JPH0793746B2 - Control signal transmission system for thermal equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Field of Industrial Application> The present invention transmits data between a master station and a plurality of slave stations in a heat device such as an air conditioner and a water heater via one transmission path. The present invention relates to a control signal transmission system for thermal equipment.

<Prior Art> Conventionally, as a control signal transmission system for this kind of thermal equipment, there is one as shown in FIG. 4 (Japanese Patent Laid-Open No. 61-228246). The control signal transmission system for heat equipment is an outdoor unit 41 as a main station of an air conditioner and indoor units 42, 43 as slave stations and a remote controller 44 corresponding to the indoor unit.
45 is connected by one signal line 46. Then, polling is performed as shown in FIG. That is, the outdoor unit 41, which is the main control unit, first addresses the remote controller 44 with the control signal M1, and the contents operated by the remote controller 44 are controlled by the control signal M1.
Send it back as S1. Next, the remote control 45 addresses the control signal M2, and the content operated by the remote control 45 is returned as the control signal S2. Next, the addressed control signal M3 is transmitted to the indoor unit 42, and the indoor unit 42 returns a control signal S3 indicating the operating state of this unit. Next, the addressed control signal M4 is transmitted to the indoor unit 43, and the control signal S4 indicating the operating state of this unit from the indoor unit 43 is returned. In this way, the outdoor unit 41 has the indoor units 42, 43 and the remote controllers 44, 45.
A control signal is transmitted in a predetermined order to the indoor units 42 and 43 and the remote controllers 44 and 45 to reply to the outdoor unit 31 in response to the control signal. Therefore, when the control signal is transmitted and received between the outdoor unit 41 and one indoor unit or the remote controller, the other indoor unit or the remote controller does not transmit the control signal to the outdoor unit 41, so the signal line 46 Since a plurality of control signals are not output at the same time, there is no interference between the control signals, and the control signals can be transmitted and received reliably.

<Problems to be Solved by the Invention> However, in the above conventional control signal transmission system for thermal equipment, the outdoor unit 41 as the main station and the indoor units 42, 43 as remote stations and the remote controllers 44, 45 have a predetermined value. Since the data is sent and received sequentially in order, even if one of the slave stations cannot transmit or receive data due to power down or is not in the connected state, the master station always sends the data to that slave station. In addition, since data is always transmitted to slave stations that do not need to transmit data, there is a problem in that it takes more transmission time than necessary and data transmission efficiency is poor.

Therefore, an object of the present invention is that the master station always checks the number of connected slave stations and changes the data transmission / reception cycle depending on the number of connected units, thereby shortening the transmission / reception cycle time when the number of connected units is small, and To provide a control signal transmission method for thermal equipment that enables efficient data transmission by transmitting data from a master station only to slave stations that need to transmit data, and only when necessary. It is in.

<Means for Solving the Problems> In order to achieve the above object, the present invention provides a control signal transmission for a thermal device, which transmits data between a master station and a plurality of slave stations via one transmission path. In this method, the master station polls a plurality of slave stations in the address order of the slave stations before transmitting the data, assigns the data transmission order to the slave stations that have received a reply, and assigns the above transmission order. Of the slave stations to which data is to be transmitted, the data is transmitted in advance of the timing signal according to the above transmission sequence, while if there is no data to be transmitted to all slave stations, the master station will If there is a slave station that transmits only the signal and is not assigned the transmission order, polls by timing signal timing in advance of the slave station and then returns. There is a transmission order following the transmission order already assigned to another slave station to the slave station that has been, and the slave station assigned the above transmission order receives the timing signal and is transmitted to the master station in accordance with the assigned transmission order. It is characterized by transmitting data.

<Operation> Prior to data transmission, the master station polls a plurality of slave stations in the address order of the slave stations, assigns the data transmission order to the slave stations that have received a reply, and assigns the above transmission order. Of the slave stations to which data is to be transmitted, the data is transmitted in advance of the timing signal according to the above transmission sequence, while if there is no data to be transmitted to all slave stations, the master station will If there is a slave station that sends only a signal and is not assigned a transmission order, it polls in advance of the timing signal in the order of the slave station's address, and the slave station that has received a reply already has that address order. The slave station assigned the transmission order following the transmission order assigned to the other slave stations is assigned to the slave station in response to the timing signal. Data is transmitted to the master station according to the assigned transmission order. In this way, the master station always checks the number of slave stations connected and changes the data transmission / reception cycle depending on the number of connected stations, thereby shortening the transmission / reception cycle time and transmitting data when the number of connected stations is small. Data transmission efficiency is improved because data is transmitted from the master station only to required slave stations and only when necessary.

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

In FIG. 1, 10 is a main station which is a remote controller of an air conditioner,
Reference numerals 11 to 14 are slave stations 1 to 4 which are indoor units of the air conditioner, and 15 is a transmission path for transmitting data between the master station and the slave stations 1 to 4.

Data having the frame structure shown in FIG. 2 is transmitted and received between the master station and the slave stations 1 to 4. In FIG. 2, 21 is a leader code (LD
R), 22 is master / slave discrimination data (M / S) indicating whether the transmitting side is a master station or a slave station, 23 is a slave station address (AD), 24 is a slave station transmission order (TNO), and 25 is a receive acknowledge ( ACK),
26 is a text (TEXT) showing the transmission data, 27 is a block check code (BCC), and 28 is a trailer code (TRL) showing the end of the data block.

Transmission and reception of the above data is performed between the master station and the slave stations 1 to 4 in the procedure shown in FIG.

First, before transmitting data from the master station to the slave stations, polling is performed to assign the slave station data transmission order to the slave stations. That is, in FIG. 3 (A), the master station sets the master station / slave station discrimination data (M / S) to “master station (M)” for the slave station 1 having the first address, and sets the address (AD ) Is set to "1" and the transmission order (TNO) is set to "1". The slave station 1 which has received the data from the above master station AD = 1,
Data with TNO = 1, M / S = S returned to the main station,
Store the transmission order as "1". When the master station receives a reply from the slave station 1 within a predetermined time T ₃ , it stores the transmission order of the slave station 1 as “1” and AD = 2, TNO = 2 to the slave station 2 of the next address.
And send the data. The slave station 2 receives this data, sends back data with AD = 2 and TNO = 2 to the master station, and stores the transmission order as "2". The master station, which receives the reply from the slave station 2 within the predetermined time T ₃ , stores the transmission order of the slave station 2 as “2”, and transmits the data with AD = 3 and TNO = 3 to the slave station 3 of the next address. To do. Since there is no reply from the slave station 3 even after the lapse of the predetermined time T ₃ , the same data is retransmitted. But,
Still, since there is no reply from the slave station 3 within the predetermined time T ₃ , the same data is retransmitted again. Then, since there is no reply from the slave station 3 for the above-mentioned two retransmissions, the data with AD = 4 and TNO = 3 is transmitted to the slave station 4 of the next address. When the slave station 4 receives this data, it stores the transmission order assigned to itself as "3" and returns the data with AD = 4, TNO = 3 to the master station. The master station receives the reply from the slave station 4 and stores the transmission order of the slave station 4 as "3".

In this way, when the slave station receives the data from the master station, it stores the transmission order assigned to the slave station by this data and returns it to the master station. When the master station receives a reply from the slave station within a predetermined time T ₃ after transmitting the data, it transmits the data specifying the next transmission order to the slave station at the next address, but for a certain period of time. If the reply from the slave station is not received even after T ₃ , the data with the same transmission order is resent up to twice to the same slave station, and if there is a reply from the slave station, it will be sent to the slave station with the next address. Then, the data specifying the next transmission order is transmitted, and if there is no reply from the slave station, the data specifying the same transmission order is transmitted to the slave station of the next address. And by this poll,
A data transmission order is assigned to a slave station (hereinafter referred to as a connection device) that is in a state capable of transmitting and receiving data to and from the master station.

When the above polling is completed, the process proceeds to FIG. 3B, and the main station waits for the reception of data from the connection device.
If the slave station 4 does not detect the recorder code (LDR) for a predetermined time T ₂ after the slave station 4 replies to the master station, the slave station 1 sequentially determines the slave station 1 according to the assigned transmission order. Data is transmitted to the main station at intervals of time T ₁ . The main station waits for the predetermined time T ₂ to elapse above the connecting device 1
Set a time limit of T ₄ per unit, and
(Number of replies)-(Number of times T ₄ timed out) = 0, and after a predetermined time T ₅ , data transmission is started. And
If there is data to be transmitted to each connection device, the data is transmitted sequentially at intervals of T _{1 in} ascending order of the address. Then, when the transmission to the connection device is completed, polling is performed to confirm whether or not the non-connection device has started up and is in the connection state ₁ hour after T. This non-connection polling is performed for one device at the end of data transmission in ascending order of the address of the non-connection device. FIG. 3 (B) shows a case where data is transmitted only to the slave station 1 after the lapse of the predetermined time T _{5, and} after transmitting data to the slave station 1, the slave station 3 which is a non-connecting machine is transmitted ₁ hour after the transmission. On the other hand, the case of transmitting data with TNO = 4 is shown.

Slave station 1 Figure 3 (C) is transmitted the data of the TNO = 4 to slave station 3 from the main station, there is no reply from the slave station 3 is a third diagram (B) the same T ₂ hours after splicing apparatus, It shows the state that data is sent from 2 and 4 to the master station. Then, the master station transmits the data to the slave station 4 ₅ hours after receiving the data, and again transmits the data of TNO = 4 to the slave station 3 which has not received the reply.

Then, in FIG. 3 (D), the slave station 3 which has started up with a delay receives the data matching the self address sent from the master station, and transmits the data to the master station after T ₁ time. When the master station receives the data from the above slave station 3 within T ₃ hours,
The slave station 3 recognizes that it is in the connected state. Since all four slave stations are connected due to the startup of slave station 3,
After ₂ hours from T, data is sequentially sent from the four slave stations to the master station according to the assigned transmission order. Since the master station does not have a slave station that performs non-connection polling after receiving data from the above four slave stations, it transmits data with AD = 0 in order to set the timing of transmitting data from the slave station.

FIG. 3 (E) shows a case where the slave station 2 out of the above four slave stations is powered down and does not transmit data. In this case, the slave station 4 assigned the next transmission order of the slave station 2 waits for a predetermined time T ₄ after receiving the data from the slave station 1, and then transmits the data if the data of the slave station 2 is not received.

In FIG. 3 (F), when the slave station 2 does not transmit data for 10 consecutive cycles with transmission / reception as one cycle, the master station judges that the slave station 2 is not connected, and excludes the slave station 2 3 It indicates that the transmission order is reassigned to one slave station. That is, TNO = 2 for slave station 4, slave station 3
Is assigned TNO = 3. Then, the three slave stations except the slave station 2 transmit data to the master station according to the newly assigned transmission order. After that, the master station performs non-connection polling for the slave station 2.

In this way, the master station always checks the number of slave stations connected and changes the data transmission / reception cycle depending on the number of connected stations, thereby shortening the transmission / reception cycle time and transmitting data when the number of connected stations is small. Since data is transmitted from the master station only to the slave stations that need it and only when it is necessary, the data transmission efficiency can be improved as compared with the conventional example.

<Effects of the Invention> As is clear from the above, in the control signal transmission system for thermal equipment of the present invention, the master station polls a plurality of slave stations in the address order of the slave stations before data transmission, and a reply is sent. The data transmission order is assigned to the slave stations in the order of address, and the slave station to which the data is to be transmitted among the slave stations to which the transmission order is assigned has the data preceded by the timing signal according to the transmission order. On the other hand, when there is no data to be sent to all slave stations, the master station sends only the timing signal, and when there is a slave station to which the transmission order is not assigned, the timing signal is sent in the order of the slave station address. The polling is performed prior to, and the transmission order that follows the transmission order that is already assigned to another slave station is assigned to the slave station that has received a reply. Then, the slave station assigned the above transmission order transmits the data to the master station in response to the timing signal in response to the timing signal, and the master station always confirms the number of connected slave stations, By changing the transmission / reception cycle of, the transmission / reception cycle time is shortened when the number of connected devices is small, and data is transmitted from the master station only to the slave stations that need to transmit data and only when necessary. Therefore, the data transmission efficiency can be improved as compared with the conventional example.

[Brief description of drawings]

FIG. 1 is a connection diagram for explaining an embodiment of a control signal transmission system for thermal equipment of the present invention, and FIG. 2 shows a frame structure of data transmitted between a master station and a slave station in the above embodiment. FIG. 3 is a diagram for explaining a data transmission sequence in the above embodiment, FIG. 4 is a connection diagram for explaining a conventional control signal transmission system for thermal equipment, and FIG. 5 is a diagram for the above conventional example. It is a figure explaining the transmission order of data. 10 ... Master station, 11-14 ... Slave station, 15 ... Transmission line.

Claims (2)

[Claims] 1. A master station (10) and a plurality of slave stations (11, 12, 13, 14)
In the control signal transmission system for thermal equipment, in which data is transmitted between the master station (10) and the slave station (11,1) before transmitting the data.
2, 13 and 14) are polled in the address order of the slave stations, and the slave stations that receive a reply are assigned the data transmission order, and data is transmitted among the slave stations assigned the above transmission order. For the power slave station, while transmitting the data in advance of the timing signal according to the above transmission order, if there is no data to be transmitted to all slave stations, the master station (10) transmits only the timing signal, If there is a slave station to which the transmission order is not assigned, polling is performed prior to the timing signal in the slave station address order, and the slave station that has received a reply is already assigned to another slave station in that address order. The transmission order following the transmission order is assigned, and the slave station assigned the above transmission order receives the timing signal and follows the assigned transmission order according to the assigned transmission order. 0)
A control signal transmission system for thermal equipment, characterized in that data is transmitted to the device. 2. When the slave station to which the transmission order is assigned does not transmit the data for a predetermined number of times, the slave stations that have not transmitted the data are reassigned to the transmission order. The control signal transmission system for thermal equipment according to the first item.