JP4882608B2 - Air conditioning system and data transmission method in air conditioning system - Google Patents

Description

  The present invention relates to an air conditioning system and a data transmission method in the air conditioning system. For example, the air conditioning system includes at least two or more outdoor units and at least one indoor unit, and data in the air conditioning system. It can be applied to a transmission method.

  Conventionally, there is an air conditioning system including at least two or more outdoor units and at least one or more indoor units (for example, Patent Document 1). In the air conditioning system, each indoor unit and each outdoor unit are connected by a refrigerant pipe. In the air conditioning system, when a compressor or the like disposed in the outdoor unit is turned on and circulation supply of the refrigerant is started, the refrigerant is supplied to the plurality of indoor units via the refrigerant pipe.

  In the above air conditioning system, the outdoor unit may be classified into a main unit and a sub unit. Here, the main unit of the outdoor unit is an outdoor unit that supplies refrigerant and controls the operation of the sub unit of the outdoor unit and the operation of each indoor unit. On the other hand, the slave unit of the outdoor unit compresses the refrigerant based on the control from the master unit of the outdoor unit and does not control the operation of the indoor unit.

  Therefore, in the air conditioning system, the main unit of the outdoor unit and the sub unit of the outdoor unit, and the main unit of the outdoor unit and each indoor unit are connected via the communication lines. Therefore, data can be transmitted and received between the main unit of the outdoor unit and the sub unit of the outdoor unit and between the main unit of the outdoor unit and each indoor unit.

  In the air conditioning system having the above-described configuration, it is necessary to avoid connecting different types of outdoor units (hereinafter, this connection is referred to as erroneous connection) in order to prevent malfunction. Therefore, the following method has been adopted as a method for avoiding the erroneous connection.

  First, the base unit of the outdoor unit transmits data for confirming (discriminating) the model of the sub unit of the outdoor unit to the sub unit of the outdoor unit. The slave unit of the outdoor unit that has received the data transmits response data including information indicating the model of the own unit to the master unit of the outdoor unit. The base unit of the outdoor unit that has received the response data determines the model of the slave unit of the outdoor unit based on the response data.

  By the above method, the presence or absence of the erroneous connection can be detected, and as a result, the erroneous connection can be avoided.

Japanese Patent Application No. 10-180748

  By the way, in the outdoor unit to be developed and manufactured in the future, if the model is renewed, it becomes necessary to increase the data length of data transmitted by the outdoor unit. This is because an outdoor unit to be developed and manufactured in the future has more functions than a conventional model, so that a lot of information needs to be transmitted to other units at once.

  Here, the main unit of the outdoor unit is the above-mentioned new model (the new model is a model capable of transmitting and receiving not only data having a conventional data length but also data having a longer data length). Yes, the outdoor unit has a conventional model (the conventional model cannot receive data having a longer data length than the new model transmits / receives, but transmits / receives data having a shorter conventional data length) Suppose that the above-mentioned method for avoiding erroneous connection is adopted.

  In such a case, the new master unit of the outdoor unit is data having a data length longer than the data length of the data that can be received by the conventional outdoor unit (the data is the model of the slave unit of the outdoor unit). Is transmitted to the outdoor unit slave unit.

  However, since the outdoor unit is a conventional model, the data transmitted from the outdoor unit is discarded. This is because the data transmitted from the main unit of the outdoor unit is longer than the reception buffer capability of the sub unit of the outdoor unit.

  Accordingly, the child unit of the outdoor unit naturally does not return the response data to the parent unit of the outdoor unit. Therefore, there arises a problem that the main unit of the outdoor unit cannot determine the presence or absence of the erroneous connection (in this case, the main unit of the outdoor unit is connected to the sub unit of the outdoor unit via the communication line). It will be recognized as not connected).

  Therefore, the present invention connects an outdoor unit of a different model via a communication line even when the base unit of the new outdoor unit and the slave unit of the conventional outdoor unit are connected. It is an object of the present invention to provide an air conditioning system and a data transmission method in the air conditioning system that can determine whether or not there is an erroneous connection.

In order to achieve the above object, the air conditioning system according to claim 1 according to the present invention is connected to at least one or more indoor units (30), and the indoor units (30) via a refrigerant pipe. In the air conditioning system (100) including at least two or more outdoor units (10, 20), one of the outdoor units ( 20 ) is a first model whose maximum data length that can be received is the first data length. , And the second model whose maximum data length that can be received is the second data length that is longer than the first data length, and the other outdoor unit (10) is the second model a is, and, before the air-conditioning control for the indoor unit (30), the one outdoor unit with respect to (20), in order to confirm the model of the one of the outdoor unit (20), said first First data (D1) having a data length of 1 A first transmission unit for transmitting (2), said sent from the first data (D1) the one outdoor unit which receives the (20), the information indicating the model of the one of the outdoor unit (20) first receiving section for receiving response data (D2) comprising a (3), based on the information indicating the model, the data length of data to be transmitted to the one outdoor unit (20), the second A first control unit (1) that can be changed to the data length of the second model, and the first control unit (1) is a model that can be grasped from information indicating the model in the second model. In some cases, the first model is a model that can change the data length of data to be transmitted to the one outdoor unit (20) to the second data length and can be grasped from the information indicating the model. In this case, the data to be transmitted to the one outdoor unit (20) The data length is not changed .

Moreover, the air conditioning system of Claim 2 which concerns on this invention is an air conditioning system of Claim 1, Comprising: The said 1st transmission part (2) is a model which can be grasped | ascertained from the information which shows the said model Is the second model, the second data (D3) having the second data length changed by the first control unit (1) is transmitted after the first data transmission. It transmits with respect to one outdoor unit (20) .

Moreover, the air conditioning system of Claim 3 which concerns on this invention is an air conditioning system of Claim 1, Comprising: When the model which can be grasped | ascertained from the information which shows the said model is the said 1st model , the first transmission unit (2) is from the one of the outdoor unit (20), the response data (D2) including information indicating that the second model, the first receiver (3 ) until the reception at the to one of the outdoor unit (20), the other data having a first data length SL before to confirm the model of the one of the outdoor unit (20), said first Continue sending after sending data .

An air conditioning system according to a fourth aspect of the present invention is the air conditioning system according to any one of the first to third aspects, wherein the one outdoor unit (20) is the second model. there are, and, before the air-conditioning control for the indoor unit (30), a second receiving unit for receiving transmission data that is transmitted (D1, D3) from the other of the outdoor unit (10) and (4) , Having a predetermined threshold value that is larger than the first data length and smaller than the second data length, and is capable of comparing a magnitude relationship between the data length of the transmission data and the predetermined threshold value. As a result of the comparison between the control unit (5) and the second control unit (5), when the data length of the transmission data is equal to or less than the predetermined threshold, the other outdoor unit (10) Transmitting third data having the first data length; Wherein when the data length of transmission data is larger than the predetermined threshold, the respect to the other of the outdoor unit (10), a second transmission unit for transmitting a fourth data having a second data length and (6), it is equipped.

The air conditioning system according to claim 5 of the present invention includes at least one indoor unit (30), and at least two or more outdoor units (10, 10) connected to the indoor unit (30) via a refrigerant pipe. 20), in the air conditioning system (200) comprising, one of the outdoor unit (20), before performing the air-conditioning control for the indoor unit (30), that are sent from the other of the outdoor unit (10) A receiving unit (4) for receiving transmission data (MD1, MD2), and a predetermined threshold value that is larger than the first data length and smaller than the second data length larger than the first data , A control unit (5) capable of comparing the magnitude relationship between the data length of transmission data and the predetermined threshold value, and as a result of the comparison in the control unit (5), the data length of the transmission data is the predetermined threshold value. In the following cases: Serial sending the other of the outdoor unit of the first data having a first data length with respect to (10) (MD4), wherein when the data length of transmission data is larger than the predetermined threshold, the other respect of the outdoor unit (10), the second transmission unit that transmits data (MD3) with the second data length and (6), wherein the other of the outdoor unit (10) includes first One of the model and the second model, the one outdoor unit (20) is the second model, and the first model can receive data having a data length equal to or less than the first data length. The second model is a model that can receive data having a data length equal to or less than the second data length .

A data transmission method in an air conditioning system according to claim 6 of the present invention includes at least one indoor unit (30) and at least two outdoor units connected to the indoor unit (30) via a refrigerant pipe. A data transmission method in the air conditioning system (100) that regulates data transmission between the outdoor units (10, 20) in an air conditioning system including a unit (10, 20), wherein one of the outdoor units ( 20 ) of the first model in which the maximum data length that can be received is the first data length, and the second model in which the maximum data length that can be received is the second data length that is longer than the first data length. The other outdoor unit (10) is the second model, and (A) before performing the air conditioning control on the indoor unit (30), the one outdoor unit (20) against, the Square outdoor unit to confirm the model of (20) in a step (step S1) of sending the first data (D1) having a first data length, (B) the first data (D1 (1) receiving response data (D2) including information indicating the model of the one outdoor unit (20) transmitted from the one outdoor unit (20) having received (1)) (C) When the model that can be grasped from the information indicating the model is the second model, the data length of data transmitted to the one outdoor unit (20) is changed to the second data length, When the model that can be grasped from the information indicating the model is the first model, the step of not changing the data length of the data transmitted to the one outdoor unit (20) is executed .

Moreover, the data transmission method in the air conditioning system of Claim 7 which concerns on this invention is a data transmission method in the air conditioning system of Claim 6, Comprising: Said other outdoor unit (10) is (D ) When the model that can be grasped from the information indicating the model is the second model, the second data (D3) having the second data length changed in the step (C) is stored in the second model (D3). After the data 1 is transmitted, transmission to the one outdoor unit (20) (step S4) is further executed .

Moreover, the data transmission method in the air conditioning system of Claim 8 which concerns on this invention is a data transmission method in the air conditioning system of Claim 6, Comprising: Said other outdoor unit (10) is (E ) When the model that can be grasped from the information indicating the model is the first model, the response data (D2) including information indicating the second model from the one outdoor unit (20) Until the other data having the first data length for confirming the model of the one outdoor unit (20) is sent to the one outdoor unit (20) until the first data is received. The step (step S3 → step S1) of continuing transmission after transmission is further executed .

A data transmission method in an air conditioning system according to claim 9 of the present invention is the data transmission method in an air conditioning system according to any one of claims 6 to 8, wherein the one outdoor unit (20) is a second type and the (a) the air conditioning control before the indoor unit (30), the transmission data (MD1, MD2) that will be transmitted from the other of the outdoor unit (10) Receiving (step S11), and (b) comparing the magnitude relationship between the data length of the transmission data and a predetermined threshold value that is larger than the first data length and smaller than the second data length (step S12). ) and, (c) the step of (b) results, wherein when the data length of transmission data is less than or equal to the predetermined threshold value has a first data length to the other of the outdoor unit (10) First 3 (MD4) is transmitted (step S13), and when the data length of the transmission data is greater than the predetermined threshold , the second data length is sent to the other outdoor unit (10). The step of transmitting the fourth data (MD3) having (step S14) is executed .

According to a tenth aspect of the present invention, there is provided a data transmission method in an air conditioning system according to the present invention, wherein at least one indoor unit (30) and at least two or more indoor units (30) connected to the indoor unit (30) via a refrigerant pipe. In the air conditioning system (200) including the outdoor units (10, 20), a data transmission method in the air conditioning system that regulates data transmission between the outdoor units, wherein one of the outdoor units (20) , and (a) receiving the front air-conditioning control of the indoor unit (30), the other of the outdoor unit transmission data sent from (10) (MD1, MD2) (step S11), (B) the transmission and the data length of data, larger than the first data length, the step of comparing the magnitude relation between the first data second data length is smaller than a predetermined threshold greater than the length (step S1 ) And, (C) the step of (B) result, wherein when the data length of transmission data is less than or equal to the predetermined threshold value has a first data length to the other of the outdoor unit (10) It sends first data (MD4) (step S13), and wherein when the data length of transmission data is larger than the predetermined threshold, the other of the outdoor unit with respect to (10), said second data and a step (step S14) of transmitting the second data having a length (MD3), run, the other of the outdoor unit (10) is in one of the first type and second type, the one The outdoor unit (20) is a second model, the one model is a model that can receive data having a data length equal to or less than the first data length, and the second model has the second data length. It is a model that can receive data of the following data length .

According to the first and sixth aspects of the present invention, in one outdoor unit, the maximum data length that can be received is the first model, and the maximum data length that can be received is the first data. One of the second models having the second data length longer than the length, and the other outdoor unit is the second model. The other outdoor unit receives the first data having the first data length for confirming the type of the one outdoor unit with respect to the one outdoor unit before performing the air conditioning control on the indoor unit. The response data including the information indicating the model of the one outdoor unit transmitted from the one outdoor unit that transmitted and received the first data is received. When the other outdoor unit is the second model that can be grasped from the information indicating the model, the data length of the data transmitted to the one outdoor unit is changed to the second data length, When the model that can be grasped from the information indicating the model is the first model, the data length of the data to be transmitted to one outdoor unit is not changed.

Therefore, one of the outdoor unit is normally be first and second type, the one of the outdoor unit can receive the first data. Therefore, of course, if a second type in which one outdoor unit can receive relatively long data, when one of the outdoor unit is the first type also possible to transmit the response data to the other of the outdoor unit The other outdoor unit can determine whether or not there is an erroneous connection between the two outdoor units.

Further, based on the information indicating the model included in the response data, the data length of the data transmitted to one of the outdoor units can be changed to the second data length that is longer than the first data length. Accordingly, after the reception of the response data, when one of the outdoor unit is a second type is a transmission of data having a second data length which the one of the outdoor unit can receive, it is the other of the outdoor unit . In other words, after receiving the response data, according to the model of the one of the outdoor unit, the other of the outdoor unit, thereby enabling more efficient data transfer.

Further, in the invention according to claim 2, 7, the other of the outdoor unit, if the model can be grasped from the information indicating the model was second models, the second data having a second data length Then, after the first data transmission, the data is transmitted to one outdoor unit.

Therefore, for example, when both outdoor units are a second model that can receive data having a relatively long data length (longer than the first data length), more efficient transmission / reception of data after receiving response data, It can be carried out between the two outdoor units.

Further, in the inventions according to claims 3 and 8, when the other outdoor unit is the first model that can be grasped from the information indicating the model, it is the second model from the one outdoor unit. Until the response data including the information indicating is received, the other data having the first data length for confirming the model of the one outdoor unit is transmitted to the one outdoor unit after the first data is transmitted. Keep doing.

Thus, for example, the response data being transmitted to the communication line affected by noise from the outside, when the error information indicating the model is generated, subsequently, the response data includes information indicating the correct type, the other The outdoor unit can receive data from one outdoor unit that has received other data. Further, in the case one of the outdoor unit is truly model different from the other of the outdoor unit (in the case of erroneous connection), by replacing one of the outdoor unit of the same type as the other of the outdoor unit, Immediately after the replacement, the other outdoor unit can determine that the erroneous connection has been eliminated.

In the inventions according to claims 4 and 9, one of the outdoor units is the second model. Then, the transmission data transmitted from the other outdoor unit is received, and the magnitude relationship between the data length of the transmission data and a predetermined threshold value that is larger than the first data length and smaller than the second data length is compared. Then, when the data length of the transmission data is equal to or smaller than the predetermined threshold, the third data having the first data length is transmitted to the other outdoor unit, and the data length of the transmission data is smaller than the predetermined threshold. If larger, the fourth data having the second data length is transmitted to the other outdoor unit.

Therefore, one outdoor unit is a second model that can receive data having a relatively long data length according to the data length of the transmission data transmitted from the other outdoor unit (in other words, the other outdoor unit can receive data having a relatively long data length). Depending on whether the first model can receive data having a relatively short data length), the length of data transmitted to the other outdoor unit can be changed.

In the inventions according to claims 5 and 10, one outdoor unit receives transmission data transmitted from the other outdoor unit, and is a second larger than the first data and larger than the first data. The predetermined threshold value is smaller than the data length, and the magnitude relation between the data length of the transmission data and the predetermined threshold value is compared. Then, when the data length of the transmission data is equal to or less than a predetermined threshold, one outdoor unit transmits the first data having the first data length to the other outdoor unit, and the data length of the transmission data Is larger than the predetermined threshold value, the second data having the second data length is transmitted to the other outdoor unit. Here, the other outdoor unit is either the first model or the second model, and the one outdoor unit is the second model. The first model is a model that can receive data having a data length equal to or less than the first data length, and the second model is a model that can receive data having a data length equal to or less than the second data length.

Therefore, according to the data length of the transmission data transmitted from the other outdoor unit, the data length of the data transmitted (returned) from one outdoor unit can be changed. Therefore, it is possible to prevent the transmitted (reply) data from being discarded by the receiving unit of the other outdoor unit.

  Hereinafter, the present invention will be specifically described with reference to the drawings showing embodiments thereof.

<Embodiment 1>
FIG. 1 is a diagram showing a configuration of an air conditioning system according to the present embodiment and an internal configuration of each outdoor unit.

  As shown in FIG. 1, the air conditioning system 100 according to the present embodiment includes two outdoor units 10 and 20, a plurality of indoor units 30, and communication lines 40 and 50.

  Here, the outdoor unit is classified into an outdoor unit (hereinafter simply referred to as a master unit) 10 serving as a master unit and an outdoor unit (hereinafter simply referred to as a slave unit) 20 serving as a slave unit. Here, in the present embodiment, it is assumed that the parent device 10 is a new model. In the present embodiment, the new model is a model having more functions than the conventional model, and not only data having a data length of data that can be received by the conventional model, but also data longer than this. It has the ability to receive long data (because it is necessary to send and receive a lot of information to and from other devices at once).

  The master unit 10 is an outdoor unit that supplies refrigerant and controls the operation of the slave unit 20 and the operation (air conditioning) of each indoor unit 30. On the other hand, the subunit | mobile_unit 20 compresses a refrigerant | coolant based on control from the main | base station 10, and does not control operation | movement (air conditioning) of the indoor unit 30. FIG.

  As shown in FIG. 1, in the air conditioning system 100, a communication line 40 is disposed between the parent device 10 and the child device 20. Further, the base unit 10 and each indoor unit 30 are connected via a communication line 50. Therefore, data can be transmitted and received between the master unit 10 and the slave unit 20 and between the master unit 10 and each indoor unit 30, and each outdoor unit 10, 20 and each indoor unit 30 has information flowing through the communication lines 40, 50. (Data) can be monitored. Note that no communication line is provided between the slave unit 20 and each outdoor unit 30. Therefore, direct data transmission / reception between the slave unit 20 and each outdoor unit 30 is not performed.

  Here, although only one slave unit 20 is shown in FIG. 1, two or more slave units 20 may be provided. The outdoor units 10 and 20 and the indoor unit 30 are connected by a single refrigerant pipe (not shown). In the air conditioning system 100, when a compressor (not shown) or the like disposed in each of the outdoor units 10 and 20 is turned on and circulation of the refrigerant is started, the refrigerant pipe is connected. The refrigerant is supplied to the plurality of indoor units 30.

  Next, the configuration inside the outdoor units 10 and 20 will be described.

  As shown in FIG. 1, a control unit 1, a transmission unit 2, and a reception unit 3 are arranged in the base unit 10. Further, in the slave unit 20, a receiving unit 4, a control unit 5, and a transmitting unit 6 are disposed. Although not shown in FIG. 1, the outdoor units 10 and 20 are also provided with a compressor, a fan, and the like as drive units, and store sensors and programs that can measure a predetermined physical quantity. The memory | storage part etc. which can be provided are also arrange | positioned.

  In the base unit 10, the transmission unit 2 can transmit the data sent from the control unit 1 to the slave unit 20 and each indoor unit 30 via the communication lines 40 and 50. Moreover, the transmission part 2 transmits the 1st data D1 with respect to the subunit | mobile_unit 20 via the communication line 40, before performing the air-conditioning control with respect to the indoor unit 30. FIG. Here, the said 1st data is data for confirming the model of the subunit | mobile_unit 20, and has 1st data length. The first data length is the maximum data length that can be received by the receiving unit provided in the conventional model, and is shorter than the second data length described later. As an example, the first data length is about 20 bytes.

  The receiving unit 3 can receive data from the slave unit 20 and each indoor unit 30 transmitted via the communication lines 40 and 50, and can transfer the received data to the control unit 1. The receiving unit 3 receives response data D2 transmitted via the communication line 40. Here, the response data D2 is data transmitted from the slave 20 that has received the first data, and is reply data to the first data. The response data D2 includes information indicating the model of the child device 20.

  The control unit 1 performs control related to refrigerant circulation. The control unit 1 also performs processing such as creation of data to be transmitted and monitoring of received data. Further, the control unit 1 transmits the response data D2 to the slave unit 20 that has transmitted the response data D2 after receiving the response data D2, based on information indicating the model included in the response data D2 received by the reception unit 3. The data length of the data (including second data or other data to be described later) can be changed to be longer than the first data length.

  For example, when the model that can be grasped from the information indicating the model is the same as that of the master unit (that is, when the slave unit 20 is also the new model), the control unit 1 sets the data length of the second data D3. The second data length (for example, about 23 bytes) longer than the first data length is changed. And the transmission part 2 transmits the 2nd data D3 which has the said 2nd data length with respect to the subunit | mobile_unit 20. FIG. Here, the second data length is the maximum data length that can be received by the receiving unit provided in the new model.

  On the other hand, when the model that can be grasped from the information indicating the model is different from the parent device (that is, when the child device 20 is a conventional model), the control unit 1 does not change the data length, and does not change the data length. 2 is controlled as follows. That is, until the reception unit 3 receives response data D2 including information indicating that it is the same model as the parent device 10 from the child device 20, the model of the child device 20 is confirmed with respect to the child device 20. Therefore, the control unit 1 controls the transmission unit 2 so that the transmission unit 2 continues to transmit other data having the first data length.

  Next, the internal structure of the subunit | mobile_unit 20 is demonstrated.

  First, an internal configuration of the slave unit 20 when the slave unit 20 is a conventional model will be described.

  The receiving unit 4 can receive data transmitted from the parent device 10 via the communication line 40 and transfer the received data to the control unit 5. Further, the receiving unit 4 can receive only data having a data length equal to or less than the first data length because of the buffer capacity of the receiving unit 4, and data having a data length longer than the first data length. Can not receive.

  The control unit 5 performs control related to refrigerant circulation. Further, the control unit 5 performs monitoring of data received by the reception unit 4, generation of data transmitted from the transmission unit 6, and the like. Further, when the reception unit 4 receives the first data D1 (including the other data), the control unit 5 creates the response data D2 including information indicating the model of the own device. Here, the response data D2 has a first data length.

  The transmission unit 6 can transmit the data sent from the control unit 5 to the parent device 10 via the communication line 40. Here, when the data sent from the control unit 5 is the response data D2 having the first data length, the transmission unit 6 sends the response data D2 to the base unit 10 via the communication line 40. Send.

  Next, an internal configuration of the child device 20 when the child device 20 is a new model will be described.

  The receiving unit 4 can receive data transmitted from the parent device 10 via the communication line 40 and transfer the received data to the control unit 5. The receiving unit 4 can receive only data having a data length equal to or less than the second data length because of the buffer capacity of the receiving unit 4. That is, not only data having the first data length but also data having a second data length longer than this can be received.

  The control unit 5 performs control related to refrigerant circulation. Further, the control unit 5 performs monitoring of data received by the reception unit 4, generation of data transmitted from the transmission unit 6, and the like. Further, when the reception unit 4 receives the first data D1 (including the other data), the control unit 5 creates the response data D2 including information indicating the model of the own device. Here, the response data D2 has a second data length.

  The transmission unit 6 can transmit the data sent from the control unit 5 to the parent device 10 via the communication line 40. Here, when the data sent from the control unit 5 is the response data D2 having the second data length, the response data D2 having the second data length is transmitted via the communication line 40. Transmit to the base unit 10.

  Next, the internal configuration of the slave unit 20 when the slave unit 20 is a new model and the invention is applied will be described.

  The receiving unit 4 can receive data transmitted from the parent device 10 via the communication line 40 and transfer the received data to the control unit 5. The receiving unit 4 can receive only data having a data length equal to or less than the second data length because of the buffer capacity of the receiving unit 4. That is, not only data having the first data length but also data having a second data length longer than this can be received.

  The control unit 5 performs control related to refrigerant circulation. Further, the control unit 5 performs monitoring of data received by the reception unit 4, generation of data transmitted from the transmission unit 6, and the like. Further, when the reception unit 4 receives the first data D1 (including the other data), the control unit 5 creates the response data D2 including information indicating the model of the own device.

  Further, the control unit 5 has a predetermined threshold, and includes data received by the receiving unit 4 (including the first data D1 and the other data, and data transmitted from the base unit 10 in addition to these data). (Including) data length and the predetermined threshold value are compared. As a result of the comparison, when the data length is equal to or smaller than the predetermined threshold, the control unit 5 creates third data having a relatively short third data length (for example, the first data length). On the other hand, when the data length is larger than the predetermined threshold, the control unit 5 creates fourth data having a relatively long fourth data length (for example, the second data length).

  The predetermined threshold can be set to an arbitrary value. However, the predetermined threshold value needs to be larger than the relatively short data length (that is, the first data length) included in the data that can be received by the conventional model, and is relatively large that the data that can be received by the new model. It needs to be smaller than the long data length (that is, the second data length).

  In addition, since the data length of the third data needs to be a data length that can be received by the conventional model, it may be equal to or less than the first data length (from the viewpoint of efficient data transfer, the first data length Preferably the same length as). On the other hand, since the data length of the fourth data needs to be a data length that can be received by the new model, it may be less than or equal to the second data length (from the viewpoint of efficient data transfer, the second data length Preferably the same length as).

  The transmission unit 6 can transmit the data sent from the control unit 5 to the parent device 10 via the communication line 40. When the data created by the control unit 5 is the response data D2, the third data, or the fourth data, the data is transmitted to the parent device 10 via the communication line 40. The response data D2 is data that is created when the first data having the first data length is received. Here, the first data length is smaller than the predetermined threshold value, and the second data length is larger than the predetermined threshold value. Therefore, it can be understood that the data length of the response data D2 is the third data having a relatively short data length (for example, the first data length).

  Next, a data transmission method for defining data transmission between the parent device 10 and the child device 20 in the air conditioning system 100 according to the present embodiment will be described.

  First, the operation of base unit 10 will be described using the flowchart shown in FIG.

  Turn on the power of the base unit 10. Thereafter, the transmission unit 2 of the parent device 10 transmits the first data D1 to the child device 20 via the communication line 40 before performing the air conditioning control on the indoor unit 30 (step S1). Here, as described above, the first data D1 is data for confirming the model of the slave unit 20, and has the first data length (data length that can be received by the conventional model). The first data D1 is generated by the control unit 1.

  Next, the receiving unit 3 receives the response data D2 transmitted from the handset 20 that has received the first data D1 via the communication line 40 (step S2). Here, the response data D2 includes information indicating the model of the slave unit 20.

  Next, the control unit 1 determines whether or not to change the data length of the data to be transmitted to the child device 20 to the first data length or more based on the information indicating the model (step S3). .

  As a result of step S3, when the model that can be grasped from the information indicating the model is the same as the model of the parent device 10 (that is, when the child device 20 is a new model), the first data length longer than the first data length is set. The control unit 1 generates second data D3 having a data length of 2. After receiving the response data D2, the transmission unit 2 transmits the second data D3 having the second data length to the slave unit 20 (step S4).

  On the other hand, as a result of step S3, when the model that can be grasped from the information indicating the model is different from the model of the master unit 10 (that is, when the slave unit 20 is a conventional model), it is transmitted from the slave unit 20. The other data is continuously generated until the model that can be grasped from the information indicating the model included in the response data D2 is the same as the model of the parent device 10. And the transmission part 2 continues transmitting the said other data with respect to the subunit | mobile_unit 20 via the communication line 40 (step S3-> step S1). Here, as described above, the other data is data for confirming the model of the slave unit 20 and has the first data length.

  For example, the response data D2 being transmitted through the communication line 40 may be affected by noise from the outside. When affected by the noise, an error may occur in the information indicating the model of the child device 20 included in the response data D2. In this case, as described above, by continuing to transmit other data for confirming the model of the slave unit 20, the correct model can be selected at any timing (that is, at a timing not affected by noise). The base unit 10 can receive the response data D2 including the indicated information.

  When the handset 20 is truly a different model from the base unit 10 (in the case of the erroneous connection), the handset 20 is replaced with the same model as the base unit 10, thereby Immediately after the replacement of 20, master device 10 can perform the operation of step S4.

  In addition, since it is not a misconnection when it can transfer to step S4, even if it operates the air conditioning system comprised by the said main | base station 10 and the subunit | mobile_unit 20 after that, a malfunction does not generate | occur | produce.

  Next, operation | movement of the subunit | mobile_unit 20 is demonstrated.

  First, the operation of the handset 20 that is a conventional model will be described.

  The power supply of the subunit | mobile_unit 20 is turned on. Thereafter, before the air conditioning control of the indoor unit 30, the slave unit 20 (more specifically, the receiving unit 4) receives the first data D <b> 1 transmitted from the master unit 10. Here, since the first data D1 has the first data length, the first data D1 can be normally received even if the handset 20 is a conventional model.

  Thereafter, the control unit 5 generates response data D2 in order to respond to the first data D1 received by the receiving unit 4. Here, the response data D2 includes information indicating the model of the handset 20. In this case, since the handset 20 is a conventional model, the response data D2 having the first data length is generated.

  Then, the transmission unit 6 transmits the response data D2 having the first data length to the parent device 10 via the communication line 40.

  Thereafter, since the handset 20 is a conventional model, the base unit 10 continues to transmit the other data described above until the handset 20 is replaced with a new model. The slave unit 20 continues to generate and transmit the response data D2 until the slave unit 20 is replaced with a new model. The operation of the new model slave unit 20 after replacement is the same as the following “operation of the new model slave unit 20” when “first data D1” is read as “other data”.

  Next, the operation of the handset 20 that is a new model will be described.

  The power supply of the subunit | mobile_unit 20 is turned on. Thereafter, before the air conditioning control of the indoor unit 30, the slave unit 20 (more specifically, the receiving unit 4) receives the first data D <b> 1 transmitted from the master unit 10. Here, since the first data D1 has the first data length, the handset 20 as a new model can naturally receive the first data D1 normally (that is, the handset 20 as a new model). Can receive data having the second data length, and the first data length is shorter than the second data length).

  Thereafter, the control unit 5 generates response data D2 in order to respond to the first data D1 received by the receiving unit 4. Here, the response data D2 includes information indicating the model of the handset 20. In this case, since the handset 20 is a new model, the response data D2 having the second data length is generated.

  Then, the transmission unit 6 transmits the response data D2 having the second data length to the parent device 10 via the communication line 40.

  Thereafter, since the slave unit 20 is a new model, the master unit 10 transmits the second data D3 when transmitting data to the slave unit 20 thereafter by the operation of step S4 in FIG. As described above, the second data D3 has a second data length that is longer than the first data length. On the other hand, since the subunit | mobile_unit 20 is a new model, the said 2nd data D3 can also be received normally. Thereafter, transmission / reception of the second data having the second data length is performed between the parent device 10 and the child device 20.

  Next, the operation of the slave unit 20 when the slave unit 20 is a new model and the invention is applied will be described with reference to the flowchart shown in FIG.

  The power supply of the subunit | mobile_unit 20 is turned on. Thereafter, before the air conditioning control of the indoor unit 30, the slave unit 20 (more specifically, the receiving unit 4) receives the first data D1 transmitted from the master unit 10 (step S11). Here, since the first data D1 has the first data length, the handset 20 as a new model can naturally receive the first data D1 normally (that is, the handset 20 as a new model). Can receive data having the second data length, and the first data length is shorter than the second data length).

  Thereafter, the control unit 5 generates response data D2 in order to respond to the first data D1 received by the receiving unit 4. Here, the response data D2 includes information indicating the model of the handset 20.

  Furthermore, the control unit 5 also performs the following process when generating the response data D2. That is, the magnitude relationship between the data length of the received first data D1 (that is, the first data length) and a predetermined threshold value preset in the control unit 5 is compared (step S12). As described above, an arbitrary value can be set as the predetermined threshold. However, the predetermined threshold value needs to be larger than a relatively short data length (for example, the first data length) included in data that can be received by the conventional model, and is relatively large that the new model can receive. It needs to be smaller than a long data length (for example, the second data length).

  When the data length is equal to or smaller than the predetermined threshold as a result of the comparison of the magnitude relationships, the control unit 5 has a third data length that is relatively short (same as the first data length). Create data. On the other hand, when the data length is larger than the predetermined threshold, the control unit 5 creates fourth data having a relatively long fourth data length (for example, the same as the second data length).

  As described above, since the data length of the third data needs to be a data length that can be received by the conventional model, it may be equal to or shorter than the first data length (from the viewpoint of efficient data transfer, It is desirable that the length is the same as the data length of 1). On the other hand, since the data length of the fourth data needs to be a data length that can be received by the new model, it may be equal to or shorter than the second data length (from the viewpoint of efficient data transfer, the second data length Preferably the same data length as In the following description, reference is made to the third data having the first data length and the fourth data having the second data length.

  In this case, since the first data D1 having the first data length is received, as a result of step S12, third data having the first data length is generated as the response data D2. Here, as described above, the response data D2 (third data) includes information indicating the model of the slave unit 20.

  After generating the response data D2, the transmission unit 6 transmits the response data D2 (third data) having the first data length to the base unit 10 via the communication line 40 (step S13).

  The base unit 10 that has received the response data D2 determines that the handset 20 is a new model through steps S2 and S3 in FIG. Accordingly, the base unit 10 thereafter transmits the second data D3 having the second data length to the handset 20 (step S4 in FIG. 2).

  The subunit | mobile_unit 20 (specifically receiving part 4) receives the said 2nd data D3 transmitted from the main | base station 10 (step S11). Here, since the second data D3 has the second data length, the handset 20 as a new model can normally receive the second data D3.

  Thereafter, the control unit 5 compares the magnitude relationship between the data length of the received second data D3 (that is, the second data length) and a predetermined threshold set in advance in the control unit 5 (step S12). Here, since the receiving unit 4 has received the second data D3 having the second data length, as a result of step S12, the control unit 5 generates fourth data having the second data length.

  Then, the transmission unit 6 transmits the fourth data having the second data length to the parent device 10 via the communication line 40.

  As described above, in the air conditioning system 100 according to the present embodiment, the master unit 10 checks the model of the slave unit 20 before performing the air conditioning control on the indoor unit 30. The first data D1 having the data length is transmitted. And based on the information which shows the model contained in the response data D2 returned from the subunit | mobile_unit 20, whether the data length of the data transmitted with respect to the subunit | mobile_unit 20 is changed more than 1st data length. Deciding.

  Therefore, since the data length of the first data D1 is the first data length, the slave device 20 can normally receive the first data D1 even if the slave device 20 is a conventional model. Therefore, not only when the child device 20 is a new model, but also when the child device 20 is a conventional model, the parent device 10 can normally determine whether there is an erroneous connection between the parent device 10 and the child device 20. Can do.

  Furthermore, since it is possible to change the data length of the data to be transmitted to the slave unit 20 based on the information indicating the model included in the response data D2, after the response data D2 is received. Data transmission / reception according to the model of the slave unit 20 can be performed between the master unit 10 and the slave unit 20.

  Further, in the air conditioning system 100 according to the present embodiment, when the model that can be grasped from the information indicating the model is the same as the model of the master unit 10, the master unit 10 is more than the first data length. The second data having a long second data length is transmitted to the slave unit 20.

  Therefore, when the master unit 10 and the slave unit 20 are new models, more efficient data transmission / reception (that is, more efficient data transmission / reception than the data having the first data length) after the response data D2 is received. Transmission / reception) can be performed between the parent device 10 and the child device 20.

  Further, in the air conditioning system 100 according to the present embodiment, when the model that can be grasped from the information indicating the model is different from the model of the master unit 10, the model that can be grasped from the information indicating the model is the parent device 10. The other data similar to the first data is continuously transmitted to the slave unit 20 until it becomes the same as the model of the unit 10.

  Therefore, for example, when the response data D2 being transmitted through the communication line 40 is affected by noise from the outside and an error occurs in the information indicating the model, after that (that is, when the influence of noise disappears), The base unit 10 can receive the response data D2 including information indicating the correct model from the slave unit 20 that has received other data. When the handset 20 is truly a different model from the base unit 10 (in the case of the erroneous connection), the handset 20 is replaced with the same model as the base unit 10, thereby Immediately after the replacement of 20, the master unit 10 can determine that the erroneous connection has been eliminated.

  In the air conditioning system 100 according to the present embodiment, the slave unit 20 compares the magnitude relationship between the data length of the received predetermined data and the predetermined threshold value. Then, when the data length is equal to or smaller than the predetermined threshold, the third data having the first data length is transmitted to the parent device 10, and when the data length is larger than the predetermined threshold, the parent device 10, the fourth data having the second data length is transmitted.

  Accordingly, the slave unit 20 transmits to the master unit 10 in accordance with the data length of the data transmitted from the master unit 10 (in other words, depending on whether the master unit 10 is a new model or a conventional model). The length of data to be changed can be changed.

<Embodiment 2>
In the first embodiment, reference has been made to the master unit 10 that can implement the flowchart of FIG. However, there is an air conditioning system 200 (this is an air conditioning system according to the present embodiment) composed of a parent device 60 described below and a child device 20 capable of realizing the flowchart shown in FIG. Also good. The structure of the air conditioning system 200 concerning this Embodiment is shown in FIG.

  In the parent device 60, the control unit 7 can generate predetermined data transmitted from the transmission unit 8, monitor the data received by the reception unit 9, and analyze the received data. Note that the parent device 60 according to the present embodiment does not perform control to change the data length of data to be transmitted to the child device 20 in accordance with the information indicating the model included in the response data D2.

  Moreover, the transmission part 8 can transmit data to the subunit | mobile_unit 20 or each indoor unit 30 via the communication lines 40 and 50. FIG. The receiving unit 9 can receive data from the slave unit 20 or each indoor unit 30 transmitted through the communication lines 40 and 50, and can transfer the received data to the control unit 7.

  Further, as described above, the slave unit 20 according to the present embodiment is the new model described above, and performs the operation shown in FIG. 3 described in the first embodiment. The other configuration of the air conditioning system 200 is the same as that of the air conditioning system 100 described in the first embodiment.

  The air conditioning system 200 performs the following operations.

  For example, before performing air-conditioning control on the indoor unit 30, the receiving unit 4 of the slave unit 20 receives predetermined data having a predetermined data length transmitted from the master unit 60 (step S11 in FIG. 3). The predetermined data may be data for confirming the model of the slave unit 20 or data issued for other purposes. In the following description, it is assumed that the predetermined data is data for confirming the model of the slave unit 20.

  Here, the predetermined data MD1 issued by the new model parent device 60 has a relatively long data length (for example, 23 bytes) that can be received by the new model parent device 60. On the other hand, the predetermined data MD2 issued by the parent device 60 of the conventional model has a relatively short data length (for example, 20 bytes) that can be received by the parent device 60 of the conventional model (the data of the predetermined data MD1). Length> data length of predetermined data MD2. In addition, since the subunit | mobile_unit 20 is a new model, both the said predetermined data MD1 and MD2 can be received normally (In other words, in the subunit | mobile_unit 20 which is a new model, the maximum value of the data length which the receiving part 4 can receive is the maximum value. The data length of the predetermined data MD1).

  Next, in order to respond to the predetermined data MD1 (or MD2) received by the receiving unit 4, the control unit 5 generates response data MD3 (or MD4). In the description here, the predetermined data MD1 (or MD2) is data for confirming the model of the child device 20. Therefore, the response data MD3 (or MD4) includes information indicating the model of the slave unit 20.

  Furthermore, the control unit 5 also performs the following process when generating the response data MD3 (or MD4). That is, the magnitude relationship between the data length of the received predetermined data MD1 (or MD2) and the predetermined threshold value preset in the control unit 5 is compared (step S12 in FIG. 3). As described above, an arbitrary value can be set as the predetermined threshold. However, the predetermined threshold needs to be larger than the relatively short data length of data that can be received by the conventional model, and needs to be smaller than the relatively long data length of the data length that can be received by the new model. .

  When the data length is equal to or smaller than a predetermined threshold as a result of the comparison of the magnitude relationships (for example, when the predetermined data MD2 is transmitted from the parent device 60), the control unit 5 has a relatively short data length (that is, Response data MD4 having a data length that can be received by the parent device 60, which is a conventional model, is created. On the other hand, when the data length is larger than the predetermined threshold (for example, when the predetermined data MD1 is transmitted from the parent device 60), the control unit 5 determines the relatively long data length (that is, the parent of the new model). Response data MD3 having a data length that can be received by the device 60 is created.

  As described above, the data length of the response data MD4 is equal to or less than the maximum data length that can be received by the conventional model (desirably, the maximum data length that can be received by the conventional model from the viewpoint of efficient data transfer). On the other hand, the data length of the response data MD3 is equal to or shorter than the data length that can be received by the new model (from the viewpoint of efficient data transfer, the maximum data length that can be received by the new model is desirable).

  As described above, the response data MD3 (or MD4) includes information indicating the model of the child device 20.

  Next, as a result of the comparison in step S12, when the data received by the receiving unit 4 is the predetermined data MD2, the transmitting unit 6 sends the response data MD4 to the parent device 60 via the communication line 40. Transmit (step S13 in FIG. 3). On the other hand, as a result of the comparison in step S12, if the data received by the receiving unit 4 is the predetermined data MD1, the transmitting unit 6 sends the response data MD3 to the parent device 60 via the communication line 40. It transmits to (step S14 in FIG. 3).

  As described above, in the air conditioning system 200 according to the present embodiment, the slave unit 20 compares the data lengths of the predetermined data MD1 and MD2 with the predetermined threshold value. When the data length is equal to or smaller than the predetermined threshold, data MD4 having a relatively short data length (below the maximum data length that can be received by the conventional model) is transmitted to the parent device 10. On the other hand, when the data length is larger than the predetermined threshold, a relatively long data length (below the maximum data length that can be received by the new model and longer than the relatively short data length) is transmitted to the base unit 10. To do.

  Therefore, since the data length of the data to be returned can be changed according to the data length of the predetermined data transmitted by the parent device 60, the returned data can be prevented from being discarded by the receiving unit 9 of the parent device 60.

  For example, when the parent device 60 transmits the data MD1 and MD2 for checking the model of the child device, the data length of the data can change according to the model of the parent device 60. However, the slave unit 20 according to the present embodiment can change the data length of the response data MD3 and MD4 according to the received data length (that is, according to the model of the master unit 60). Therefore, master device 60 can normally receive response data MD3 and MD4 from slave device 20, and can recognize (determine) information indicating the model of the slave device included in response data MD3 and MD4.

  In the first and second embodiments, the process of automatically setting the addresses in the outdoor units 10, 20, 60 and the indoor unit 30 may be performed prior to or after the process of confirming the model described above. (For example, Japanese Patent Application No. 2006-85903 and Japanese Patent Application No. 2006-64434).

It is a figure which shows the structure of the air conditioning system concerning Embodiment 1, and the internal structure of an outdoor unit. 3 is a flowchart for explaining an operation of the parent device according to the first embodiment. 5 is a flowchart for explaining the operation of the slave unit according to the first and second embodiments. It is a figure which shows the structure of the air conditioning system concerning Embodiment 2, and the internal structure of an outdoor unit.

Explanation of symbols

1, 7 (Master unit) Control unit 2, 8 (Master unit) Transmitter unit 3, 9 (Master unit) Receiver unit 4 (Slave unit) Receiver unit 5 (Slave unit) Control unit 6 (Slave unit) Transmitter unit 10, 60 Master unit 20 Slave unit 30 Indoor unit 40, 50 Communication line 100, 200 Air conditioning system D1 First data D2, MD3, MD4 Response data D3 Second data MD1, MD2 Predetermined data

Claims (10)

In an air conditioning system (100) including at least one or more indoor units (30), and at least two or more outdoor units (10, 20) connected to the indoor units (30) via a refrigerant pipe,
One of the outdoor units ( 20 )
One of the first model whose maximum data length that can be received is the first data length and the second model whose maximum data length that can be received is the second data length that is longer than the first data length. And
The other outdoor unit (10)
The second model, and
Before performing the air-conditioning control for the indoor unit (30), wherein to one of the outdoor unit (20), in order to confirm the model of the one of the outdoor unit (20), having a first data length A first transmission unit (2) for transmitting first data (D1);
The sent from the first data (D1) the one outdoor unit which receives the (20), a first for receiving response data (D2) including information indicating the model of the one of the outdoor unit (20) A receiver (3);
A first control unit (1) capable of changing a data length of data transmitted to the one outdoor unit (20) to the second data length based on information indicating the model; Have
The first control unit (1)
When the model that can be grasped from the information indicating the model is the second model, the data length of data transmitted to the one outdoor unit (20) is changed to the second data length, When the model that can be grasped from the information indicating the model is the first model, the data length of the data to be transmitted to the one outdoor unit (20) is not changed.
An air conditioning system characterized by that. The first transmitter (2)
When the model that can be grasped from the information indicating the model is the second model, the second data (D3) having the second data length changed by the first control unit (1) is stored. , Transmitting to the one outdoor unit (20) after transmitting the first data ,
The air conditioning system according to claim 1. When the model that can be grasped from the information indicating the model is the first model, the first transmitter (2)
Until the response data (D2) including information indicating the second model is received from the one outdoor unit (20) by the first receiving unit (3), the one outdoor unit ( against 20), the other data having a first data length SL before to confirm the model of the one of the outdoor unit (20), continues to transmit after transmitting the first data,
The air conditioning system according to claim 1 . The one outdoor unit (20)
The second model, and
Before performing the air-conditioning control for the indoor unit (30), a second receiving unit for receiving transmission data that is transmitted (D1, D3) from the other of the outdoor unit (10) and (4),
A second control that has a predetermined threshold that is larger than the first data length and smaller than the second data length, and that can compare a magnitude relationship between the data length of the transmission data and the predetermined threshold; Part (5),
As a result of the comparison in the second control unit (5), when the data length of the transmission data is equal to or less than the predetermined threshold , the first data length is set to the other outdoor unit (10). And transmitting the third data having the second data length to the other outdoor unit (10) when the data length of the transmission data is greater than the predetermined threshold. the second transmission unit that transmits data and (6), and includes,
The air conditioning system according to any one of claims 1 to 3, wherein In the air conditioning system (200) including at least one or more indoor units (30), and at least two or more outdoor units (10, 20) connected to the indoor units (30) via a refrigerant pipe,
One of the outdoor units (20)
Before performing the air-conditioning control for the indoor unit (30), receiving unit for receiving transmission data that is transmitted (MD1, MD2) from the other of the outdoor unit (10) and (4),
It has a predetermined threshold value that is larger than the first data length and smaller than the second data length that is larger than the first data, and compares the magnitude relationship between the data length of the transmission data and the predetermined threshold value A control unit (5) capable of
The comparison of the results in the control unit (5), wherein when the data length of transmission data is less than the predetermined threshold, the first having a first data length to the other of the outdoor unit (10) the transmit data (MD4), wherein when the data length of transmission data is larger than the predetermined threshold, the respect to the other of the outdoor unit (10), a second having a second data length A transmission unit (6) for transmitting data (MD3) ,
The other outdoor unit (10)
One of the first and second models,
The one outdoor unit (20)
The second model,
The first model is
A model capable of receiving data having a data length equal to or less than the first data length;
The second model is
A model capable of receiving data having a data length equal to or shorter than the second data length;
An air conditioning system characterized by that. The outdoor unit (10) in an air conditioning system including at least one or more indoor units (30) and at least two or more outdoor units (10, 20) connected to the indoor unit (30) via a refrigerant pipe. , 20), the data transmission method in the air conditioning system (100),
One of the outdoor units ( 20 )
One of the first model whose maximum data length that can be received is the first data length and the second model whose maximum data length that can be received is the second data length that is longer than the first data length. And
The other outdoor unit (10)
The second model,
(A) before performing the air-conditioning control for the indoor unit (30), wherein to one of the outdoor unit (20), in order to confirm the model of the one of the outdoor unit (20), said first data Transmitting the first data (D1) having a length (step S1);
(B) The response data (D2) including information indicating the model of the one outdoor unit (20) transmitted from the one outdoor unit (20) that has received the first data (D1) is received. Step (step S2);
(C) When the model that can be grasped from the information indicating the model is the second model, the data length of data transmitted to the one outdoor unit (20) is changed to the second data length. When the model that can be grasped from the information indicating the model is the first model, the step of changing the data length of the data to be transmitted to the one outdoor unit (20) is executed. ,
A data transmission method in an air conditioning system. The other outdoor unit (10)
(D) When the model that can be grasped from the information indicating the model is the second model, the second data (D3) having the second data length changed by the step (C) is obtained. the transmitted to one of the outdoor unit (20) after sending the first data (step S4), and further executes,
The data transmission method in the air conditioning system according to claim 6. The other outdoor unit (10)
(E) When the model that can be grasped from the information indicating the model is the first model, the response data including information indicating the second model is received from the one outdoor unit (20). D2) is received, the other data having the first data length for confirming the model of the one outdoor unit (20) with respect to the one outdoor unit (20), continue transmitting after data transmission, the step (step S3 → step S1), and further executes,
The data transmission method in the air conditioning system according to claim 6 . The one outdoor unit (20)
The second model, and
And (a) the prior air conditioning control of the indoor unit (30), the step of receiving transmission data that is transmitted (MD1, MD2) from the other of the outdoor unit (10) (step S11), and
(B) comparing the magnitude relationship between the data length of the transmission data and a predetermined threshold value that is larger than the first data length and smaller than the second data length (step S12);
(C) As a result of the step (b), when the data length of the transmission data is equal to or less than the predetermined threshold, the third data having the first data length with respect to the other outdoor unit (10) transmitting data (MD4) (step S13), and wherein when the data length of transmission data is larger than the predetermined threshold, the other of the outdoor unit with respect to (10), having a second data length Executing the step of transmitting the fourth data (MD3) (step S14);
A data transmission method in an air conditioning system according to any one of claims 6 to 8. The outdoor unit in the air conditioning system (200) including at least one or more indoor units (30) and at least two or more outdoor units (10, 20) connected to the indoor units (30) via a refrigerant pipe. A data transmission method in an air conditioning system that regulates data transmission between machines,
One of the outdoor units (20)
(A) the indoor unit in the air-conditioning control before (30), a step (step S11) of receiving transmission data that is transmitted (MD1, MD2) from the other of the outdoor unit (10),
(B) Comparing the magnitude relationship between the data length of the transmission data and a predetermined threshold value that is larger than the first data length and smaller than the second data length that is larger than the first data length (step S12). When,
(C) the step of (B) result, wherein when the data length of transmission data is less than the predetermined threshold, a first having the first data length to the other of the outdoor unit (10) transmitting data (MD4) (step S13), and wherein when the data length of transmission data is larger than the predetermined threshold, the other of the outdoor unit with respect to (10), having a second data length Executing the step of transmitting the second data (MD3) (step S14),
The other outdoor unit (10)
One of the first and second models,
The one outdoor unit (20)
Second model,
The one model is
A model capable of receiving data having a data length equal to or less than the first data length;
The second model is
A model capable of receiving data having a data length equal to or shorter than the second data length;
A data transmission method in an air conditioning system.

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