JP2012202670A - Air conditioner system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner system capable of carrying out defrost control while meeting a user's requirement for an air conditioner system capacity.SOLUTION: The air conditioner system 100 is provided with outdoor units 1a and 1b, indoor units 2a-1 and 2b-2 connected to the outdoor units 1a and 1b, respectively, and a remote controller 4 connected to the indoor units 2a-1 and 2b-2 and carrying out control for operations of the indoor units 2a-1 and 2b-2. The indoor units 2a-1 and 2b-2 transmit operating state information including the operating capacity of the indoor units 2a-1 and 2b-2 to the remote controller 4, and the remote controller 4 makes defrost execution determination whether or not the defrost operation of each of the indoor units 2a-1 and 2b-2 should be carried out based on the operating capacity included in the operating condition information and the required air conditioner system capacity.

Description

  The present invention relates to an air conditioner system.

  In recent years, an air conditioner system includes a plurality of outdoor units, one or more indoor units connected to the outdoor unit via a communication line, and a remote controller (hereinafter referred to as “remote control” connected to the indoor unit via a communication line). In general, it is configured to include “ The air conditioner system configured as described above is configured to start defrosting by defrosting control in order to prevent the frost from hindering heat exchange when frost adheres to the outdoor heat exchanger during heating operation. ing. However, when all the indoor units connected to the air conditioner system start defrosting at the same time, the required capacity of the air conditioner system requested by the user is not satisfied and the room temperature is lowered (that is, the user feels cold air). It will be. This required capacity indicates the operation capacity (heating capacity or cooling capacity) required by the user for the air conditioner system. Therefore, when the heating capacity of the air conditioner system is smaller than the required capacity required for the air conditioner system, the user feels a cold wind.

  In order to solve such a problem, for example, in the conventional technique represented by Patent Document 1 below, when frost formation is detected by the frost detection means when a plurality of air conditioners are simultaneously performing heating operation, The frost detection signal is sequentially transmitted to the defrosting means. And since a defrosting means sequentially transmits a defrost start signal to several air conditioners one by one, the air conditioner is defrosted one by one sequentially, and the rapid fall of room temperature is suppressed.

JP-A-62-131135

  However, in the conventional technique represented by the above-mentioned Patent Document 1, when the frost detection is detected by the frost detection means, the defrosting of the air conditioner is started by the defrosting means in sequence, for example, There existed a subject that it might become unable to satisfy the required capability calculated | required by the air conditioner system because one air conditioner started defrosting.

  This invention is made | formed in view of the above, Comprising: It aims at obtaining the air conditioner system which can perform defrost control while satisfy | filling the required capability of the air conditioner system which a user asks.

  In order to solve the above-described problems and achieve the object, the present invention performs operation control of a plurality of outdoor units, one or a plurality of indoor units connected to each of the outdoor units, and the indoor units. An air conditioner system including a remote controller, wherein each indoor unit has operating state information including an operation capability of each indoor unit and a continuous operation time of each indoor unit, and a request to start a defrosting operation. A defrost request signal indicating to the remote controller, and when the remote controller receives the defrost request signal, the operating capacity and the continuous operation time included in the operation state information, and the air conditioner system A defrosting execution determination is made as to whether or not the defrosting request signal is transmitted to the indoor unit that is the transmission source of the defrosting request signal, based on the required operating capacity.

  According to this invention, the required capacity of the air conditioner system requested by the user is compared with the operating capacity of the air conditioner system, and it is determined whether or not the defrosting operation is executed for each indoor unit. The defrosting control can be executed while satisfying the required capacity of the air conditioner system desired by the user.

FIG. 1 is a diagram schematically illustrating an air conditioner system according to a first embodiment of the present invention. FIG. 2 is a diagram for explaining the defrosting execution determination of the remote controller when the defrost request signal is generated. FIG. 3 is a flowchart showing mainly the operation of determining whether to permit defrosting. FIG. 4 is a diagram schematically illustrating an air conditioner system according to the second embodiment of the present invention. FIG. 5 is a diagram for explaining the defrosting execution determination of the remote controller when the operation state signal is generated.

  Embodiments of an air conditioner system according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram schematically illustrating an air conditioner system 100 according to the first embodiment of the present invention. An air conditioner system 100 shown in FIG. 1 includes an outdoor unit 1a, an outdoor unit 1b, and an indoor unit 2a-1 and an indoor unit 2a-2 connected to the outdoor unit 1a by an outdoor unit-indoor unit communication line 8a. The indoor units 2b-1 and 2b-2 connected to the outdoor unit 1b by the outdoor unit-indoor unit communication line 8b, and the indoor units 2a-1, 2a-2, 2b by the indoor unit-remote control communication line 9. -1, 2b-2 (respective indoor units 2a-1 to 2b-2) and a remote controller 4 connected to each other. In addition, although the air conditioner system 100 shown by FIG. 1 is comprised including the four indoor units 2a-1 to 2b-2, the number of indoor units is not limited to this. . For example, the air conditioner system 100 may be configured to connect one or three or more indoor units to each outdoor unit.

  The remote controller 4 includes, for example, a liquid crystal display unit, a power on / off button, a temperature increase / decrease button, and a control unit (not shown) that controls the operation of each indoor unit 2a-1 to 2b-2. It is configured.

  The outdoor unit 1a communicates with the indoor units 2a-1 and 2a-2 via the outdoor unit-indoor unit communication line 8a, and the outdoor unit 1b passes through the outdoor unit-indoor unit communication line 8b. Communicating with the indoor units 2b-1 and 2b-2. For example, information such as cooling or heating operation mode, set temperature (23 ° C., 24 ° C., etc.), continuous operation time, and temperature change of various thermistors is transmitted to the outdoor unit-indoor unit communication lines 8a and 8b. And each outdoor unit 1a, 1b should be in the state which can start defrosting with respect to indoor unit 2a-1-2b-2, when defrosting start conditions (for example, outside temperature, piping temperature, etc.) are satisfy | filled. Defrost preparation signals 5a and 5b are transmitted.

  Each of the indoor units 2a-1 to 2b-2 communicates with the remote controller 4 via the indoor unit-remote control communication line 9. In each of the indoor units 2a-1 to 2b-2, there are a communication circuit with the outdoor units 1a and 1b, a fan motor for sending out the air heat-exchanged by a heat exchanger using a commercial power source as a power supply source, The circuit includes a circuit for driving a stepping motor that changes the wind direction, a receiving circuit that receives a control signal from the remote controller 4, a temperature detection circuit, and the like (not shown).

  The indoor unit-remote control communication line 9 includes, for example, the above-described operation mode, set temperature, temperature change of various thermistors, continuous operation time of the indoor unit, and identification information for specifying each indoor unit 2a-1 to 2b-2. (For example, No. 1 unit, No. 2 unit, etc.), information such as the driving capability of each indoor unit 2a-1 to 2b-2 is transmitted. These pieces of information are information (operation state information) indicating the operation states of the indoor units 2a-1 to 2b-2. The operation state information is transmitted from the indoor units 2a-1 to 2b-2 to the remote controller 4 as "operation state signals 7a-1 to 7b-2" described later.

  Further, when the indoor units 2a-1 to 2b-2 receive the defrosting preparation signals 5a and 5b, the indoor units 2a-1 to 2b-2 are connected to the remote controller 4 from the indoor units 2a-1 to 2b-2. Defrost request signals 3a-1, 3a-2, 3b-1, 3b-2 (defrost request signals 3a-1 to 3b-2) transmitted. The defrost request signals 3a-1 to 3b-2 are signals indicating a request to start the defrost operation.

  Furthermore, when the remote controller 4 receives the defrost request signals 3a-1 to 3b-2, the remote controller 4 transmits the defrost request signals 3a-1 to 2b-2 to the indoor units 2a-1 to 2b-2. A defrost control signal 6 is transmitted. This defrost control signal 6 shows the determination result (defrosting execution determination) whether or not to execute the defrosting operation for each of the indoor units 2a-1 to 2b-2.

  When the remote controller 4 receives the defrost request signals 3a-1 to 3b-2 from the indoor units 2a-1 to 2b-2, the operation capability and the continuous operation time of each indoor unit 2a-1 to 2b-2 And the required capacity required for the air conditioner system 100 (operating capacity required for the air conditioner system 100), the indoor unit 2a- that is the transmission source of the defrost request signals 3a-1 to 3b-2 It is determined whether or not the defrosting operation is executed in 1-2b-2, that is, whether defrosting is permitted or prohibited. The required capacity required for the air conditioner system 100 indicates an operation capacity (heating capacity or cooling capacity) requested by the user for the air conditioner system 100.

  Next, operation | movement of the air conditioner system 100 concerning Embodiment 1 is demonstrated concretely using FIG.

  FIG. 2 is a diagram for explaining the defrosting execution determination of the remote controller 4 when the defrost request signals 3a-1 to 3b-2 are generated. In FIG. 2, for the sake of simplicity, the outdoor unit is not shown, and two indoor units (the indoor unit 2 a-1 and the indoor unit 2 b-1) and the remote controller 4 are shown. .

  When receiving the defrost request signal 3a-1 from the indoor unit 2a-1, the remote controller 4 executes the defrosting execution determination described above. Similarly, when receiving the defrost request signal 3b-1 from the indoor unit 2b-1, the remote controller 4 executes the defrosting execution determination.

  The determination parameters for determining whether or not to perform the defrosting operation are, for example, the continuous operation time, the operation capability of each of the indoor units 2a-1 to 2b-2, and the required capability of the air conditioner system 100.

  For example, when the remote controller 4 shown in FIG. 2 receives the defrost request signal 3a-1, the remote controller 4 compares the required capacity of the air conditioner system 100 requested by the user with the operating capacity of the air conditioner system 100. . In addition to the operation capability of the indoor unit 2b-1 that has not transmitted the defrost request signal 3a-1 in addition to this operation capability, the continuous operation time of the indoor unit 2a-1 is also considered in the defrosting execution determination of the remote controller 4. . And when this driving capability does not satisfy the required capability, the remote controller 4 transmits a signal indicating that defrosting is prohibited to the indoor unit 2b-1 as the defrost control signal 6a. The signal which shows is transmitted to the indoor unit 2b-1 as the defrost control signal 6b. As described above, since the indoor unit-remote control communication line 9 includes identification information for specifying each indoor unit 2a-1 to 2b-2, the remote controller 4 determines each indoor unit based on this information. The transmission source of 2a-1 to 2b-2 is grasped and the defrosting control signal 6 is transmitted.

  The defrosting execution determination by the remote controller 4 is performed for each indoor unit 2a-1 to 2b-2, and the defrosting control signal 6 is a defrosting request signal 3a-1 from each indoor unit 2a-1 to 2b-2. To be transmitted in response to ~ 3b-2.

  Supplementing the relationship between the operation capability of each of the indoor units 2a-1 to 2b-2 and the required capability of the air conditioner system 100 is as follows. For example, assuming that the maximum operating capacity of each of the indoor units 2a-1 and 2b-1 shown in FIG. 2 is “50”, the maximum operating capacity of the air conditioner system 100 is “100”. Here, when the necessary capacity of the air conditioner system 100 at a predetermined time is “50”, the indoor units 2a-1 and 2b-1 at this time satisfy the necessary capacity of the air conditioner system 100. It is assumed that the heating operation is performed with the operation capacity “25”. Here, when the indoor unit 2a-1 starts defrosting, in order to satisfy the necessary capacity of the air conditioner system 100 (cover the necessary capacity), it is necessary to increase the operating capacity of the indoor unit 2b-1. In this example, since the operating capacity of the indoor unit 2b-1 has “25” remaining capacity, the air conditioner system 100 is increased by increasing the operating capacity of the indoor unit 2b-1 from “25” to “50”. In addition to satisfying the necessary capacity, the user is not given a cold air feeling even when defrosting is started.

  FIG. 3 is a flowchart showing mainly the operation of determining whether to permit defrosting.

  First, the remote controller 4 determines whether or not the defrost request signals 3a-1 to 3b-2 from any of the indoor units 2a-1 to 2b-2 have been received (step S31). For example, when receiving the defrosting request signal 3a-1 from the indoor unit 2a-1 (step S31, Yes), the remote controller 4 executes the defrosting execution determination at the timing of receiving the defrosting request signal 3a-1, for example. (Step S32). In addition, the timing which performs defrosting implementation determination by the remote control 4 may be immediately after receiving the defrost request signal 3a-1, or may be a predetermined time (for example, several seconds after) when the defrost request signal 3a-1 is received. .

  In step S31, when the defrost request signals 3a-1 to 3b-2 are not received (step S31, No), the remote controller 4 is in a waiting state for receiving the defrost request signals 3a-1 to 3b-2.

  As a result of executing the defrosting execution determination, in order to satisfy the required capacity required for the air conditioner system 100 as the operating capacity of the air conditioner system 100, when defrosting is performed, that is, when defrosting is permitted (Yes in Step S33), The remote controller 4 transmits a signal indicating defrosting permission as the defrosting control signal 6 (step S34). For example, in FIG. 1, when the remote controller 4 receives the defrost request signal 3 a-1, the necessary capacity can be covered by the heating capacity of the indoor units 2 a-2 to 2 b-2 other than the indoor unit 2 a-1. The remote controller 4 transmits a signal indicating defrosting permission to the indoor unit 2a-1 as a defrosting control signal 6.

  As a result of executing the defrosting execution determination, the operating capacity of the air conditioner system 100 does not satisfy the required capacity required for the air conditioner system 100, and therefore, when defrosting is not performed, that is, when defrosting is not permitted (step S33, No). ) The remote controller 4 transmits a signal indicating defrosting prohibition as the defrosting control signal 6 and waits for reception of the defrosting request signals 3a-1 to 3b-2 (step S35). For example, in FIG. 1, when the remote controller 4 receives the defrost request signal 3a-1, the heating capacity of the indoor units 2a-2 to 2b-2 other than the indoor unit 2a-1 cannot cover this necessary capacity. The remote controller 4 transmits a signal indicating that the defrosting is prohibited to the indoor unit 2a-1 as the defrosting control signal 6, and waits to receive the defrosting request signals 3a-1 to 3b-2.

  As described above, in the air conditioner system 100 according to the first embodiment, each of the indoor units 2a-1 to 2b-2 includes an operation capability and a continuous operation time of each of the indoor units 2a-1 to 2b-2. When the status information and the defrost request signals 3a-1 to 3b-2 indicating the start request for the defrosting operation are transmitted to the remote controller 4, and the remote controller 4 receives the defrost request signals 3a-1 to 3b-2, the operation is performed. Based on the operation capability and continuous operation time included in the state information and the operation capability (required capability) required for the air conditioner system 100, the transmission source of the defrost request signals 3a-1 to 3b-2 Since the defrosting execution determination as to whether or not to cause the indoor unit to perform the defrosting operation is performed, the remote controller 4 receives the defrosting request signals 3a-1 to 3b-2 from the indoor units 2a-1 to 2b-2. Each room at the timing For each machine 2a-1~2b-2, it is judged whether the permit defrosting, it is possible to send the result to each of the indoor units 2a-1~2b-2. As a result, it is possible to perform defrosting while satisfying the required capacity of the air conditioner system.

Embodiment 2. FIG.
In the first embodiment, the remote controller 4 is configured to make a defrosting execution determination when receiving the defrosting request signals 3a-1 to 3b-2 from the indoor units 2a-1 to 2b-2. In the second mode, even when the defrost request signals 3a-1 to 3b-2 are not generated, the operation state signals 7a-1, 7a-2, 7b-1, 7b-2 which are operation state information recorded in the remote controller 4 are used. Based on (operating state signals 7a-1 to 7b-2), the defrosting execution determination can be executed. Hereinafter, the same reference numerals are given to the same parts as those in the first embodiment, and the description thereof is omitted, and only different parts will be described here.

  FIG. 4 is a diagram schematically illustrating the air conditioner system 100 according to the second embodiment of the present invention. The air conditioner system 100 of the second embodiment has the same configuration as the air conditioner system 100 of the first embodiment. Further, although the defrost request signals 3a-1 to 3b-2 shown in FIG. 1 are not transmitted to the indoor unit-remote control communication line 9 shown in FIG. 4, the operation state signals 7a-1 to 7b-2 described above are not transmitted. Sent.

  As described above, the operation state signals 7a-1 to 7b-2 are information indicating the operation states of the indoor units 2a-1 to 2b-2. In the operation state signals 7a-1 to 7b-2, the operation mode, the set temperature, the temperature change of various thermistors, the continuous operation time of the indoor unit, and the identification information for specifying each indoor unit 2a-1 to 2b-2 (For example, No. 1 unit, No. 2 unit, etc.) and the driving capability of each indoor unit 2a-1 to 2b-2 are included. The operation state signals 7a-1 to 7b-2 are periodically transmitted from the indoor units 2a-1 to 2b-2 to the remote controller 4, and the operation state information in the operation state signals 7a-1 to 7b-2 is stored in the remote controller. 4 is accumulated.

  The remote controller 4 includes the operation capability, temperature information (information relating to temperature changes of various thermistors), continuous operation time, and air conditioner system included in each of the recorded indoor state information 2a-1 to 2b-2. Based on the driving capability required for 100, the defrosting execution determination is performed as to whether or not each indoor unit 2a-1 to 2b-2 is to execute the defrosting operation.

  Next, operation | movement of the air conditioner system 100 concerning Embodiment 2 is demonstrated concretely using FIG.

  FIG. 5 is a diagram for explaining the defrosting execution determination of the remote controller 4 when the operation state signals 7a-1 to 7b-2 are generated. In FIG. 5, for the sake of simplicity, the outdoor unit is not shown, and two indoor units (indoor unit 2 a-1 and indoor unit 2 b-1) and a remote controller 4 are shown for convenience. .

  Since the remote control 4 according to the second embodiment periodically records the driving state information, for example, even when the driving state signal 7a-1 is temporarily not transmitted to the remote control 4 due to a communication error in the remote control communication line 9 or the like. The remote controller 4 can execute the defrosting execution determination at an arbitrary timing using the accumulated operation state information.

  The determination parameters for determining whether or not to execute the defrosting operation are the operation capacity, temperature information, and continuous operation time of each of the indoor units 2a-1 to 2b-2, the necessary capacity required for the air conditioner system 100, and the like. .

  For example, the remote controller 4 shown in FIG. 5 receives the driving state signals 7a-1 and 7b-1 and accumulates the driving state information. And the remote control 4 compares the required capacity | capacitance of the air conditioner system 100 which a user requests | requires, and the driving capacity of the air conditioner system 100. In addition to the operation capability of the indoor unit (for example, the indoor unit 2b-1) that does not perform the defrosting operation, the operation capability is determined by the indoor unit (for example, the indoor unit) that is scheduled to perform the defrosting operation in the defrosting execution determination of the remote controller 4. The continuous operation time and temperature information of 2a-1) are also considered. And when this driving capability does not satisfy the required capability, the remote controller 4 transmits a signal indicating that the defrosting is prohibited to the indoor unit 2b-1 as the defrosting control signal 6a. The signal which shows is transmitted to the indoor unit 2b-1 as the defrost control signal 6b. Note that the defrosting execution determination by the remote controller 4 is performed for each of the indoor units 2a-1 to 2b-2, as in the first embodiment, and the remote controller 4 uses the identification information to identify each indoor unit 2a-1 The transmission source of 2b-2 is grasped and the defrosting control signal 6 is transmitted.

  As described above, in the air conditioner system 100 according to the second embodiment, each indoor unit 2a-1 includes an operation state, temperature information, and continuous operation time of each indoor unit 2a-1 to 2b-2. The information is transmitted to the remote controller 4, and the operation state information transmitted from each indoor unit 2 a-1 to 2 b-2 is recorded in the remote controller 4, and the remote controller 4 includes each indoor unit included in the recorded operation state information. The indoor units 2a-1 to 2b are based on the operation capability, temperature information, and continuous operation time of the units 2a-1 to 2b-2 and the necessary capability (operation capability) required for the air conditioner system 100. -2 is to determine whether or not to perform the defrosting operation, whether to perform defrosting before receiving the defrost request signals 3a-1 to 3b-2 described in the first embodiment. It can be determined whether or not , It is possible to obtain the same effect as the air conditioner system 100 of the first embodiment.

Embodiment 3 FIG.
The air conditioner system 100 according to the first and second embodiments is based on the defrost request signals 3a-1 to 3b-2 received from the indoor units 2a-1 to 2b-2 or the operation state information recorded in the remote controller 4. In addition to the operation state information, the remote control 4 according to the third embodiment records time information when defrosting was performed in the past, and is configured to perform the defrosting execution determination. And it is comprised so that defrosting execution determination may be performed based on time information. Note that the air conditioner system 100 according to the third embodiment has the same configuration as the air conditioner system 100 shown in FIGS. 1 and 4, and the illustration of the configuration is omitted.

  The time information is recorded for each of the indoor units 2a-1 to 2b-2. For example, it is assumed that the day on which defrosting will be performed from now on is “predetermined day”, and further, defrosting is performed at 9 pm on the day before the predetermined day and 9 pm on the day before the predetermined day. . In this case, the remote controller 4 records time information regarding these dates and times. Therefore, when 9 pm on the predetermined day approaches (for example, 8 pm on the predetermined day), the remote controller 4 executes the defrosting execution determination based on the operation state information and the time information.

  The determination parameters for determining whether or not to execute the defrosting operation include the operation capacity, temperature information, and continuous operation time of each indoor unit 2a-1 to 2b-2, the necessary capacity necessary capacity required for the air conditioner system 100, and the like. It is.

  As described above, the remote controller 4 according to the third embodiment records time information when defrosting was performed in the past in addition to the driving state information. The remote controller 4 stores the recorded driving state information and time information. Since the defrosting execution determination is performed based on the above, the defrosting execution determination is executed before each indoor unit 2a-1 to 2b-2 outputs the defrosting request signals 3a-1 to 3b-2. It is possible to start defrosting. For example, when the defrosting execution determination is performed at the timing at which the defrost request signals 3a-1 to 3b-2 are transmitted, the defrost request signals 3a-1 to 3a-1 are determined depending on the operating states of the indoor units 2a-1 to 2b-2. When 3b-2 is transmitted, the required capacity required for the air conditioner system 100 cannot be satisfied, and defrosting may not be performed. On the other hand, since the time information is recorded in the remote controller 4 when the operation capability of the air conditioner system 100 satisfies the required capability required for the air conditioner system 100, the remote controller 4 uses this time information to It is possible to start defrosting of each indoor unit 2a-1 to 2b-2 at a date and time when there is a high probability of satisfying the required capacity required for the air conditioner system 100.

  Moreover, the past defrosting execution timing becomes clear by recording the defrosting determination result information. Therefore, for example, when the air conditioner system 100 is defrosting at regular intervals, the defrosting can be executed at a stable timing. Therefore, it is possible to maintain a state where the necessary capacity of the air conditioner system 100 is satisfied.

  As described above, the air conditioner system 100 according to the third embodiment records time information when the remote controller 4 performs defrosting in the past in addition to the operation state information, and the recorded operation state information and Since the defrosting execution determination is performed based on the time information, in addition to the effects of the first and second embodiments, the defrosting is suppressed from being performed at a date and time that does not satisfy the required capacity required for the air conditioner system 100. can do.

Embodiment 4 FIG.
Although the air conditioner system 100 according to the first to third embodiments is configured to execute the defrosting execution determination, the air conditioner system 100 according to the fourth embodiment is necessary capacity of the air conditioner system 100. Accordingly, the operation capacity of each indoor unit 2a-1 to 2b-2 is changed. Note that the air conditioner system 100 according to the fourth embodiment has the same configuration as the air conditioner system 100 shown in FIGS. 1 and 4, and illustration of the configuration is omitted.

  For example, assuming that the maximum operating capacity of each of the indoor units 2a-1 and 2b-1 shown in FIG. 2 is “50”, the maximum operating capacity of the air conditioner system 100 is “100”. Here, when the necessary capacity of the air conditioner system 100 at a predetermined time is “50”, the indoor units 2a-1 and 2b-1 at this time satisfy the necessary capacity of the air conditioner system 100. It is assumed that the heating operation is performed with the operation capacity “25”.

  Here, when the indoor unit 2a-1 starts defrosting, in order to satisfy the necessary capacity of the air conditioner system 100 (cover the necessary capacity), it is necessary to increase the operating capacity of the indoor unit 2b-1. When the defrosting of the indoor unit 2a-1 is performed, the remote controller 4 according to the fourth embodiment has the remaining capacity of “25” in the operating capacity of the indoor unit 2b-1, and thus the operating capacity of the indoor unit 2b-1 is “ Control is performed so as to increase from “25” to “50”. This control is realized by the remote controller 4 transmitting a control command (not shown) to the indoor unit 2b-1 through the indoor unit-remote control communication line 9.

  As described above, the air conditioner system 100 according to the fourth embodiment performs defrosting when the remote control 4 performs defrosting execution determination on the indoor units 2a-1 to 2b-2. Since the control signal for increasing the operation capability of the indoor units other than the indoor unit to be transmitted is individually transmitted to the indoor units other than the indoor unit that performs defrosting, it is possible to give the user a feeling of cold wind even if defrosting is started. Absent.

  In addition, the air conditioner concerning Embodiment 1-4 shows an example of the content of this invention, and it is also possible to combine with another another well-known technique, and does not deviate from the summary of this invention. Of course, it is possible to change the configuration such as omitting a part of the range.

  As described above, the present invention can be applied to an air conditioner, and in particular, in the case where an air conditioner with a matching unit setting coincides with an air conditioner with a unit number setting that does not match, a notification of a difference in unit setting is made. This is useful as an invention that can release the user from annoyance.

1a, 1b outdoor unit
2a-1, 2a-2, 2b-1, 2b-2 Indoor unit 3a-1, 3a-2, 3b-1, 3b-2 Defrost request signal 4 Remote control 5a, 5b Defrost preparation signal 6, 6a, 6b Defrost control signal
7a-1, 7a-2, 7b-1, 7b-2 Operating state signals 8a, 8b Outdoor unit-indoor unit communication line 9 Indoor unit-remote control communication line 100 Air conditioner system

Claims (4)

An air conditioner system comprising a plurality of outdoor units, one or a plurality of indoor units connected to each of the outdoor units, and a remote controller for controlling the operation of each indoor unit,
Each indoor unit transmits operation state information including the operation capability of each indoor unit and the continuous operation time of each indoor unit, and a defrost request signal indicating a defrosting start request to the remote controller,
When the remote controller receives the defrost request signal, the defrost request is based on the operation capability and the continuous operation time included in the operation state information, and the operation capability required of the air conditioner system. An air conditioner system that performs a defrosting execution determination as to whether or not to cause a defrosting operation to be performed by an indoor unit that is a signal transmission source. An air conditioner system comprising a plurality of outdoor units, one or a plurality of indoor units connected to each of the outdoor units, and a remote controller for controlling the operation of each indoor unit,
Each indoor unit transmits operating state information including the operation capability of each indoor unit, temperature information of the indoor unit, and continuous operation time to the remote controller,
In the remote controller, the operation state information transmitted from each indoor unit is recorded,
The remote controller, based on the operation capability, the temperature information, and the continuous operation time included in the recorded operation state information, and the operation capability required for the air conditioner system, An air conditioner system that performs a defrosting execution determination as to whether or not to perform a defrosting operation. In the remote controller, in addition to the operation state information, time information when defrosting was performed in the past is recorded,
The air conditioner system according to claim 2, wherein the remote controller performs the defrosting execution determination based on the recorded operation state information and the time information.   When the remote controller performs the defrosting control of the indoor unit as a result of performing the defrosting execution determination, the remote controller transmits a control signal for increasing the operation capability of the indoor units other than the indoor unit that executes the defrosting control to the room that executes the defrosting control. The air conditioner system according to any one of claims 1 to 3, wherein the air conditioner system is individually transmitted to indoor units other than the unit.

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