JPS6369490A - Air conditioner - Google Patents

Abstract

PURPOSE:To prevent an electric compressor from breakdown due to false connection by switching two phases of an inverter controller from each other to make the electric compressor rotate forward when detecting a reverse rotation of said compressor. CONSTITUTION:An AC input current (i) is detected by a current transformer 34 and inputted to an A/D conversion input of a microcomputer 23 via a rectifier 33. If the AC input current (i) exceeds a certain value between 30 Hz and 50 Hz operating frequencies. The fact is detected that the rotation of a compressor 1 is in reverse. In this manner, outputs OUT1 and OUT3, and OUT2 and OUT4 of the microcomputer 23 are respectively switched from each other and then outputted, and the compressor 1 is rotated in a normal direction so as to be capable of making a normal cooling or heating operation.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an air conditioner that performs heating and cooling using a refrigerant compression cycle, and particularly relates to an air conditioner of variable heating and cooling capacity controlled by an inverter.

C. Prior Art] Conventionally, an air conditioner has a refrigerant compression cycle in which an electric compressor, a refrigerant flow path switching valve, an outdoor heat exchanger, a pressure reducer, and an indoor heat exchanger are connected in sequence, and the above-mentioned outdoor heat exchanger and an indoor heat exchanger are connected in sequence. The indoor heat exchanger and the indoor heat exchanger are each equipped with a blower, and cooling operation or heating operation is performed by switching operation of a refrigerant flow path switching valve.

Such control of the operation of the air conditioner is performed, for example, by an inverter control unit using an inverter system that controls the voltage and frequency of power supplied to the electric compressor. This method allows stepless control of the rotation speed,
This method is also very effective in keeping the range of room temperature fluctuations small. "U of the three-phase output in the inverter control section 2.
The phase, {circle around (2)} phase, and W phase are connected to each phase of an electric compressor using a three-phase induction motor by three power supply lines so as to correspond to each other.

However, with the above conventional structure, when manufacturing electric compressors and air conditioners, it is necessary to connect the three-phase power supply lines and three-phase terminals in correspondence with each other, making the assembly work extremely difficult. It's a hassle. In addition, when reconnecting the inverter control unit after removing it for repair of an air conditioner, etc., care must be taken to match each phase. If this continued, there would be problems such as damage to the electric compressor.

[Purpose of the invention]

The present invention has been made in consideration of the above-mentioned conventional problems, and is intended to prevent the inverter control unit and the electric compressor from being connected incorrectly when their corresponding phases are connected to each other. The purpose of the present invention is to provide an air conditioner that allows the electric compressor to rotate normally in the correct direction even when the electric compressor rotates in the correct direction, simplifies assembly work, and prevents damage to the compressor due to incorrect connection. It is something.

[Structure of the Invention] In order to achieve the following objects, the air conditioner of the present invention has a refrigerant compression cycle for heating and cooling, and is provided with a refrigerant compression cycle for heating and cooling. Air conditioner equipped with compressor6. - Also includes a reversal detection means for detecting reversal of the electric compressor, and generates three-phase power to be supplied to the electric compressor, and controls the frequency and voltage of this phase power to operate the electric compressor. At the same time, when the reversal of the electric compressor is detected by the reversal detection means, any three phases of the three-phase power supplied to the electric compressor are switched to rotate the electric compressor in the normal direction. The present invention is characterized in that it is provided with an inverter control section and configured to prevent accidents such as damage to the compressor due to incorrect connection on the corresponding homology.

〔Example〕

An embodiment of the present invention will be described below based on FIGS. 1 to 5.

As shown in Fig. 1, a three-phase induction motor 2 that drives the compressor is connected to the compressor a1 provided in the air conditioner, and these two together constitute an electric compressor. . A four-way valve 3 for switching the flow of refrigerant is connected to the compressor 1, and an outdoor heat exchanger 4 is connected to the four-way valve 3.
, a pressure reducer 5 consisting of an electronic expansion valve that can adjust the amount of pressure reduction;
A refrigerant compression cycle is configured by sequentially connecting the indoor heat exchanger 6 and the indoor heat exchanger 6 in a closed circuit. And-
1- The outdoor heat exchanger 4 and the indoor heat exchanger 6 each include:
An outdoor blower 7 and a guide blower 8 are installed nearby.

On the other hand, the three-phase induction motor 2 has an inverter section 9 that generates three-phase alternating current based on the control signal of the microcomputer 23 inputted via the drive circuit 22 and drives the three-phase induction motor 2. A drive circuit 22 of the inverter section 9 is connected to the inverter section 9 . The drive circuit 22 determines the frequency and voltage of three-phase power generated in the inverter section 9, and drives the three-phase induction motor 2.
An AC input current i detected by a current transformer 34, which will be described later, is a reference value I. When the above conditions occur, a general one-chip type micro 7-viewer (hereinafter referred to as a microcomputer) 23 is connected which switches and outputs any two phases out of the three phases of the control signal. The inverter section 9, drive circuit 22, and microcomputer 23 constitute a so-called pulse width modulation (hereinafter referred to as PWM) inverter control section. The inverter section 9 includes transistors 10 and 11 and diodes 16 and 1 for creating three-phase alternating current corresponding to the U phase, V phase, and W phase of the three-phase induction motor 2, respectively.
7, transistors 12 and 13 and diodes 18 and 1
9, transistors 14 and 15 and diodes 20 and 2
1 is provided. The microcomputer 23 includes a program ROM (re-ad only memory),
, data RAM (random accessmem)
ory), A L U (artthn+etic
andlogic unit), etc., and outputs control signals for the three-phase induction motor 2 from output terminals 0UTI to 0.
The three-phase electric power outputted from the UT 6 and based on this control signal controls the rotational speed of the three-phase induction electric motor 8!2, and has a control function of varying the air conditioning capacity.

In addition, the inverter section 9 has power terminals 24 and 25.
A rectifying and smoothing circuit 31 is connected to the rectifying and smoothing circuit 31 for voltage-doubling rectification of the alternating current inputted from the diodes 26 and 27 and capacitors 28 and 29, smoothing it in a capacitor 30, and then supplying the same to the transistors 10 to 15. Above power terminal 24
A current transformer 34, which is a reversal detection means for detecting the value of the negative side AC input current i, is disposed in the power supply path connecting the rectifying and smoothing circuit 31. Further, the microcomputer 23 is connected to a signal receiving section 32 that inputs various information such as operation and stopping from the indoor unit, and furthermore, a rectifying section 33 that rectifies the output voltage of the current transformer 34 is connected to an analog/ It is connected to a digital (hereinafter referred to as A/D) conversion input section.

In the above configuration, the three-phase induction motor 2 generally uses three-phase alternating current whose phase is shifted by 120 degrees as a power source, as shown in FIG. In this case, the direction of rotation is reversed. That is, the rotation direction of the three-phase induction motor 2 is determined such that, for example, the inverter section 9 is connected to the U phase.
When the output V phase is connected, it rotates in the opposite direction to when the LJ, V, and W phases are connected correspondingly. on the other hand,
The outputs 0UTI to 0UT6 of the microcomputer 23 output PWM control signals as shown in (a) to (f) in FIG.
A pulse, that is, a driving pulse is being output.

When the drive pulses shown in (a) to (f) of the figure are input to the corresponding transistors 10 to 5, the compressor 1 rotates in the normal direction, and the power terminals 24 and 25
The alternating current input current i of the primary power source input from the main power source is as shown in curve A in FIG. 4 for each operating frequency. Here, among the three feeder lines connected from the inverter section 9 to the three-phase induction motor 2 of compression m1, for example, the U-phase output is connected to the V terminal of the three-phase induction motor 2, and the ■-phase output is connected to the V terminal of the three-phase induction motor 2. If the U terminal is incorrectly connected, the compressor 1 will rotate in the opposite direction, and a current as shown by curve B in FIG. 4 will flow as the AC input current i. At this time, the refrigerant compression cycle does not operate normally, and not only is cooling and heating operations impossible, but there is a risk of damage to the compressor.

However, in this machine, the AC input current i is
A of the microcomputer 23 is detected via the rectifier 33.
By being input to the /D conversion input section, an AC input current i as shown by curve B in the figure flows, and this value is I.

When this happens, the microcomputer 23 switches and outputs the U-phase and V-phase PWM pulses to be output. Therefore, even if there is an incorrect connection, the compressor 1 can be rotated in the normal direction. In order to detect the reverse rotation of the three-phase induction motor 2, the inverter section 9 output 3011z~50
Accurate detection can be achieved by detecting the AC input current i in a range of about 11z. That is, between the operating frequency of the compressor 1 of 30 Hz to 50 Hz, the AC input current i is ■. If the above happens, the compressor 1 will be stopped, and after a certain period of time the outputs will be 0UTI, 0UT3, 0UT2 and 0U.
T4 are respectively switched and output, and compressor 1
is rotated in the normal direction, allowing normal cooling and L1 air conditioner operation.

Next, the control operation of this machine by the above-mentioned microcomputer 23 will be explained below according to the flowchart shown in FIG.

First, the device is operated, the PWM pulse output data switching flag Fc is set to Fc=O (Sl), and it is determined whether to run or stop (S2).

If the operation is to be stopped, various processes for the stop mode are performed (S3). If it is operation, it is determined whether Fe=1 or not (S4), and if Fe=1, the operating frequency fn
output PWM pulses from 0UT1 to 0UT6 (S5), gradually increase fn until fn is 30)12 to
If the frequency is 50Hz (S7), the AC input current i is ■
. (S8), in the above S7, f7
If the value is not 3011z to 501 (z, processing for the operation mode is performed (S9).Furthermore, in S8, if the AC input current i is not 10 or more, the processing in S9 of "2" is similarly performed. Then, in S8, the AC input current i is changed to I
. If the above is the case, the output of the PWM pulse is temporarily stopped (S10), and the T+waiting time timer is set (S10).
ll). After that, when T1 time has passed (S 12)
, PWM pulse output data switching flag Fc, Fe
= 1 (S13).

Then, if Fc=1, (34), P for f
When outputting WM pulse, 0UTI data and 0UT3
The data is switched, and 0UT2 data and 0UT4 data are switched and output (36).

Furthermore, when Fc=1, the same result can be obtained by switching between 0UTI data and 0UT5 data, and switching between 0UT2 data and 0UT6 data, and also when 0UT3 data and 0U
The same result will be obtained even if the T5 data is switched and the 0UT4 data and 0UT6 data are switched.

〔Effect of the invention〕

As described above, the air conditioner of the present invention has a refrigerant compression cycle that performs heating and cooling, and is equipped with a three-phase electric compressor provided for this refrigerant compression cycle. a reversal detection means for detecting a reversal of the compressor, a reversal detection means for generating three-phase power to be supplied to the electric compressor, and controlling the frequency and voltage of the three-phase electric power to control the operation of the electric compressor; and an inverter control unit that switches any two phases of the three phases of the three-phase power supplied to the electric compressor to rotate the electric compressor in the normal direction when reverse rotation of the electric compressor is detected. It is. As a result, even if there is an incorrect connection between the corresponding phases of the devices that make up this machine, the phase of the inverter control unit output can be switched appropriately, and the electric compressor can be rotated in the correct direction. can. Therefore, damage to the electric compressor due to the above-mentioned incorrect connection can be prevented, and reliability can be improved. In addition, there is no need to take into account incorrect connections between corresponding phases during manufacturing, etc., and the assembly work can be simplified, which is an excellent effect.

[Brief explanation of the drawing]

FIG. 1 is an overall configuration diagram of an air conditioner showing an embodiment of the present invention, and FIGS. 2(a) to (f) are time charts of pulse width modulated pulses output from the microcomputer shown in FIG. Figure 3 is a graph showing the voltage waveform of a general three-phase AC.
FIG. 4 is a graph showing the relationship between the operating frequency f7 and the AC input current i in the air conditioner, and FIG. 5 is a flowchart showing the control operation of the microcomputer. 1 is a compressor (electric compressor), 2 is a three-phase induction motor (electric compressor), 9 is an inverter section (inverter control section), 1
0 to 15 are transistors, 22 is a drive circuit (inverter control section), 23 is a microcomputer (inverter control section), 31 is a rectifying and smoothing circuit, and 34 is a current transformer (reversal detection means). (Twenty two!

Claims (1)

[Claims] 1. An air conditioner having a refrigerant compression cycle for heating and cooling, and equipped with a three-phase electric compressor provided for this refrigerant compression cycle, comprising: a reversal detection means for detecting reversal of the electric compressor, and an electric compressor. generates three-phase power to be supplied to the compressor, controls the frequency and voltage of this three-phase power to control the operation of the electric compressor, and when the reversal detection means detects the reversal of the electric compressor, An air conditioner comprising: an inverter control section that switches any two phases among three phases of three-phase power supplied to an electric compressor to rotate the electric compressor in the normal direction.