KR100390420B1 - Device for preventing backward-flow in scroll compressor - Google Patents

Abstract

The present invention is to improve the backflow prevention device of the scroll compressor, to minimize the dead volume and thus the backflow phenomenon.

To this end, the present invention is a scroll compressor having a fixed scroll and a movable scroll provided in a closed casing and interlocked with each other so that the compression chamber is partitioned; In normal operation in which the compression chamber pressure is greater than the discharge chamber pressure, a branched communication port branched upward in the fixed scroll so that the refrigerant gas compressed in the compression chamber flows to the discharge chamber. Is formed; When the compression chamber pressure is lower than the discharge chamber pressure during operation stop or high pressure ratio operation, the backflow prevention is prevented at the branch center of the communication port so that the refrigerant gas in the discharge chamber does not flow back into the compression chamber through the branched communication port. It provides a backflow prevention device of a scroll compressor, characterized in that the means is provided.

Description

Device for preventing backward-flow in scroll compressor

The present invention relates to a scroll compressor, and more particularly, to a backflow prevention device of a scroll compressor for preventing the refrigerant gas from flowing back into the compression chamber during operation stop or high pressure ratio operation.

In general, a scroll compressor is a compressor that compresses refrigerant gas by changing a volume of a compression chamber formed by a pair of opposed scrolls, and has a higher efficiency, lower vibration and noise than a reciprocating compressor and a rotary compressor. In addition, it is possible to reduce the size and weight of the Braille is expanding the use area.

Here, the scroll compressor, as shown in Figure 1, the high and low pressure separation provided to partition the inner casing 1, the inner space in the sealed casing into a high pressure discharge chamber (1a) and a low pressure suction chamber (1b). A movable scroll (3) and a fixed scroll (4) interlocked with each other so that a plate (2) and a compression chamber (4a) having a high pressure part, a medium pressure part, and a low pressure part are provided in the suction chamber on the bottom side of the high and low pressure separating plate; And, the prime mover (5) for turning the movable scroll, and the all-round ring (6, oldham ring) is made so that the movable scroll is rotated to prevent the rotation of the prime mover.

The scroll compressor made as described above performs the following operation.

When power is supplied to the scroll compressor, an induced current is generated between the stator 5a and the rotor 5b of the prime mover 5, and the eccentric shaft 7 coupled to the rotor by the induced current is The movable scroll 3 is rotated by the rotation of the eccentric shaft.

At this time, the refrigerant gas is introduced into the suction chamber (1a) through the suction pipe (8), and then into the compression chamber (3a) through the suction port (not shown) formed on one side of the fixed scroll, the operation It is compressed while moving to the center of the compression chamber by the pivoting movement of the scroll (3), is compressed and discharged through the discharge port (4a) formed in the center side of the fixed scroll (4), and through the discharge chamber (1b) It flows out to the discharge pipe 9.

On the other hand, the conventional scroll compressor is further provided with a backflow prevention device 10 in the upper center portion of the fixed scroll (4).

The reason for this is to prevent the problem occurring during the reverse flow by preventing the refrigerant gas in the discharge chamber 1b from flowing back into the compression chamber 3a during the operation stop or the high pressure ratio operation.

On the other hand, prior to explaining the problem in detail, the aforementioned high pressure ratio operation means that the pressure of the refrigerant gas flowing into the discharge chamber 1b and the discharge pipe 9 is equal to the discharge pressure of the compression chamber 3a. As the operating state becomes larger, in particular, the refrigerant gas flowing out of the discharge pipe does not flow to an external device (not shown) due to a blockage of a capillary tube (not shown), and accumulates continuously so that the pressure in the discharge chamber becomes larger than the discharge pressure of the compression chamber. The operating pressure or outside air condition does not match the condition of the general pressure ratio (discharge pressure / suction pressure) of the compressor, and the abnormal pressure is larger than the discharge pressure of the compression chamber where only a limited pressure ratio can be obtained due to a limited volume change. As an external device is generated under the influence of temperature rise, which is a condition, it means an operating state in which the pressure in the discharge chamber is greater than the discharge pressure in the compression chamber.

Therefore, the problems caused by reverse flow during operation stop and high pressure ratio operation are as follows.

First, when the operation is stopped, the high-pressure refrigerant gas on the discharge chamber 1b side flows back to the compression chamber 3a to rotate the movable scroll 3 in reverse, so that the vortex windings 3b and 4b of the movable scroll and the fixed scroll are rotated; And the surrounding members are damaged or the compressed high-pressure refrigerant gas is expanded and flowed back into the suction chamber 1a, thereby degrading the compression performance of the device.

Second, during the high pressure ratio operation, the high pressure refrigerant gas on the discharge chamber 1b side flows back to the compression chamber 3a and the load of the prime mover 5 is continuously caught on the movable scroll 3, so that the countercurrent force of the high pressure refrigerant gas flows. Due to the excessive driving force of the prime mover, the vortex winding 3b of the movable scroll is subjected to excessive force, so that the vortex shape is misaligned or cracked, and the prime mover is damaged by overload. In the compression chamber 3a, the refrigerant gas is not compressed, but the compressed pressure of the device is deteriorated as the compressed high-pressure refrigerant gas is expanded by the reverse rotation of the movable scroll 3.

In order to solve this problem, the non-return apparatus 10 according to the related art is mounted on the top surface of the fixed scroll 4, as shown in FIG. 2, and the upper portion is cylindrical and the upper portion is inward. A guide 11 having a bent shape (see 11b), the lower part of which has a shape in which two support parts 11a protrude and are opened between the support parts; A bolt 12 for screwing together the upper end of the support part 11a and the fixed scroll 4; Is inserted into the upper portion of the guide consists of a piston valve 13 for selectively opening and closing the opening (not shown) and the discharge port (4a) of the lower end of the guide.

The non-return apparatus 10 according to the prior art made as described above performs the following operation.

First, in the normal operation, since the pressure in the compression chamber 3a is greater than the pressure in the discharge chamber 1b, the piston valve 13 is guided by the earth output of the high pressure refrigerant gas discharged through the discharge port 4a. 11) It is moved a predetermined distance to the top to be caught and stopped by the upper bent portion (11b) of the guide, and the open portion (not shown; the portion open between both supports) is formed in the lower portion of the guide is opened. Therefore, the high pressure refrigerant gas of the compression chamber is discharged to the discharge chamber.

Second, since the pressure in the discharge chamber 1b is greater than the pressure in the compression chamber 3a at the time of operation stop or the high pressure ratio operation, the discharge chamber high pressure refrigerant gas flowing through the upper opening 11c of the guide 11 By the inflow force, the piston valve 13 is moved to the lower portion of the guide to seal the lower opening (not shown) of the guide and the discharge port 4a of the fixed scroll. Therefore, the high pressure refrigerant gas of the discharge chamber does not flow into the compression chamber.

However, the backflow prevention device according to the prior art made as described above has the following problems.

The non-return device 10 according to the prior art has a structure in which a separate guide 11 is mounted on an upper end of the fixed scroll 4 to insert a piston valve 13 therein, thereby allowing the fixed scroll to be mounted on the fixed scroll. When the volume of the discharge port 4a formed and the volume of the piston valve moving space of the guide are summed up, there is a dead volume V, and the high pressure refrigerant gas in the dead volume is compressed in the compression chamber 3a at the time of operation stop or high pressure ratio operation. As a result of the back flow, the problems of the already mentioned members of the spiral bodies 3b and 4b, the prime mover 5, and the like were damaged.

The present invention is to solve the problems of the prior art, and to improve the backflow prevention device of the scroll compressor, the object is to minimize the dead volume and the resulting backflow phenomenon.

1 is a cross-sectional view showing the configuration of a general scroll compressor.

Figure 2 is a detailed view 'A' part of the non-return device of the scroll compressor according to the prior art.

Figure 3 is a detailed view showing the configuration of the backflow prevention device according to the present invention and the operating state during normal operation.

Figure 4 is a detailed view showing the configuration of the backflow prevention device according to the present invention and the operation state during operation stop or high pressure ratio operation.

Explanation of symbols for main parts of the drawings

1: hermetic casing 1a: suction chamber

1b: discharge chamber 2: high and low pressure separator

3: movable scroll 3a: compression chamber

4: fixed scroll 110: branch communication port

120: guide groove 130: valve

140: control unit 141: first locking jaw

142: second locking jaw

In order to achieve the above object, the present invention provides a scroll compressor having a fixed scroll and a movable scroll which are engaged with each other so that the compression chamber is partitioned; In normal operation in which the compression chamber pressure is greater than the discharge chamber pressure, branched communication branched upwardly to the fixed scroll so that the refrigerant gas compressed in the compression chamber flows to the discharge chamber. A sphere is formed; When the compression chamber pressure is lower than the discharge chamber pressure during operation stop or high pressure ratio operation, the backflow prevention is prevented at the branch center of the communication port so that the refrigerant gas in the discharge chamber does not flow back into the compression chamber through the branched communication port. It provides a backflow prevention device of a scroll compressor, characterized in that the means is provided.

Referring to the drawings to describe the above content in more detail as follows.

3 is a detailed view of the main part showing the configuration of the non-return device according to the invention and the operating state in normal operation, Figure 4 is a configuration and operation of the non-return device in accordance with the present invention during operation stop or high pressure ratio operation Main part detail view.

The apparatus for preventing backflow of a scroll compressor according to the present invention, as shown in FIGS. 3 and 4, compresses in the compression chamber during normal operation in which the pressure of the compression chamber 3a is greater than the pressure of the discharge chamber (see 1b in FIG. 1). A branched communication port 110 branched upwardly is formed in the fixed scroll 4 so that the refrigerant gas flows into the discharge chamber, and the compression chamber pressure is applied to the discharge chamber. In operation stop or operation under a high pressure ratio smaller than the pressure, a backflow prevention means is provided at the branch center of the communication port so that the refrigerant gas in the discharge chamber cannot flow back into the compression chamber through the branch communication port.

At this time, the backflow prevention means, as shown in Figure 3, the guide hole is formed vertically upward in the branch center portion C of the branch communication port 110 to communicate with the discharge chamber (1b) It is inserted into the groove 120 and the guide groove, is moved upward along the guide groove in the normal operation to open the branched communication port 110, along the guide groove during operation stop or high pressure ratio operation A valve 130 is moved downward to close the branched communication port, and a control unit 140 is added to maintain a stroke of the valve and at the same time add a sealing force.

And, the control unit 140, as shown in Figure 3, is provided on the upper side of the guide groove 120 formed in the fixed scroll (4), the valve 130 in the normal operation of the branch type The first locking jaw 141 for stopping after opening the communication port 110, and the lower side of the guide groove formed in the fixed scroll, the valve is branched when the operation is stopped or high pressure ratio operation It is made of a second locking step 142 to seal the communication port and stop at the same time.

In addition, the first locking jaw 141 is a separate member formed by screwing the surface facing the discharge chamber 1b of the fixed scroll 4, or in the guide groove 120 of the fixed scroll It can be protruding.

In addition, the second locking jaw 142 is formed to protrude from the guide groove 120 of the fixed scroll (4), or the center (C) width of the branched communication port 110 is the guide groove 120 Steps are processed to be smaller than the width of the step so that the valve 130 is caught in the stepped portion.

In addition, the valve 130 is preferably a piston valve so as to be movable in the guide groove 120 formed in the fixed scroll (4).

The backflow prevention device according to the present invention made as described above performs the following operation.

First, in the normal operation, since the pressure in the compression chamber 3a is greater than the pressure in the discharge chamber 1b, the high pressure refrigerant gas discharged through the central portion C of the branched communication port as shown in FIG. By the valve 130 is moved a predetermined distance to the upper guide groove 120 is stopped by the first locking jaw 141 at the top of the guide groove, and branched communication port 110 formed in the lower guide groove Will be opened. Therefore, the high pressure refrigerant gas of the compression chamber is discharged to the discharge chamber through the branched communication port.

Second, since the pressure in the discharge chamber 1b is greater than the pressure in the compression chamber 3a during the operation stop or the high pressure ratio operation, the inflow through the upper opening 120a of the guide groove 120 as shown in FIG. 4. By the inflow force of the discharge chamber high pressure refrigerant gas, the valve 130 is moved to the lower portion of the guide groove to close the branch portion and the central portion (C) of the branch-type communication port 110 in the lower guide. Therefore, the high pressure refrigerant gas of the discharge chamber does not flow into the compression chamber.

So far, the present invention has been described with reference to the preferred embodiments, and those skilled in the art to which the present invention pertains to the detailed description of the present invention and other forms of embodiments within the essential technical scope of the present invention. Could be implemented. Herein the essential technical scope of the present invention is shown in the claims.

As described above, the reverse flow prevention device of the scroll compressor according to the present invention has a branched communication port, a guide groove, and a valve in the fixed scroll itself, which has the following effects.

First, since the backflow of refrigerant gas can be minimized during operation stop or high pressure ratio operation, the damage of the device can be minimized and the compression performance of the device can be minimized by minimizing the reverse expansion phenomenon of the already compressed high-pressure refrigerant gas. Can improve.

Second, the backflow prevention device according to the present invention is simple in structure compared to the prior art can reduce the cost accordingly.

And it includes all the effects mentioned in the detailed description of the invention.

Claims (7)

A scroll compressor having a fixed scroll and a movable scroll provided in a closed casing and engaged with each other so as to partition the compression chamber, A branched communication port branched upward is formed on the fixed scroll so that the refrigerant gas compressed in the compression chamber flows to the discharge chamber. A guide groove formed vertically upwardly at the branch center portion of the branched communication port to communicate with the discharge chamber, and inserted into the guide groove and moved upwardly along the guide groove to open the branched communication hole; And a back flow preventing means having a valve which moves downward along the guide groove to close the branch communication port, and a control unit which maintains the stroke distance and adds a sealing force at the same time. Backflow prevention device of scroll compressor. delete The method of claim 1, The control unit; A first latching jaw provided at an upper side of the guide groove formed in the fixed scroll to stop the valve after opening the branch communication port; It is provided on the lower side of the guide groove formed in the fixed scroll, the valve is a reverse flow prevention device of the scroll compressor, characterized in that the valve is made of a second locking step to stop at the same time to seal the branched communication port. The method of claim 3, wherein The first locking step is a reverse flow prevention device of the scroll compressor, characterized in that the screw is coupled to the surface facing the discharge chamber of the fixed scroll. The method of claim 3, wherein The first locking step is a backflow prevention device of the scroll compressor, characterized in that protruding from the guide groove of the fixed scroll. The method of claim 3, wherein The second locking step is a backflow prevention device of the scroll compressor, characterized in that the protrusion formed in the guide groove of the fixed scroll. The method of claim 3, wherein The second locking jaw, the reverse flow prevention device of the scroll compressor, characterized in that the central width of the branched communication port of the fixed scroll is smaller than the width of the guide groove so that the valve is caught in the step portion.