KR100282726B1 - Compressor Vacuum Preventer - Google Patents

Abstract

Disclosed is a vacuum preventing device of a compressor for preventing the inside of the compressor from being excessively vacuumed.

The present invention is such that one of the application line connecting each terminal of the power supply terminal and the power mechanism unit has a sealed first seal that includes both ends of the application line and is set to a predetermined pressure, and has the same pressure as the internal pressure of the compressor. And a pressure switch including a second chamber having at least one refrigerant inlet hole, and a diaphragm made of a conductor for energizing or breaking both ends of the applied line according to the pressure of each chamber.

As a result, the compressor can be selectively stopped according to the pressure change in the compressor, thereby preventing short circuits between terminals applying external power to the power mechanism, thereby preventing the terminal from being damaged or damaging the power mechanism. There is an advantage to that.

Description

Compressor Vacuum Preventer

The present invention relates to a compressor, and more particularly, to a vacuum prevention device of a low pressure compressor for preventing the burnout of a terminal for applying external power to the power mechanism of the compressor by switching the power according to the pressure inside the shell.

In general, the refrigeration and air conditioning cycle is divided into four components, a compressor, a condenser, an expansion valve, and an evaporator. Among these, the compressor plays an intermediate role of sucking low temperature low pressure refrigerant from the evaporator, compressing it to high temperature and high pressure, and sending it to the condenser. .

As such, a compressor in which the inside of the compressor shell is filled with a low pressure refrigerant is called a low pressure compressor.

There are many kinds of such low pressure compressors, and the scroll compressor will be described as an example.

This scroll compressor is mainly used in air conditioners and freezers because it has excellent dynamic performance in a wide range of capacity compared to other types of compressors.

Its configuration is as shown in Figure 1, the upper and lower shells (2) (2a) divided by the upper diaphragm (1), the rotor mechanism consisting of the rotor (3) and the stator (4), the turning scroll in conjunction with the electric mechanism ( 6) and a main shaft 5 for transmitting the rotational force generated from the power transmission mechanism and the compression mechanism consisting of the fixed scroll 7 to the compression mechanism.

At this time, the upper portion of the diaphragm 1, the upper portion is composed of the discharge chamber (8), the lower portion is composed of the suction chamber (9), the upper diaphragm (1) and the separation that separates the suction chamber (9) and the discharge chamber (8) The refrigerant compressed by the compression mechanism portion is sent to the discharge chamber 8 through the check valve 10 provided between the scrolls 7.

Therefore, the pressure distribution inside the compressor shell 2 (2a) is such that the suction chamber 9 through which the refrigerant flows through the suction pipe 11 becomes the low pressure side, and the upper shell 2 flows through the compression mechanism. The discharge chamber 8 forms a relatively high pressure side.

The refrigerant flowing through the suction pipe 11 is sucked into the compression chamber of the involute curve wrap formed on the fixed scroll 7 and the swing scroll 6, and the rotor 3 of the electric mechanism rotates. Rotating the spindle 5 is connected to the swing frame 6 and the one-way keyway by the old dam ring 14 on the upper frame 12 and the drive bushing 13 to rotate the rotation of the spindle 5 Will be transformed into a turning movement.

The refrigerant compression process according to the turning angle of the turning scroll 6 is shown in FIG. 2. Where A is the direction of rotation and S1 is the center of rotational movement = spindle center = fixed scroll center.

When the swing scroll lap forms a suction flow path away from the outer lap of the fixed scroll at 0 °, the refrigerant flows through the two semi-moon compression chambers formed by the two scroll wraps to the center of the scroll, depending on the swing angle. Proceed.

Eventually, the compression chamber collected at the center is opened at the discharge port 15 on the rear of the fixed scroll 7, and the compressed refrigerant discharged through the valve housing 16 is mounted on the fixed scroll 7. ) Is pushed upward and discharged into the discharge chamber 8 composed of the upper diaphragm 1 and the upper shell 2, and the refrigerant compressed through the discharge pipe 18 is sent to a freezing / air conditioning cycle.

Since the three-phase induction motor is generally used as the electric mechanism part 3 (4) of such a scroll compressor, a power supply terminal 19 having three terminals is provided on the side wall of the lower shell 2a to provide the electric machine part 3 External power is applied to (4).

Meanwhile, in the refrigerating or air conditioning cycle of the refrigerant to which the scroll compressor is applied, the low-temperature low-pressure gas phase refrigerant flows into the compressor 21 from the evaporator 20 and is compressed into a high-temperature high-pressure gas phase refrigerant as shown in FIG. 3. The refrigerant is condensed into a liquid refrigerant during heat exchange with cold air in the condenser 22, and becomes a two-phase refrigerant in a gas phase and a liquid phase through an expansion valve 23, and the two-phase refrigerant is an evaporator 20 of the indoor unit side. In the process of heat exchange with the hot air in the room, the refrigerant is evaporated to a low-temperature, low-pressure gaseous refrigerant and the heat-exchanged cold air performs freezing or cooling.

When installing or transferring such a refrigerator or an air conditioner, each element must be disassembled and dismantled, and thus the refrigerant remaining in each element must be recovered.

This process is performed by the operator. That is, the operator closes the valve 24 at the rear end of the condenser 22 or the valve 24 'at the front of the compressor 21 before dismantling each element, and then drives the compressor 21 to collect the refrigerant in the condenser. When the refrigerant is properly recovered, the valve of the condenser 22 is closed so that the refrigerant is trapped in the condenser 22.

After that, we will separate each element and perform the operation.

However, in the conventional refrigerant recovery method, the completion point of the refrigerant recovery is determined by the operator's judgment, so if the compressor is not stopped at an appropriate time due to the immaturity of the operator, the refrigerant continues to flow out to the condenser side, and the internal pressure of the compressor shell rapidly decreases. Eventually, the vacuum is close.

As is well known, the conductivity increases under vacuum, so that if the inside of the compressor shell approaches a vacuum state, sparks may occur between adjacent terminals of the power supply terminal. If sparks occur, the terminals are melted and burned out, and thus, electric There is also a fear that the mechanism itself may be inoperable.

Accordingly, the present invention has been proposed in view of this point, and when the pressure inside the compressor shell falls below the set pressure, the operation of the compressor is stopped to prevent the burnout of the power terminal terminal. There is this.

1 is a longitudinal sectional view of a general scroll compressor,

2 is a refrigerant compression progress diagram of a typical scroll compressor,

3 is a general refrigeration and air conditioning cycle configuration diagram,

4 is a longitudinal sectional view of a scroll compressor according to the present invention;

5 is an operation diagram of the vacuum switch of the scroll compressor according to the present invention;

Figure 5a is in normal driving,

5B is a refrigerant recovery time.

*** Explanation of symbols for main parts of drawing ***

2a: lower shell 3, 4: electric mechanism part

19: power terminal 101: pressure switch

102: first applying line 103: second applying line

104: first pressure chamber 105: refrigerant inlet hole

106: second pressure chamber 107: diaphragm

108, 108 ': stopper

The vacuum prevention device of the compressor according to the present invention for achieving the above object has a compressor mechanism for compressing a refrigerant, a power mechanism for providing a driving force to the compressor mechanism, and a plurality of terminals for applying external power to the power mechanism. For compressors with power terminals:

At least one predetermined portion of an application line connecting each terminal of the power supply terminal and the power mechanism unit,

(1) a sealed first seal including both ends of the application line and set to a predetermined pressure;

(2) a second chamber having at least one refrigerant inlet hole to have a pressure equal to the internal pressure of the compressor; And

(3) The first chamber and the second chamber are partitioned, and a pressure switch including a diaphragm made of a conductor is provided to conduct or break both ends of the application line according to the pressure of each chamber. .

Optionally, a stopper is formed on sidewalls of the first chamber and the second chamber to limit the movement position of the diaphragm.

In this case, when the compressor is in normal operation, the power is in the applied state, and when the pressure inside the compressor drops sharply due to the refrigerant recovery, the power is cut off and the operation is stopped.

As a result, since the vacuum inside the compressor is prevented, there is an advantage that the burnout of the power supply terminal and damage to the electric mechanism part of the compressor can be prevented in advance.

And, there may be a plurality of embodiments of the present invention, hereinafter will be described in detail with respect to the most preferred embodiment.

This preferred embodiment allows for a better understanding of the objects, features and advantages of the present invention.

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

In addition, the techniques of the present invention can be applied to various low pressure compressor products as well as scroll compressors.

Therefore, the drawings used in the description are not related to a specific scroll compressor product, but focus on various low pressure compressors.

In addition, in drawing used for description, about the component same as FIG. 1 and FIG. 2, the same code | symbol is attached | subjected, and the overlapping description may be abbreviate | omitted.

In addition, in the following, an example applied to a scroll compressor is considered to help understand the description.

Figure 4 is a view showing an embodiment provided in the description of the vacuum preventing device of the compressor according to the present invention, a vertical cross-sectional view of the scroll compressor, Figure 5 is an operation of the vacuum prevention switch of the compressor according to the present invention, Figure 5a In normal operation, FIG. 5B is a refrigerant recovery time.

The vacuum preventing device of the compressor according to the present embodiment is a kind of a pressure switch 101, which is provided from the respective terminals of the power supply terminal 19 provided on the side wall of the lower shell 2a to the power mechanism unit 3 and 4 side as shown in FIG. It is interposed in one of the applied licensed lines.

This pressure switch 101 is the first application line 102 from the power supply terminal 19 and the second application line 103 applied to the power transmission mechanism (3) (4) side as shown in FIG. A first pressure chamber 104 inserted and set to a constant pressure, a second pressure chamber 106 in which a plurality of refrigerant inlet holes 105 are formed to have the same pressure as the pressure inside the compressor shell, and While partitioning the first pressure chamber 104 and the second pressure chamber 106, the first application line 102 and the second application line 103 are energized by moving in accordance with the pressure of each chamber 104 and 106. It consists of a disconnecting diaphragm 107.

At this time, the diaphragm 107 is preferably composed of a conductor, the stopper 108 for limiting excessive movement of the diaphragm 107 on the side walls of the first pressure chamber 104 and the second pressure chamber 106. (108 ') is preferred.

The vacuum preventing device of the compressor according to the present invention made as described above operates as follows.

First, in the normal operation state, since the pressure inside the compressor is considerably large as shown in FIG. 5A, the pressure in the second pressure chamber 106 is greater than the pressure in the first pressure chamber 104, so that the diaphragm 107 may have a first pressure. It moves to the pressure chamber 104 side, it is connected to the first application line 102 and the second application line 103 to energize it.

When each of the applied wires 102 and 103 is energized, the external power is applied to the transmission mechanisms 3 and 4 via the respective terminals of the power supply terminal 19, so that the compressor operates normally.

This normal operation continues even when the refrigerant pressure is not lower than the pressure range set in the first pressure chamber 104 even when the refrigerant is recovered.

When the recovery of the refrigerant proceeds to some extent, the pressure inside the compressor is rapidly lowered. At this time, the pressure in the first pressure chamber 104 becomes larger than the pressure in the second pressure chamber 106, that is, the pressure inside the compressor. 107 is moved toward the second pressure chamber 106, whereby the diaphragm 107 is separated from the first application line 102 and the second application line 103 so that each application line 102, 103 is separated. It is in a broken state.

When each of the applied wires 102 and 103 is broken, the external power applied to the power mechanism units 3 and 4 is cut off, and the compressor is stopped, thereby preventing excessive vacuum inside the compressor.

Here, it is obvious that the pressure of the first pressure chamber 104 should be set to match the characteristics of each compressor.

On the other hand, as a comparative example, when the external power is directly applied from the power supply terminal to the electric mechanism part, and the inside of the compressor is in a vacuum state, a short circuit occurs between the terminals so that the terminals melt and burn. It can be seen that the compressor is selectively stopped according to the pressure inside the compressor via a pressure switch on an application line applied from the power supply terminal to the motor mechanism side.

As a result, according to the present invention, when the internal pressure of the compressor is in the normal range, the compressor is normally operated. When the internal pressure of the compressor decreases rapidly, the compressor is stopped to prevent short circuit between the terminals and to prevent burnout of the terminals. There is an advantage that can be prevented.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be variously modified and implemented by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments should fall within the appended claims of the present invention.

It is clear from the above description that the present invention can selectively stop the compressor according to the pressure fluctuations inside the compressor, so that a short circuit between the terminals applying external power to the power mechanism is prevented and the terminal is damaged or the power mechanism is damaged. There is an effect that can prevent the phenomenon in advance.

Claims (2)

A compressor comprising a compressor mechanism for compressing a refrigerant, a power mechanism portion for providing a driving force to the compressor mechanism portion, and a power terminal having a plurality of terminals for applying external power to the power mechanism portion: At least one predetermined portion of an application line connecting each terminal of the power supply terminal and the power mechanism unit, (1) a sealed first seal including both ends of the application line and set to a predetermined pressure; (2) a second chamber having at least one refrigerant inlet hole to have a pressure equal to the internal pressure of the compressor; And (3) partitioning the first chamber and the second chamber, the pressure switch including a diaphragm made of a conductor which energizes or breaks both ends of the application line according to the pressure of each chamber; Compressor vacuum protection device. The method of claim 1, The sidewalls of the first chamber and the second chamber are formed with a stopper for limiting the movement position of the diaphragm.