JPWO2004079273A1 - Data transfer method - Google Patents

Abstract

The present invention provides a data exchange method that can be applied to monitoring of outdoor units of different models. The first information (A1b) is a part provided in the outdoor unit (10b), and is information about an object whose situation should be grasped. The monitor (20) inputs the first information (A1b) in step (S22). The operator of the monitor (20) selects a target whose situation is to be grasped from the first information (A1b), and requests information indicating the status of the target. In step (S24), the monitor (20) outputs the second request (Q2). The outdoor unit (10b) outputs the second information (A2) as information indicating the status of the selected target. The operator of the monitor (20) can grasp the status of the outdoor unit (10b), especially the status of the target selected based on the first information (A1b).

Description

  The present invention relates to a technique for exchanging data, and can be used, for example, when monitoring the condition of an outdoor unit of an air conditioner from the outside.

Conventionally, for example, in an air conditioner in which an indoor unit and an outdoor unit are connected by a transmission line, a technique has been proposed in which a data read / write device is connected to a communication line to thereby receive information on the indoor unit. Such a technique is introduced in, for example, Patent Document 1.
: JP 2002-310489 A

  However, the outdoor unit of an air conditioner differs in the type and number of components, for example, sensors and actuators, whose conditions should be grasped for each model. Therefore, in the device for monitoring the condition of the outdoor unit, it is necessary to operate different software for each model. Therefore, as new models increased, it was necessary to develop new monitoring software.

An object of the present invention is to solve such a problem, and provide a data transmission / reception method that can be applied to monitoring outdoor units of different models.
In the first aspect of the data exchange method according to the present invention, first information (A1b) is transmitted from the first device (10b) to the second device (20) (S14), and based on the first information. The second information (A2) request (Q2) is output (S24) from the second device to the first device, and the first device responds to the request for the second information from the first device. The second information is transmitted to the two devices (S16). The first information includes information about a target that is a component of the first device and whose status should be grasped, and the second information indicates the status of the target.
According to the first aspect of the method for exchanging data according to the present invention, the information about the object whose situation is to be grasped is informed to the second device in advance, so even if there is a difference in the target with which the first device is provided, There is no need to newly develop software for the second device.
A second aspect of the data exchange method according to the present invention is the first aspect, wherein the second information request (Q2) is made for the target selected based on the first information (A1b). .
According to the second aspect of the data transfer method according to the present invention, the operator of the second device grasps the status of the first device, particularly the status of the target selected based on the first information. Can do.
In the first aspect and the second aspect of the data exchange method according to the present invention, preferably the request for the first information (A1b) from the second device (20) to the first device (10b) ( Q1) is output (S21), and the first information or abnormality information (A1a) is transmitted from the first device to the second device in response to the request for the first information (S13, S14). . The abnormality information is transmitted when the request for the first information is not normal (S12, S13), and the first information is transmitted when the request for the first information is normal (S12, S14). )
More preferably, when the abnormality information is transmitted from the first device (10b) to the second device (20), the request (Q2) of the second information is not output (S23).
Preferably, the first information (A1b) includes information on the type and number of the objects.
More preferably, the first device is an outdoor unit of an air conditioner, and the first information includes information on the number of sensors and actuators.
Preferably, the sensor includes at least one of a pressure sensor and a thermistor.
Preferably, the actuator includes at least one of a compressor, a fan, an evaporation valve, a four-way valve, a crankcase heater, and an electromagnetic valve.
Preferably, the information (Q2) of the second information requests the second information about the object selected from the sensor and the actuator.
Preferably, the second information (A2) includes data of the sensor.
Preferably, the second information (A2) includes data of the actuator.
Preferably, the second device (20) displays the status of the selected object.
According to this desirable mode, the operator of the second device can grasp the status of the first device, especially the status of the selected target.
The objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description and the accompanying drawings.

FIG. 1 is a block diagram showing a connection relationship in which the data exchange method according to the present invention can be adopted.
FIG. 2 is a flowchart showing a data exchange method according to the present invention together with data exchange.

例えば異常情報Ａ１ａは１バイトのアスキーデータ“ＯＸ１５”（Ｘは所定の１６進数）及び１バイトのチェックサムデータＢＣＣを含んでいる。ここではチェックサムデータＢＣＣの値は“ＯＸＥＡ”となっている。
表２に室外機１０ｂから送信される送信データの構造を例示する。

例えば送信データはいずれも１バイトの“Ｄ”コマンド、サブコマンド、データ長と、室外機が備えるメモリ、例えばＲＡＭから読み出される２０バイトのＲＡＭデータと、データの続きの有無を示す１ビットのデータと、１バイトのチェックサムデータＢＣＣを含んでいる。
“Ｄ”コマンドはモニタ２０と室外機１０ｂとの間で授受されるデータであって、室外機１０ｂの状況の把握に関連する情報である必要はない。一方、サブコマンド及びＲＡＭデータは、室外機１０ｂの状況を把握すべき対象（例えば室外機１０ｂが備える部品）についての情報である。またデータ長は送信データの長さを示し、送信データをモニタ２０が正しく認識するために用いられる。
表３にサブコマンドの内容を例示する。

サブコマンドは２０バイトのＲＡＭデータの内容の区分を示す。具体的にはＲＡＭデータのうち、アドレス“ＯＸ００”から始まる１０バイトのデータがモニタデータ情報であることを、アドレス“ＯＸ１＊”（＊は任意の１６進数）から始まる２バイトのデータがセンサデータであることを、アドレス“ＯＸ２＊”から始まる８バイトのデータがアクチュエータデータであることを、それぞれ指定する。
送信データが第１情報Ａ１ｂである場合には、ＲＡＭデータとしてモニタデータ情報のみが含まれ、センサデータやアクチュエータデータは含まれない。
表４にＲＡＭデータの内容を例示する。

ＲＡＭデータのうちモニタデータ情報は、室外機１０ｂが備えるセンサ、インバータ駆動の圧縮機（表中で“ＩＮＶ”と表記）、インバータを用いずに駆動する圧縮機（表中で“ＳＴＤ”と表記）、ファン、蒸発弁（表中で“ＥＶ”と表記）、四路弁、クランクケースヒータ、電磁弁の各々の個数、並びに室外機１０ｂが対応できる室内機の台数（表中で“対応室内台数”と表記）及び室外機１０ｂに実際に接続されている室内機の台数（表中で“接続室内台数”と表記）を有している。これらの個数並びに台数は、いずれも１バイトのデータとして表される。
アクチュエータデータでは、インバータの運転周波数（表中で“ＩＮＶ周波数”と表記）に１バイトを、インバータを用いずに駆動する圧縮機の採否に１ビットを（表中で“ＳＴＤ圧縮機”と表記）、ファンステップ（回転数）に１バイトを、蒸発弁の開度（表中で“ＥＶ開度”と表記）に２バイトを、四路弁の切り替え（表中で“四路切”と表記）に１ビットを、クランクケースヒータの動作の有無に１ビットを、電磁弁の動作の有無に１ビットを、それぞれ割り当てている。例えばインバータの運転周波数やファンステップはｕｎｓｉｇｎｅｄ ｃｈａｒ形式で、蒸発弁の開度はｕｎｓｉｇｎｅｄ ｓｈｏｒｔ形式で、それぞれ表される。
センサデータは２バイトが割り当てられている。センサデータは例えば１０倍のｉｎｔ形式で表現される。例えば圧力センサについてのデータはｋｇ／ｃｍ^２を単位として、サーミスタについてのデータは℃を単位として、表される。
送信データが第１情報Ａ１ｂである場合には、これがモニタデータ情報、即ち室外機１０ｂにおいて備えられる部品であって、状況を把握すべき対象についての情報を含む。
図２に戻り、モニタ２０はステップＳ２２において異常情報Ａ１ａ及び第１情報Ａ１ｂのいずれか一方を入力する。そして入力した情報が異常情報Ａ１ａであればモニタ２０の動作は終了し、第１情報Ａ１ｂであればステップＳ２４に進む。モニタ２０の動作は終了した場合、改めてステップＳ２１から動作をやり直すことができる。この場合、室外機１０ｂとモニタ２０との接続関係を確認してからステップＳ２１を実行する事が望ましい。
さて、モニタ２０において第１情報Ａ１ｂが入力されれば、モニタ２０の操作者は第１情報Ａ１ｂに基づいて、例えばＲＡＭデータの中に含まれていたモニタデータ情報から状況を把握すべき対象を選択して、当該対象の状況を示す情報を要求する。
具体的にはステップＳ２４において、モニタ２０は第２要求Ｑ２を出力する。第２要求Ｑ２は、第１情報Ａ１ｂに基づいて、例えば選択された対象についての、状況を示す情報である第２情報Ａ２を出力させる要求である。室外機１０ｂはステップＳ１５によって第２要求Ｑ２を入力する。そして室外機１０ｂは第２要求Ｑ２に対応して、ステップＳ１６において第２情報Ａ２を出力する。
表５及び表６に、それぞれセンサデータ及びアクチュエータデータの内容を例示する。

センサデータは一つのセンサについて２バイトの長さを有する。表４に示されるモニタデータ情報を有する第１情報Ａ１ｂに基づいて、センサの個数を選択することにより、第２要求Ｑ２においてセンサ個数Ｎｓが指定される。これに対応して、第２情報Ａ２として表２に示される送信データが出力される。この場合、第２情報Ａ２としての送信データにおいて、そのＲＡＭデータには２・Ｎｓバイトのセンサデータが含まれアクチュエータデータは含まれない。
あるいは第２要求Ｑ２においてアクチュエータ（インバータ駆動の圧縮機、ファン、蒸発弁、四路弁、クランクケースヒータ）の種類毎にアクチュエータの個数を設定することもできる。これにより、状況を取得するアクチュエータを選択することができる。例えばインバータ駆動の圧縮機の個数Ｎｉと、蒸発弁の個数Ｎｅとを第２要求Ｑ２において指定した場合には、これに対応して第２情報たる送信データが出力される。この場合、ＲＡＭデータには（Ｎｉ＋２・Ｎｅ）バイトのデータとして、Ｎｉ個の圧縮機のインバータ周波数と、Ｎｅ個の蒸発弁の開度とが含まれ、センサデータは含まれない。
但し、第２情報Ａ２においてはモニタデータ情報を含む必要がないので、送信データとしてＲＡＭデータに準備されているデータ長（ここでは２０バイト）を越えない限り、センサデータとアクチュエータデータとを併せて第２要求Ｑ２において要求することができる。
モニタ２０はステップＳ２５において第２情報Ａ２を入力し、ステップＳ２６においてその内容を表示する。これにより、モニタ２０の操作者は、室外機１０ｂの状況、なかでも、第１情報Ａ１ｂに基づいて選択した対象についての状況を把握することができる。
以上のようにして、状況を把握すべき対象の選択が可能であるので、室外機１０ｂについてセンサの数やアクチュエータの数など、対象に相違（例えば対象の個数の相違）があっても、新たにモニタ用のソフトウェアを開発する必要がない。例えばモニタ２０において一度に監視できる対象の個数に上限があっても、状況を示す情報を複数回得ることにより、監視できる対象を増加させることができる。
この発明は詳細に説明されたが、上記した説明は、すべての局面において、例示であって、この発明がそれに限定されるものではない。例示されていない無数の変形例が、この発明の範囲から外れることなく想定され得るものと解される。FIG. 1 is a block diagram showing a connection relationship in which the data exchange method according to the present invention can be adopted. The air conditioner 10 includes an indoor unit 10a and an outdoor unit 10b. And the monitor 20 which monitors the condition of the outdoor unit 10b from the outside is connected to the outdoor unit 10b. The monitor 20 can employ a personal computer, for example. And the condition of the outdoor unit 10b is monitored by operating predetermined software.
FIG. 2 is a flowchart showing a data exchange method according to the present invention together with data exchange. The flowchart on the left half of the broken line shows the operation of the outdoor unit 10b, and the flowchart on the right half of the broken line shows the operation of the monitor 20.
First, the monitor 20 outputs the first request Q1 in step S21. The outdoor unit 10b inputs the first request Q1 in step S11. The first request Q1 is a request for outputting first information A1b described later from the outdoor unit 10b.
However, the outdoor unit 10b and the monitor 20 may not be normally connected, for example. Therefore, first, the outdoor unit 10b determines whether or not the first request Q1 is normal in step S12. If not normal, it will progress to Step S13 and outdoor unit 10b will output abnormal information A1a. If normal, the process proceeds to step S14, and the outdoor unit 10b outputs the first information A1b.
Table 1 illustrates the contents of the abnormality information A1a.

For example, the abnormality information A1a includes 1-byte ASCII data “OX15” (X is a predetermined hexadecimal number) and 1-byte checksum data BCC. Here, the value of the checksum data BCC is “OXEA”.
Table 2 illustrates a structure of transmission data transmitted from the outdoor unit 10b.

For example, each of the transmission data is a 1-byte “D” command, a subcommand, a data length, a memory provided in the outdoor unit, for example, 20-byte RAM data read from the RAM, and 1-bit data indicating whether data is continued. And 1-byte checksum data BCC.
The “D” command is data exchanged between the monitor 20 and the outdoor unit 10b, and need not be information related to grasping the status of the outdoor unit 10b. On the other hand, the subcommand and the RAM data are information on a target (for example, a part included in the outdoor unit 10b) for which the status of the outdoor unit 10b should be grasped. The data length indicates the length of the transmission data, and is used for the monitor 20 to correctly recognize the transmission data.
Table 3 shows the contents of the subcommand.

The subcommand indicates the division of the contents of 20-byte RAM data. Specifically, of the RAM data, 10-byte data starting from the address “OX00” is monitor data information, and 2-byte data starting from the address “OX1 *” (* is an arbitrary hexadecimal number) is sensor data. That the 8-byte data starting from the address “OX2 *” is actuator data.
When the transmission data is the first information A1b, only monitor data information is included as RAM data, and sensor data and actuator data are not included.
Table 4 illustrates the contents of the RAM data.

Among RAM data, monitor data information includes a sensor provided in the outdoor unit 10b, an inverter-driven compressor (indicated as “INV” in the table), and a compressor driven without using an inverter (indicated as “STD” in the table). ), Fans, evaporation valves (indicated as “EV” in the table), four-way valves, crankcase heaters, solenoid valves, and the number of indoor units that the outdoor unit 10b can handle (in the table, “corresponding room” And the number of indoor units actually connected to the outdoor unit 10b (denoted as “number of connected rooms” in the table). These numbers and numbers are both represented as 1-byte data.
In the actuator data, 1 byte is indicated for the operating frequency of the inverter (indicated as “INV frequency” in the table), and 1 bit is indicated as “STD compressor” in the table for whether or not the compressor is driven without using the inverter. ), 1 byte for the fan step (rotation speed), 2 bytes for the opening of the evaporation valve (shown as “EV opening” in the table), and 4 way valve switching (“4 way off” in the table) 1 bit is assigned to the notation), 1 bit is assigned to the operation of the crankcase heater, and 1 bit is assigned to the operation of the solenoid valve. For example, the operating frequency and fan step of the inverter are represented in unsigned char format, and the opening of the evaporation valve is represented in unsigned short format.
Two bytes are allocated to the sensor data. The sensor data is expressed in, for example, 10 times int format. For example, the data for the pressure sensor is expressed in kg / cm ² and the data for the thermistor is expressed in ° C.
When the transmission data is the first information A1b, this is monitor data information, that is, a component provided in the outdoor unit 10b, and includes information on a target whose situation should be grasped.
Returning to FIG. 2, the monitor 20 inputs either the abnormality information A1a or the first information A1b in step S22. If the input information is abnormal information A1a, the operation of the monitor 20 ends. If the input information is first information A1b, the process proceeds to step S24. When the operation of the monitor 20 is completed, the operation can be restarted from step S21. In this case, it is desirable to execute step S21 after confirming the connection relationship between the outdoor unit 10b and the monitor 20.
When the first information A1b is input to the monitor 20, the operator of the monitor 20 selects a target whose situation should be grasped based on the first information A1b, for example, from the monitor data information included in the RAM data. Select to request information indicating the status of the subject.
Specifically, in step S24, the monitor 20 outputs the second request Q2. The second request Q2 is a request for outputting, for example, the second information A2, which is information indicating the status of the selected target, based on the first information A1b. The outdoor unit 10b inputs the second request Q2 in step S15. Then, the outdoor unit 10b outputs the second information A2 in step S16 in response to the second request Q2.
Tables 5 and 6 illustrate the contents of sensor data and actuator data, respectively.

The sensor data has a length of 2 bytes for one sensor. By selecting the number of sensors based on the first information A1b having the monitor data information shown in Table 4, the sensor number Ns is designated in the second request Q2. In response to this, the transmission data shown in Table 2 is output as the second information A2. In this case, in the transmission data as the second information A2, the RAM data includes 2 · Ns bytes of sensor data and does not include actuator data.
Alternatively, the number of actuators can be set for each type of actuator (inverter-driven compressor, fan, evaporation valve, four-way valve, crankcase heater) in the second requirement Q2. Thereby, the actuator which acquires a condition can be selected. For example, when the number Ni of inverter-driven compressors and the number Ne of evaporation valves are specified in the second request Q2, transmission data as second information is output correspondingly. In this case, the RAM data includes (Ni + 2 · Ne) byte data including the inverter frequency of the Ni compressors and the opening degree of the Ne evaporation valves, and does not include the sensor data.
However, since it is not necessary to include the monitor data information in the second information A2, the sensor data and the actuator data are combined unless the data length (20 bytes here) prepared in the RAM data as the transmission data is exceeded. This can be requested in the second request Q2.
The monitor 20 inputs the second information A2 in step S25, and displays the contents in step S26. Thereby, the operator of the monitor 20 can grasp the status of the outdoor unit 10b, particularly the status of the target selected based on the first information A1b.
As described above, since it is possible to select a target whose situation should be grasped, even if there is a difference in the target such as the number of sensors or the number of actuators in the outdoor unit 10b (for example, a difference in the number of targets), a new There is no need to develop monitoring software. For example, even if there is an upper limit on the number of objects that can be monitored at a time on the monitor 20, the number of objects that can be monitored can be increased by obtaining information indicating the situation multiple times.
Although the present invention has been described in detail, the above description is illustrative in all aspects, and the present invention is not limited thereto. It is understood that countless variations that are not illustrated can be envisaged without departing from the scope of the present invention.

Claims (12)

The first information (A1b) is transmitted from the first device (10b) to the second device (20) (S14),
Based on the first information, the second information (A2) request (Q2) is output (S24) from the second device to the first device,
In response to the request for the second information, the second information is transmitted from the first device to the second device (S16),
The first information includes information about an object that is a part of the first device and whose status should be grasped,
The method for exchanging data, wherein the second information indicates the status of the object. The method for exchanging data according to claim 1, wherein a request (Q2) for the second information is made for the object selected based on the first information (A1b). A request (Q1) of the first information (A1b) is output from the second device (20) to the first device (10b) (S21),
In response to the request for the first information, the first information or the abnormality information (A1a) is transmitted from the first device to the second device (S13, S14),
The abnormality information is transmitted when the request for the first information is not normal (S12, S13),
The method of exchanging data according to any one of claims 1 and 2, wherein the first information is transmitted when the request for the first information is normal (S12, S14). . When the abnormality information is transmitted from the first device (10b) to the second device (20), the request (Q2) for the second information is not output (S23), How to exchange data described in the section. The data transmission / reception method according to any one of claims 1 to 4, wherein the first information (A1b) includes information on a type and the number of the objects. The first device is an outdoor unit of an air conditioner,
6. The data exchange method according to claim 5, wherein the first information includes information on the number of sensors and actuators. The data transmission / reception method according to claim 6, wherein the sensor includes at least one of a pressure sensor and a thermistor. 8. The actuator according to claim 6, wherein the actuator includes at least one of a compressor, a fan, an evaporation valve, a four-way valve, a crankcase heater, and an electromagnetic valve. Data exchange method. The information (Q2) of the second information requests the second information about the object selected from the sensor and the actuator, according to any one of claims 6 to 8. Data exchange method. The data transmission / reception method according to claim 9, wherein the second information (A2) includes data of the sensor. The data transmission / reception method according to any one of claims 9 and 10, wherein the second information (A2) includes data of the actuator. 12. The data transmission / reception method according to claim 1, wherein the second device (20) displays the status of the selected target.

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