JPS60223966A - Refrigerator - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Technical Field of the Invention] 1.Regarding the improvement of a refrigeration system that uses a parka to control the rotation of a compressor. It is.

[Prior art]

A refrigeration system having an inverter controls the rotation of an electric motor that drives a refrigerant compressor by varying the power frequency. By controlling the rotational speed of the compressor in this way, the refrigerating capacity can be changed continuously.

FIG. 1 is a block diagram showing an example of a refrigeration system with an inverter that has been commonly used in the past, in which (1) is a compressor that compresses refrigerant, (2) is a condenser, and (3) is an expansion valve. , (4) is an evaporator, which is connected to a closed loop through these pipes to constitute a refrigeration cycle. (5) is an inverter that outputs a variable frequency of the commercial power supply, and (6) is an inverter that outputs a variable frequency of the commercial power supply, and (6) is an inverter that outputs a variable frequency of the commercial power supply, and (6) is an inverter that outputs a variable frequency of the commercial power supply. This is a control unit that controls the inverter (5). (8) is an electromagnetic contactor installed on the power line connecting the inverter (5) and the compressor (1), and this electromagnetic contactor (8) is a protective switch 00 including an overcurrent relay, a high voltage switch, etc. It is connected to the break contact (10b) of. (9) is an overcurrent relay also provided in series with the above power supply line.

In the conventional refrigeration system configured as described above, when a power switch (not shown) is turned on, the electromagnetic contactor (8) is closed and the electric power output from the inverter (δ) is transferred to the electric motor of the compressor (1) (Fig.・The compressor (not shown) is supplied to the compressor (1
) is driven. When compressed refrigerant flows through the refrigeration cycle by operating the compressor (1), cooling is performed by the evaporator (4) as is well known.

Here, when the cooling load decreases, the refrigerant pressure on the low pressure side of the refrigeration cycle decreases, and the pressure detection section (7)
The level of the pressure detection signal outputted to the control unit (6) also decreases. The control unit (6) compares the pressure detection signal with the reference value, so if the pressure detection signal is lower than the reference value, the control unit (6) controls the inverter (5) so that the output frequency is reduced. The cooling capacity is lowered by lowering the rotation speed of the compressor (1). When the cooling capacity is lowered in this way, the refrigerant pressure on the low-pressure side of the refrigeration cycle increases.Also, when the cooling load is high, the refrigerant pressure on the low-pressure side of the refrigeration cycle increases, and the pressure detection unit The pressure detection signal output from (7) to the control unit (6) increases. As a result, the control section (6) controls the inverter (5
) is controlled so that its output frequency increases, and the compressor (
1) The cooling capacity is increased by increasing the rotation speed.

Therefore, in a refrigeration system having such an inverter (5), it is possible to control the cooling capacity according to the cooling load, and it is possible to save power.

However, in the conventional refrigeration equipment described above, the inverter (
5), there is no backup circuit, so the compressor (1) will stop for a long time, causing a problem in that the temperature inside the refrigerator will rise and the objects to be cooled will rot.

[Summary of the invention]

This invention solves the conventional problems as mentioned above.
By installing a control unit that detects the inverter output and detects whether there is an inverter abnormality, and automatically switches to commercial power if it is determined that the inverter is abnormal, the compressor will continue to operate even if the inverter fails. [Embodiment of the invention] Fig. 2 is a configuration diagram showing an embodiment of the refrigeration equipment according to the present invention. The same parts as in the figures are indicated using the same symbols. In the figure, 0υ is an inverter abnormality detection section provided on the output side of the inverter (5), which detects the output of the inverter (5) and generates a detection signal indicating the presence or absence of an inverter abnormality. The detection signal generated by this inverter abnormality detection section 0υ is input to the control section (6).

Now, when the power switch (not shown) is turned on, the control unit (6
) - a break contact (10b) of the protective switch (11) - a closed circuit of the electromagnetic contactor (8) is formed. The electromagnetic contactor (8) is energized by this closed circuit, and the electromagnetic contactor (8a) is turned on. Therefore, during normal operation, when the electromagnetic contactor (8a) is turned on, F:r
, mm (1) is an overcurrent relay (9), an electromagnetic contactor (8a
), and is connected to a commercial power source via an inverter (5) and driven.

Next, if the inverter (5) fails, the control unit (6)
relay (not shown) is energized, a closed circuit is formed between the make contact (6a) of the control section (6) and the time-limited relay (1, 1), and the time-limited relay a is energized.The time-limited relay 01 is energized. When a predetermined period of time, for example 8 seconds, has elapsed since the current was energized, the time-limited relay (to) is energized.When the time-limited relay α is energized, the make contact (18a) of the time-limited relay (18a)-! A magnetic contactor-like closed circuit is formed. The electromagnetic contactor (2) is energized by this closed circuit, and the electromagnetic contactor (12a) is turned on. On the other hand, since the relay (not shown) of the control section (6) is energized, the break contact (6b) of the control section (6) is energized.
) is opened and the magnetic contactor (8) is deenergized.

When the magnetic contactor (8) is deenergized, the magnetic contactor (8a)
will be released.

Therefore, as described above, the inverter abnormality detection unit Ql
) By inputting the detection signal generated from the inverter (6) to the control unit (6), the control unit (6) automatically outputs the signal to the output side of the inverter (6) during normal operation, and to the commercial power supply side when there is an abnormality in the inverter. Switch to.

In other words, even if the inverter (5) fails, the inverter abnormality detection unit 0) automatically detects the inverter abnormality, and the control unit (6) automatically switches to commercial power, and the compressor (1) operates continuously without stopping.

[Efficacy of invention]

As explained above, in the refrigeration system according to the present invention, even if the inverter malfunctions, the inverter malfunction detection section detects the inverter malfunction and switches to commercial power, so even if the inverter malfunctions, the compressor does not have to be stopped. Can be operated continuously.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing a conventional refrigeration system, and FIG. 2 is a block diagram showing an embodiment of the refrigeration system according to the present invention. (1)---Compressor, (2)... Condenser, (3)...
・Expansion valve, (4)...evaporator, (5)...inverter, (6)...control unit, (7)...pressure detection unit, (
11)... Inverter abnormality detection section is shown. Agent Masuo Oiwa

Claims (1)

[Claims] A refrigeration cycle configured by connecting a compressor, a condenser, an expansion valve, and an evaporator in a closed loop, an inverter that varies the power frequency and supplies it to an electric motor that drives the compressor, and a low pressure of the refrigeration cycle. an inverter abnormality detection section that detects the output of the inverter and generates a detection signal indicating whether or not there is an abnormality in the inverter; and a control unit that controls the inverter to converge the refrigerant pressure on the low pressure side to a predetermined set value, and switches to commercial power when the inverter abnormality detection unit receives a signal indicating that there is an inverter abnormality. Characteristic refrigeration equipment.