to 4. The light emitting portion is arranged on a side surface of the outer surface of the casing.
The outdoor air conditioning system according to any one of claims 1 to 6. The casing is formed with outlets (30a to 30d) on the utilization side that blow out the air flow that has passed through the heat exchanger on the utilization side to the outside of the casing.
The utilization side outlet is provided with a flap (37) for changing the direction of the air flow blown from the utilization side outlet.
The remote controller operates the flap of the outdoor air conditioner to be operated among the plurality of outdoor air conditioners.
The outdoor air conditioning system according to any one of claims 1 to 6. The casing has a heat source side outlet (23a) that blows the air flow that has passed through the heat source side heat exchanger to the outside of the casing, and an air flow that has passed through the utilization side heat exchanger to the outside of the casing. The outlets (30a to 30d) on the user side to blow out are formed.
The remote controller operates the heat source side fan and / or the user side fan of the outdoor air conditioner to be operated among the plurality of outdoor air conditioners.
The outdoor air conditioning system according to any one of claims 1 to 6. The remote controller has a display unit (45) and has a display unit (45).
When an abnormality occurs in the plurality of outdoor air conditioners, the remote controller displays the abnormality information having the highest degree of severity of the abnormality on the display unit as the first abnormality information.
The outdoor air conditioning system according to any one of claims 1 to 9. When the abnormality displayed on the display unit as the first abnormality information is resolved, the remote controller displays the abnormality information having the next highest degree of seriousness on the display unit as the first abnormality information.
The outdoor air conditioning system according to claim 10.

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