KR100691228B1 - Non-polar two-wire type indoor and outdoor communication device for multi type air conditioner - Google Patents

Abstract

The present invention relates to a non-polar two-wire communication device of a multi-type air conditioner, and in particular, the present invention provides a non-polar communication environment in software without additional hardware in a polarized communication environment where each microcomputer replaces the function of each relay switch in software. By constructing the circuit board, each printed circuit board can be miniaturized, and manufacturing cost of each printed circuit board can be reduced.

To this end, the present invention is a non-polar two-wire communication device of a multi-type air conditioner, a master microcomputer for transmitting command data for data inversion recognition, and non-inverting the data received thereafter according to whether the received command data received Slave microcomputer to determine whether to recognize or invert to recognize.

Description

Non-polar 2-wire communication device of multi-type air conditioner {NON-POLAR TWO-WIRE TYPE INDOOR AND OUTDOOR COMMUNICATION DEVICE FOR MULTI TYPE AIR CONDITIONER}

1 is a view showing an example of a communication line misconnection of a non-polar two-wire communication device of a conventional multi-type air conditioner.

FIG. 2 is a diagram for describing a miswiring solution through communication line switching of a communication line miswiring device of FIG. 1.

FIG. 3 is a diagram illustrating a normal communication between devices by eliminating a miswiring line through FIG. 2.

4 is a diagram illustrating an example of a communication line erroneous connection of a non-polar two-wire communication device of a conventional multi-type air conditioner according to an embodiment of the present invention.

FIG. 5 is a diagram for explaining the elimination of the communication line misconnection of FIG. 4 in a software manner.

FIG. 6 is a diagram illustrating a normal communication between devices by eliminating communication line misconnection by software through FIG. 4.

* Description of the symbols for the main functions of the drawings *

100: outdoor unit 101: outdoor unit microphone

110A, 110B: Outdoor unit 111A, 1101: Indoor unit micro

120: refrigerant classifier 121: refrigerant classifier

130: communication line

The present invention relates to a non-polar two-wire communication device of a multi-type air conditioner, and more particularly, a non-polar two of a multi-type air conditioner capable of miniaturizing a printed circuit board required for non-polar two-wire communication and reducing manufacturing costs. It relates to a wire communication device.

In general, the multi-type air conditioner, in particular, the air-conditioning simultaneous multi-type air conditioner is provided with a plurality of outdoor units, a plurality of indoor units, a plurality of refrigerant sorting apparatus.

Such outdoor units, indoor units, and refrigerant classifiers transmit and receive data through a communication line, and are connected by using a polarized communication method.

The multi-type air conditioner frequently causes such a misconnection of communication lines due to the uniqueness of the installation environment in which a plurality of devices are spaced far apart, and the installer wastes a lot of time and effort to solve the misconnection of the communication lines.

To this end, as an example, as shown in FIG. 1, the indoor unit # 1 20A and the indoor unit # 2 (20B) are normally connected to the communication line 40 in the outdoor unit 10, and the refrigerant classification device 30. Is reversely connected to the communication line 40, when the outdoor unit microcomputer 11 of the outdoor unit 10 transmits a transmission signal through the communication circuit 12, the indoor unit # 1 (20A) and the indoor unit # 2 (20B) Each indoor unit microcomputer 21A, 21B receives the transmission signal of the outdoor unit 10 as it is, but the microcomputer 31 of the refrigerant classification device 30 receives a signal opposite to the transmission signal of the outdoor unit 10.

When using this to operate the relay switch 13 of the outdoor unit 10 as shown in Figure 2 in order to correct the communication line incorrect wiring of the refrigerant sorting device 30 to reverse its communication line 40 to change the polarity, The outdoor unit 10, the indoor unit # 1 (20A), and the indoor unit # 2 (20B) can be reversed in communication polarity, the outdoor unit 10 and the refrigerant sorting device 30 can be the same. In this state, as shown in FIG. 3, when the outdoor unit 10 operates the relay switch 33 of the refrigerant classification device 30 to reverse the communication line 40 and transmits a communication protocol for reversing the polarity, the indoor unit # 1 (20A) and indoor unit # 2 (20B) are reversed in communication polarity and thus cannot receive the data transmitted by the outdoor unit. However, since the refrigerant classification device 30 has the same polarity as the outdoor unit 10, the refrigerant classification device 30 receives the data transmitted by the outdoor unit 10. For this reason, the refrigerant classification device 30 reverses its communication line through its relay switch 33, thereby eliminating the erroneous connection of the communication line 40.

When the outdoor unit 10 switches its communication line 40 to its original state through the relay switch 13 after the communication line misconnection of the refrigerant classification device 30 is eliminated, the outdoor unit 10 is the indoor unit # 1 (20A). , Both the indoor unit # 2 (20B) and the refrigerant classification device 30 and the communication line 40 are correctly connected.

However, in the related art, since relay switches for changing communication polarity must be installed in outdoor units, indoor units, and refrigerant classifiers, it is difficult to miniaturize printed circuit boards (PCBs) due to the installation of relay switches, and the manufacturing cost of printed circuit boards increases. There is a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is a non-polar two-wire communication device of a multi-type air conditioner capable of removing each relay switch so that each microcomputer replaces the function of each relay switch in software. To provide.

In the non-polar two-wire communication device of the multi-type air conditioner of the present invention for achieving the above object, in the non-polar two-wire communication device of the multi-type air conditioner, a master microcomputer for inverting and transmitting the command data for data inversion recognition; And a slave microcomputer for determining whether to recognize inverted or inverted data subsequently received after the received command data; The master microcomputer inverts or non-inverts the command data and transmits the command data so that only the indoor unit miswired to the outdoor unit receives the command data.

The master microcomputer is an outdoor unit microcomputer for controlling the overall operation of the outdoor unit, the slave microcomputer is characterized in that the indoor unit microcomputer to control the overall operation of the indoor unit.

The slave microcomputer is a non-polar two-wire communication device of the multi-type air conditioner, characterized in that the microcomputer of the plurality of indoor microcomputers or a plurality of indoor microcomputers and the cooling and cooling refrigerant sorting device at the same time.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

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In particular, the multi-type air conditioner according to the present invention is an air conditioner simultaneous multi-type air conditioner, as shown in FIG. 4, which is largely used for communication between the outdoor unit 100, the indoor unit 110, the refrigerant classification device 120, and the like. The communication line 130 is provided.

First, the outdoor unit 100 serves as a master of communication with each of the indoor units 110A and 110B and the refrigerant classification device 120, and responds to each of the indoor units 110A and 110B and the refrigerant classification device 120 for multiple communication. Allocate In addition, the outdoor unit 100 includes an outdoor unit microcomputer 101 and a communication circuit 102 capable of inverting and transmitting communication data.

Each indoor unit 110A, 110B receives a response time from the outdoor unit 100 and transmits its information to the outdoor unit 100 and the refrigerant classification device 120. In addition, each indoor unit (110A, 110B) is provided with indoor unit microcomputer (111A, 111B) and communication circuits (112A, 112B) that can be recognized by inverting the communication data.

The refrigerant classification device 120 receives a response time from the outdoor unit 100 and transmits its information to the outdoor unit 100 and the indoor units 110A and 110B. In addition, the refrigerant classifier 120 includes a refrigerant classifier microcomputer 121 and a communication circuit 122 that can recognize the communication data by inverting it.

The outdoor unit 100 is connected to each indoor unit (110A, 110B), the refrigerant classification device 120 by a polarizing communication line 130, and share information with each other through the communication line 130. If the polarity of the communication line 130 is reversed, the device may not perform normal communication.

As shown in FIG. 4, the indoor unit # 1 110A and the indoor unit # 2 110B are normally connected to the communication line 130 in the outdoor unit 100, and the refrigerant classification device 120 # 1 is connected to the communication line 130 in reverse. In this case, when the outdoor unit microcomputer 101 of the outdoor unit 100 transmits a transmission signal, each of the indoor unit microcomputers 111A and 111B of the indoor unit # 1 (110A) and the indoor unit # 2 (110B) is connected to the outdoor unit 100 of the outdoor unit 100. Although the transmission signal is received as it is, the microcomputer of the refrigerant classification device 120 receives a signal opposite to the transmission signal of the outdoor unit 100.

The outdoor unit microcomputer 101 of the outdoor unit 100 sets its transmission state to NOT REVERSE in advance, and each of the indoor unit # 1 (110A), the indoor unit # 2 (110B), and the refrigerant classification device (120). The microcomputers 111A, 111B, and 121 also set the reception state to NOT REVERSE in advance. In this manner, a communication protocol that is a communication promise between the outdoor device microcomputer 101 and each of the microcomputers 111A, 111B, and 121 is determined.

When the outdoor unit 100 transmits data In the indoor unit # 1 (110A) and the indoor unit # 2 (110B), the communication line 130 is correctly connected to receive the same data as the transmission data of the outdoor unit 100, but the refrigerant In the case of the classification apparatus 120, the outdoor unit 100 and the communication line 130 are reversed to receive the data in the inverted state of the outdoor unit 100 transmission data.

In order to solve this problem, as shown in FIG. 5, the outdoor unit microcomputer 101 of the outdoor unit 100 changes the transmission state to inversion. At this time, the reception state of each of the microcomputers 111A, 111B, 121 of the indoor unit # 1 110A, the indoor unit # 2 110B, and the refrigerant classification device 120 is still set to non-inverting.

In this state, the outdoor unit microcomputer 101 of the outdoor unit 100 transmits a communication protocol for reversing the polarity. The polarity reversal communication protocol is command data for the micom to invert and recognize the received data. At this time, since the transmission state of the outdoor unit 100 is set to inversion, the data is transmitted to the indoor unit # 1 (110A), the indoor unit # 2 (110B) and the refrigerant classification device 120 in the inverted state.

The indoor unit # 1 110A, the indoor unit # 2 110B, and the refrigerant classification device 120 may recognize the non-inverted data after receiving the communication protocol for polarity reversal transmitted from the outdoor unit 100 according to whether or not it is received. It will decide whether or not to recognize it.

That is, the indoor unit # 1 (110A) and the indoor unit # 2 (110B) has a non-inverted reception state and the connection state of the outdoor unit 100 and the communication line 130 is the same, so that the data inverted from the outdoor unit 100 The reception is possible, but it cannot be performed because the polarity reversal communication protocol is not recognized. Therefore, the indoor unit microcomputers 111A and 111B of the indoor unit # 1 110A and the indoor unit # 2 110B continue to recognize the data received thereafter as non-inverting as initially set.

However, although the refrigerant classification device 120 has set the reception state to non-inverting, since the polarity of communication with the outdoor unit 10 is reversed, since the data reversed from the outdoor unit 100 is reversed and the polarity inversion communication protocol is received, The refrigerant classifier microcomputer 121 performs the polarity reversal communication protocol and inverts and receives the received data. At this time, the refrigerant classifier 120 sets the reception state of the refrigerant classifier microcomputer 121 to inversion due to the received polarity reversal communication protocol.

After that, the outdoor unit 100 returns the transmission state of the outdoor unit microcomputer 101 to non-inverting.

Thus, the communication environment as shown in FIG. 6 is finally established. The refrigerant classifier microcomputer 121 of the refrigerant classifier 120 in which the communication polarities between the outdoor unit 100, the indoor unit # 1 (110A), and the indoor unit # 2 (110B) are reversed are subjected to the processes of FIGS. 4 and 5. By setting the reception state of the own microcomputer 121 to reverse, it is possible to perform normal communication between all devices.

As described in detail above, the present invention can miniaturize each printed circuit board by constructing a non-polar communication environment in software without adding hardware in a polarized communication environment in which each microcomputer replaces the function of each relay switch in software. And, there is an effect that can reduce the manufacturing cost of each printed circuit board.

Claims (5)

In the non-polar two-wire communication device of the multi-type air conditioner, A master microcomputer that transmits command data for data inversion recognition; And a slave microcomputer for determining whether to recognize inverted or inverted data subsequently received after the received command data; The master microcomputer is a non-polar two-wire communication device of the multi-type air conditioner for transmitting the inverted or non-inverted command data so that only the indoor unit miswired to the outdoor unit receives the command data. The non-polar two-wire communication device of claim 1, wherein the master microcomputer is an outdoor unit microcomputer for controlling the overall operation of the outdoor unit, and the slave microcomputer is an indoor unit microcomputer for controlling the overall operation of the indoor unit. The non-polar two-wire communication device of claim 2, wherein the slave microcomputer is a microcomputer of a plurality of indoor microcomputers or a plurality of indoor microcomputers and a cooling / heating refrigerant sorting device. delete delete

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