JPH01252846A - Data transmission method for thermal component - Google Patents

Abstract

PURPOSE:To make it possible to receive and transmit data in dual directions, by selecting either of two transmission formats automatically when equipment of a new model provided with the two transmission formats is connected to another equipment which can receive and transmit data only with one of the two transmission formats. CONSTITUTION:A power line 3 and a signal line 5 are connected on the both sides of indoor equipment 1 and outdoor equipment 2 through photo TRIACs 7 and 8. A power line 4 and a signal line 5 are connected to photo couplers 9, 12 parallelly in reverse direction. In the case that the indoor equipment 1 is a new model provided with two transmission versions, say, both V1.0 and V2.0 while the outdoor equipment 2 is an old model provided with a single transmission version of V1.0 or a new model provided with two transmission versions of both V1.0 and V2.0, the transmission from the outdoor equipment 2 to the indoor equipment 1 is carried out by only V1.0 or V2.0 or interchangeably carried out by V2.1 or V1.0, thereby deciding the transmission version. Then, when the indoor equipment 1 is an old model provided with a single transmission version of V1.0 while the outdoor equipment 2 is a new model provided with the transmission versions of both V1.0 and V2.0, the indoor equipment 1 tries to receive data by V1.0. When the reception is established, it is decided that the subsequent transmission version is determined to be V1.0.

Description

[Detailed Description of the Invention] <Field of Application of Industry-F> This invention relates to data transmission for thermal equipment, which is applied to thermal equipment that transmits and receives data bidirectionally, such as an indoor unit and an outdoor unit in an air conditioner. Regarding the method.

<Conventional technology> Conventionally, thermal equipment that transmits and receives data in both directions is
There is one without as shown in Figure 8 (Japanese Unexamined Patent Publication No. 62-5234
No. 6). In this thermal equipment, an indoor unit A and an outdoor unit B of an air conditioner are connected by two power lines 81 and one signal line 82. Then, the AC power source 83 taken into the indoor unit A is supplied to the outdoor unit B via the power line 81,
This power is supplied to a compressor 86 via a power rectifier 84 and a power transistor monocall 85. Further, rectifying elements 87a, 8 are connected between both poles of the power line 81 on the indoor unit side.
7b are connected in opposite directions, and rectifying elements 88a and 88b are connected in opposite directions between both poles of the power line 81 on the outdoor unit side. Then, one end of the signal line 82 is connected to the connection point of the rectifying elements 87a and 87b on the indoor unit side via a resistor 90, a receiving photocoupler 91, and a transmitting photocoupler 92, and the rectifying element 88a on the outdoor unit side, The other end of the signal line 82 is connected to the connection point of the signal line 88b via a resistor 93, a transmitting photocoupler 94, and a receiving photocoupler 95.

The photocouplers 91 and 92 on the indoor unit side are controlled by a communication control circuit 98 that receives signals from the operation input changeover switch 96 and the air temperature detection element 97, and the photocouplers 94 and 95 on the outdoor unit side are controlled by the air temperature detection element 97. It is controlled by a communication control circuit 100 which receives signals from 99 as input. Data is exchanged with the communication control circuits 98 and 100 via a power line 81 and a signal line 82.

<Problems to be Solved by the Invention> By the way, in the conventional air conditioner described above, indoor unit A and outdoor unit B have the same transmission format, and data is sent and received using this transmission format. . Therefore, if the transmission format is changed due to a model change, etc., there is a problem that transmission and reception between the old model and the new model becomes impossible and compatibility is lost.

Therefore, when changing the transmission format due to a model change, etc., the new model should be equipped with two transmission formats: the old model's transmission format and a new transmission format with expanded commands. It is conceivable to enable data transmission between both old and new models. However, even in this case, there is a problem in that the user must select the transmission format depending on the model of the other party, which is troublesome.

Therefore, an object of the present invention is that when a new model that has these two transmission formats is connected to a model (for example, an old model) that can only transmit and receive data using one of the transmission formats, 1. When the new models mentioned above are connected, the new transmission format is automatically selected and data can be sent and received in both directions. The object of the present invention is to provide a data transmission method for thermal equipment that can perform the following steps.

<Means for Solving the Problems> In order to achieve the above object, the present invention provides a first thermal device having a first transmission format and a second transmission format;
A data transmission method for a thermal device that bidirectionally transmits and receives data to and from a second thermal device that has one or both of the first and second transmission formats. , the i-th thermal device attempts to receive data from the second thermal device using the second transmission format a predetermined number of times, and if reception is successful, the i-th thermal device determines the second transmission format as the subsequent transmission format; On the other hand, if the reception is not successful, an attempt is made to receive the data from the second thermal device a predetermined number of times using the first transmission format, and the reception is successful and the received data has a predetermined flag. If you are
If the first transmission format is determined to be the subsequent transmission format, and the received data does not have a predetermined flag, the first transmission format is not determined to be the subsequent transmission format, and the first transmission format is determined to be the subsequent transmission format. The present invention is characterized in that the transmission format is determined by attempting to receive data from the second thermal device in the second transmission format.

<Operation> The first thermal device attempts to receive data from the second thermal device a predetermined number of times using the second transmission format, and if reception is successful, determines the second transmission format as the subsequent transmission format. , if the reception is not successful, attempts to receive the data from the second thermal device a predetermined number of times using the first transmission format, and the reception is successful, and the received data has a predetermined flag. In case,
If the first transmission format is determined to be the subsequent transmission format, and the received data does not have a predetermined flag, do not determine the first transmission format to be the subsequent transmission format. , attempts to receive data from the second thermal device again using the second transmission format to determine the transmission format. Therefore, data can be sent and received bidirectionally between the first thermal device and the second thermal device by automatically selecting the transmission former node from 1 to 1.
Thermal equipment is the first and second transmission former! In the case where the second transmission format is automatically selected with priority, it is possible to receive data in both directions.

<Example> Hereinafter, the present invention will be explained in detail with reference to illustrated embodiments.

FIG. 1 is a circuit diagram showing a connection between an indoor unit and an outdoor unit of an air conditioner that bidirectionally transmits and receives data using the thermal equipment transmission method of this embodiment.

In FIG. 1, 1 is an indoor unit as a first thermal device, and 2 is an outdoor unit as a second thermal device. The indoor unit 1 and the outdoor unit 2 are connected to each other by two power lines 3.4 and one signal line 5. Then, the AC power source 6 introduced into the indoor unit is supplied to the outdoor unit 2 via the power line 3.4. In addition, the power line 3
The power line 4 and the signal line 5 are connected to the indoor unit 1 side and the outdoor unit 2 side via phototriacs 7 and 8 for transmission, respectively, and the power line 4 and the signal line 5 are connected to the indoor unit 1 side and the outdoor unit 2 side. On the second side, they are connected via photocouplers 9.10, which are connected in parallel in opposite directions, and photocouplers 11.12, which are also connected in parallel in opposite directions.

The phototriac 7 and photocoupler 9.10 on the indoor unit side are controlled by the CPU 14, and the phototriac 8 and photocoupler 11.12 on the outdoor unit side
is controlled by the CPU 15.

A power line of 3°·t is connected between the CPUs 14 and 15.
Data is exchanged with each other via the signal line 5.

-1- Distribution indoor unit 1 is transmission version 1.0 (Vl, 0)
This is a new model with two transmission versions: and transmission version 2.1 (V2.I), and the outdoor unit 2 has Vt,
Old model with O only transmission version or Vt
, is a new model with both O and v2.1 transmission virginity.

The above transmission version V2. 1, data is transmitted in the transmission format shown in FIG. That is, the indoor unit 1 receives 1 packet of 57-bit data from the outdoor unit 2, and when the reception is completed, sends 1 packet of 57-bit data to the outdoor unit 2 with an 8-bit space (0 level) left open. The outdoor unit 2 repeats transmission at 130-bit intervals regardless of the presence or absence of transmission from the indoor unit 1.

The bit configuration of this l packet is as shown in FIG. Here, “STX” is the start bit, “DAD
” or “SAD” is the destination address, “A”, “B”
", ..., "J" is control information based on flag bits, "
P" is vertical parity, "operation" and operand are bits that give a control command as a pair, the operand part is a code, and the operand part is a code or flag bit. Also, "BCC" is a block code,
“ETX” is a stop bit.

When the indoor unit 1 is turned on, it starts in the receiving state.

After receiving "STX", 56-bit data is input. This data is sent LSB (least significant bit) first.

On the other hand, in the transmission version V160, data is transmitted in the transmission format shown in FIG. That is,
Indoor unit 1 receives and receives 24-bit data sent from outdoor unit 2, and when the reception is completed, it fills an 8-bit space (
0 level) and transmit 32-bit data.

Outdoor unit 2 receives 8 regardless of the presence or absence of transmission from indoor unit 1.
Repeat transmission at 0-bit intervals.

The 24-pit data transmitted from the outdoor unit 2 to the indoor unit 2 includes control information "A" based on a start bit and a spare bit "13". The above "ST", "A", and 'B' each have a 4-bit configuration as shown in FIG.
This control information "A" is the Fd flag indicating defrost,
It consists of a Pds flag representing defrost standby, a FIIls flag representing that the compressor is operating, and a FII flag representing the transmission version.

If this F+a flag is “Pi”, it means that it has both transmission versions of Vt, O and V2.1, and “0”.
” indicates that only the transmission versions of Vt and O are included.

On the other hand, the 32-bit data sent from indoor unit 1 to outdoor unit 2 includes a start bit "ST" and control information "C" and "D".
, “E” and their inverted bit “C”.

It is composed of "D" and "E". Each of these data has a 4-bit configuration as shown in FIG. This control information "C" has a flag that instructs the operation mode and a flag that instructs fan operation, and control information "D" has a Pc flag that instructs compressor operation and a Pch flag that instructs power-up of the compressor. Has a flag. Further, the control information "E" is data indicating whether the time is shortened or not.

As mentioned above, transmission versions v1.0 and V2.1
Since the transmission formats are different between the two, it is necessary to determine the transmission version before transmitting and receiving data. Now, indoor unit l is Vl.

This is a new model that has both transmission versions of Vl, 0 and V2.1, and outdoor unit 2 is either an old model that has transmission versions of only Vl, O, or a new model that has transmission versions of both Vl, 0 and V2゜l. Therefore, the transmission from the outdoor unit 2 to the indoor unit 1 is ■Vl.

0 only, ■■2.1 only, ■V2.1 and V
There are three ways to perform t and O alternately. And the seventh
The transmission version is determined by a method as shown in the example shown in the figure.

First, after turning on the power and resetting it, reception attempts using V2°l are repeated up to 6 times. And Figure 7 (
As shown in a), if reception is established during six reception attempts, at that point the subsequent transmission version is changed to V2.
Set to 1. However, if reception is not established during the six reception attempts by V2゜l, as shown in Fig. 7(b), reception attempts by vi and o are made in the seventh and eighth reception attempts. conduct. If reception is established between these two receptions, refer to Figure 5 to determine whether the outdoor unit is a model that only has Vt and O or a model that has both V2.1 and Vl and O. Check the F11 flag of the control information "A" shown. Then, if the F-flag is “O”,
Since the outdoor unit is a model having only Vl,0, the subsequent transmission version is determined to be Vl,0. On the other hand, the seventh
As shown in figure (c), if the FIl flag is "V", the outdoor unit is a model that has both transmission versions of V2.1 and Vl,0, so the transmission version is not determined, so after the 9th reception , try again to receive by V2.l 6
Repeat times. If reception is established during that time, the subsequent transmission version is determined to be V2.1 at that point. This again V2. If reception is not established during six receptions by l, it is determined that there is an abnormality, and abnormality processing is performed.

Next, if the indoor unit 1 is an old model that has a transmission version of only Vt, O, and the outdoor unit 2 is a new model that has a transmission version of both Vl, 0 and v2.1, then
As shown in d), the indoor unit 1 attempts reception using Vl,0, and when reception is successful, the subsequent transmission version is determined to be Vl,0.

In this way, there are two transmission versions with different transmission formats: ■2.1 and a new model with vl, 0, and a new model with vl, 0.
The transmission version is automatically determined before data transmission between an old model that has a transmission version of V2゜1 and a new model that has a transmission version of both V2゜1 and Vl,0. There is no need for the user to select the transmission version, and when new models are connected, the transmission version is automatically changed to V2. Since it is determined to be 1, data can be sent and received using the new transmission version.

In the above embodiment, if the indoor unit is a new model, the indoor unit is V2. After repeating reception at l six times, Vl, 0
17, so that the outdoor unit is a new model, send V2.1 twice, and ■1.0 twice in the same order. , the number of repetitions is not limited to this.

<Effects of the Invention> As is clear from the above, in the data transmission method for thermal equipment of the present invention, a first thermal equipment having a first transmission format and a second transmission format can transmit data using the first and second transmission formats. The data from the second thermal device having one or both of the transmission formats is transmitted to the second thermal device.
A predetermined number of receptions are attempted using the transmission format, and if reception is successful, the second transmission format is determined as the subsequent transmission format, while if reception is not successful, the first transmission format is used. When an attempt is made to receive the data from the second thermal device a predetermined number of times, and the reception is successful j7, and the received data j7 sets a predetermined flag a, the first transmission - format is determined as the subsequent transmission format, and if the data received in - does not have a predetermined flag,
Since the first transmission format is not determined as the subsequent transmission format, try again to receive data from the second thermal unit number using the second transmission format to determine the transmission format. The transmission format can be automatically selected between the thermal device and the second thermal device to transmit and receive data bidirectionally, and when the second thermal device has the first and second transmission formats, The second transmission format is automatically selected with priority, and data can be transmitted and received in both directions.

[Brief explanation of the drawing]

Figure 1 is a circuit diagram for connecting an indoor unit and an outdoor unit of an air conditioner that performs two-way data transmission and reception using an embodiment of the data transmission system for thermal equipment of the present invention. A diagram showing the transmission format of transmission version V2゜! in the embodiment, Fig. 3 is a diagram showing the bit structure of one packet of data transmitted in 2.1 above, and Fig. 4 is a transmission bar in the above embodiment. Figures 5 and 6 are diagrams showing the bit structure of the data transmitted in V1.0, and Figure 7 is a diagram showing the transmission format of the above-mentioned V1.0. Figure 8 is a diagram explaining the data transmission pattern for connecting the indoor unit and outdoor unit of an air conditioner that performs two-way data transmission and reception using the conventional data transmission method for thermal equipment (also a circuit diagram). l...indoor unit, 2...outdoor unit, 7, 8--transmission phototriac, 9, IO...
Receiving photocoupler, 14.15...CPU0 patent
Applicant: Daikin Industries, Ltd. Representative: Patent Attorney The above person is Rikishi Nago A+, Q Figure 5

Claims (1)

[Claims] (1) Between a first thermal device having a first transmission format and a second transmission format and a second thermal device having one or both of the first and second transmission formats. A data transmission method for a thermal device that transmits and receives data in both directions, wherein the first thermal device attempts to receive data from the second thermal device a predetermined number of times using the second transmission format. , if the reception is successful, the second transmission format is determined as the subsequent transmission format, and if the reception is not successful, the data from the second thermal device is received a predetermined number of times using the first transmission format. If reception is successful and the received data has a predetermined flag, the first transmission format is determined as the subsequent transmission format, and the received data has a predetermined flag. If not, the first transmission format is not determined as the subsequent transmission format, and the transmission format is determined by attempting to receive data from the second thermal device again using the second transmission format. A data transmission method for thermal equipment that is characterized by: