KR100834017B1 - Bypass apparatus for scroll compressor - Google Patents

Abstract

In the bypass device of the scroll compressor according to the present invention, at least one pair of compression chambers is formed in engagement with a turning scroll and at least one along the path of the compression chamber so that the compressed gas is discharged to the discharge space in advance in the compression chamber. Fixed scroll in which the above bypass hole is formed; A valve guide installed outside the bypass hole of the fixed scroll; And a sliding valve which is slidably coupled to the valve guide to open and close the bypass hole of the fixed scroll, by installing a valve guide having a plurality of sliding valves mounted on an upper surface of the hard plate portion of the fixed scroll. The pressure can be maintained at a constant pressure, and the bypass valve can be easily and easily installed, thereby reducing material cost and reducing assembly time.

Description

Bypass device for scroll compressors {BYPASS APPARATUS FOR SCROLL COMPRESSOR}

1 is a cross-sectional view showing an example of a conventional scroll compressor,

2 is an exploded perspective view showing the fixed scroll back of the conventional scroll compressor;

3 is a cross-sectional view showing an example of the scroll compressor of the present invention;

Figure 4 is an exploded perspective view showing a bypass valve in the scroll compressor of the present invention,

5 is a cross-sectional view showing the operation of the bypass valve in the scroll compressor of the present invention,

Figure 6 is a cross-sectional view showing a modification of the bypass valve in the scroll compressor of the present invention.

** Description of symbols for the main parts of the drawing **

6: fixed scroll 6c: discharge port

6d: bypass hole 110: valve guide

111 ~ 115: Valve hole 116: Supporting protrusion

111a ~ 115a: Valve stopper 121 ~ 125: Sliding valve

130: fastening bolt

The present invention relates to a bypass device of a scroll compressor, and more particularly, to a bypass device of a scroll compressor to open and close according to the pressure change of the compression chamber to prevent overcompression.

In general, a scroll compressor is a high-efficiency low noise compressor widely applied to an air conditioner. A plurality of compression chambers are formed in pairs between scrolls while the two scrolls rotate relative to each other, and the compression chamber continuously moves toward the center. The volume decreases and the refrigerant gas is continuously sucked and compressed to be discharged.

As shown in FIG. 1, a conventional scroll compressor includes a casing 1 having a gas suction pipe SP and a gas discharge pipe DP, and a main frame fixed to upper and lower sides of an inner circumferential surface of the casing 1, respectively. 2) and a subframe (not shown), a drive motor 3 mounted between the main frame 2 and the subframe, and a main frame (B) pressed into the center of the rotor 3B of the drive motor 3. 2) a driving shaft 4 penetrating the driving motor 3 to transmit the rotational force of the driving motor 3, a turning scroll 5 mounted on the main frame 2 and coupled to the driving shaft 4 to make a turning movement, and the turning A fixed scroll 6 for forming a spiral wrap 6a so as to be engaged with the wrap 5a of the scroll 5 to form a plurality of compression chambers P, and fixed to an upper surface of the main frame 2; (5) and the old dam ring (7) to be coupled between the main frame (2) to prevent rotation of the swing scroll (5), High and low pressure separating plate (8) which is coupled to the surface and divides the inside of the casing (1) into the suction space (S1) and the discharge space (S2), and the discharge space by coupling to the center of the rear surface of the hard plate portion of the fixed scroll (6) A plurality of check valves 9 for preventing the reverse flow of the compressed gas discharged to the step S2 and a plurality of the bypass valves in advance along the compression chamber P on the rear surface of the hard plate portion of the fixed scroll 6 to bypass a part of the compressed gas in advance. Bypass valves 11 to 14 are included.

The pivoting scroll (5) is formed on the upper surface of the hard plate portion with a wrap (6a) of the fixed scroll (6) to be described later to form a spiral wrap (5a) forming a pair of compression chamber (P) in the involute shape In the center of the bottom surface of the hard plate portion of the turning scroll 5, a boss portion 5b coupled to the driving shaft 4 to receive power from the driving motor 3 is formed.

The fixed scroll (6) is in the involute shape of the fixed wrap (6a) to form a pair of compression chamber (P) by engaging the pivoting wrap (5a) on the bottom surface of the hard plate portion as shown in Figs. And a suction port 6b communicating with the gas suction pipe SP at a side of the hard plate portion of the fixed scroll 6, and a final compression chamber P at the center of the top surface of the hard plate portion of the fixed scroll 6. A discharge port 6c is formed in communication with the center of the discharge port 6c for discharging the compressed gas into the discharge space S2 of the casing 1, and the initial compression chamber P and the middle of the discharge port 6c along the compression chamber. A plurality of bypass holes 6d are formed in the compression chamber P, respectively, penetrating toward the rear surface of the hard plate portion to bypass a part of the compressed gas.

The bypass valves 11 to 14 are formed in a plate body to open and close the upper end of each bypass hole 6d of the fixed scroll 6 as shown in FIGS. 1 and 2 and fixed to an outer surface of the fixed scroll 6. Retainer for limiting the opening amount of the valve plate (11a-14a) and the valve plate (11a-14a) to be fixed to the fixed scroll (6) together to be fixed to the fixed scroll (6) 11b-14b).

In the figure, reference numeral 3A denotes a stator, and 4a denotes an oil passage.

The conventional scroll compressor as described above operates as follows.

That is, when power is applied to the drive motor 3, the turning scroll 5 is rotated by the old dam ring 7 while the drive shaft 4 rotates together with the rotor 3B of the drive motor 3. In the upper surface of the frame (2), the pivoting movement is made by an eccentric distance, and a pair of compression chambers (P) between the fixed wrap (5a) of the fixed scroll (5) and the swing wrap (6a) of the swing scroll (5) ), And the compression chamber (P) moves to the center by the continuous turning motion of the turning scroll (5) to decrease the volume to suck and compress the refrigerant gas, and the compressed refrigerant discharges the discharge port of the fixed scroll. Through the discharge through the upper space, that is, the discharge space (S2) of the high and low pressure separating plate (8).

At this time, if the operation compression ratio during the compression of the refrigerant gas is set higher than the designed compression ratio, the gas pressure in the compression chamber has not yet reached the discharge pressure, causing insufficient compression, and the refrigerant may flow back from the discharge chamber to the compression chamber. If the pressure ratio is lower than the design pressure ratio, even if the gas pressure in the compression chamber is equal to the discharge pressure, compression will continue if the discharge start angle is not reached yet, causing overcompression loss. When overcompression occurs as described above, the bypass valves 11 to 14 are automatically opened and closed according to the pressure difference between the compression chamber P and the discharge space S2, and a portion of the compressed gas is pre-flowed to rotate the scroll scroll. The starting torque in (5) is reduced or the lap damage due to overcompression is prevented in advance.

However, in the conventional scroll compressor as described above, as the plurality of bypass valves 11 to 14 are independently installed on the upper surface of the fixed scroll 6, the installation itself is not easy due to the interference between the valves. In addition, there is a problem that the production cost and productivity is reduced due to the increased material cost and the complicated assembly process.

In addition, since the bypass valves 11 to 14 are self-rigid lead type valves, there is a problem that the compression loss of the compressor is further increased without being opened quickly during overcompression.

The present invention has been made in view of the problems of the bypass device of the conventional scroll compressor as described above, by simplifying the structure of the bypass valve and facilitate the installation of the scroll compressor to reduce the production cost and increase the productivity It is an object of the present invention to provide a pass device.

Another object of the present invention is to provide a bypass device for a scroll compressor that can be quickly opened during overcompression to reduce the compression loss of the compressor.

In order to achieve the object of the present invention, two pairs of compression chambers are formed in engagement with the turning scroll, and at least one bypass along the path of the compression chamber so that the compressed gas is discharged to the discharge space in advance in the compression chamber. A fixed scroll in which a hole is formed and one discharge port is formed so as to discharge the refrigerant compressed through the discharge space in the final compression chamber; A plurality of support protrusions are formed to maintain a predetermined interval with respect to the surface facing the fixed scroll, and are installed outside the bypass hole of the fixed scroll so that the support protrusions are opened toward the discharge space. A valve guide having a plurality of valve holes respectively corresponding to the bypass hole and one discharge port; And a plurality of sliding valves slidingly coupled to the valve hole of the valve guide to open and close the bypass hole and the discharge space of the fixed scroll and between the discharge port and the discharge space, respectively. .

Hereinafter, a bypass device for a scroll compressor according to the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

Figure 3 is a cross-sectional view showing an example of the scroll compressor of the present invention, Figure 4 is an exploded perspective view showing a bypass valve in the scroll compressor of the present invention, Figure 5 is a cross-sectional view showing the operation of the bypass valve in the scroll compressor of the present invention.

As shown in the scroll compressor according to the present invention, the main frame (2) is fixedly installed on the inner circumferential surface of the casing (1), and the swinging scroll (5) for pivoting on the upper surface of the main frame (2) and The fixed scroll (6) is fixedly installed so as to form two pairs of compression chambers (P) moving in series with each other, and a bypass for discharging a part of the compressed gas to the rear surface of the hard plate portion of the fixed scroll (6). The unit 100 is installed and configured.

The fixed scroll (6) is formed in the involute shape of the fixed wrap (6a) to form a pair of compression chamber (P) by engaging the swing wrap (5a) of the swing scroll (5) on the bottom surface of the hard plate portion In addition, a suction port 6b communicating with the gas suction pipe SP is formed at the side of the hard plate portion of the fixed scroll 6, and a central portion of the final compression chamber P is disposed at the center of the upper surface of the hard plate portion of the fixed scroll 6. A discharge port 6c is formed in communication with the center to discharge the compressed gas into the discharge space S2 of the casing 1, and along the path of the compression chamber P toward the upper surface of the hard plate portion of the fixed scroll 6. A plurality of bypass holes 6d penetrating toward the discharge space S2 are formed at appropriate positions.

The bypass hole 6d may have the same cross-sectional area at both ends of the upper and lower ends so as to have the same shape as the outer circumferential surface of the sliding valves 121 to 125 which will be described later, or may be formed as a truncated cone having a narrower cross-sectional area toward the outside. The bypass hole 6d may be formed in various shapes such as an angular shape in addition to a circular shape.

The bypass unit 100 is a valve guide 110 which is installed on the upper surface of the fixed scroll (6) to accommodate the discharge port (6c) and all the bypass holes (6d) of the fixed scroll (6) together as shown in FIG. And a plurality of sliding valves 121 to 125 slidingly coupled to the valve guide 110 to open and close the discharge port 6c and the bypass hole 6d of the fixed scroll 6, respectively.

The valve guide 110 is formed with a plurality of valve holes 111 to 115 so as to axially coincide with the discharge port 6c and the bypass hole 6d of the fixed scroll 6, and the valve holes 111 to 115. ) Valve stops 111a to 115a for limiting the opening amount of the sliding valves 121 to 125 are formed stepped or penetrated smaller in diameter than the valve holes 111 to 115, although not shown in the drawing. A valve stop plate having a hole may be provided on the outer side of the valve guide.

In addition, the valve guide 110 is provided separately or integrally provided with a plurality of support protrusions 116 at a predetermined height on the surface facing the fixed scroll 6, the space between the support protrusions 116 discharge space Open toward S2 to form the discharge flow path F. FIG.

In addition, a through hole 116a may be formed in the support protrusion 116 such that a fastening bolt 130 for fixing the valve guide 110 to the fixed scroll 6 passes therethrough.

The sliding valves 121 to 125 may be formed of an engineered plastic material such that the sliding valves 121 to 125 are light and high in strength so as not to be worn with the metallic valve guide 110 so as to quickly react to the pressure change of the compression chamber.

In addition, the sliding valves 121 to 125 are formed in the same rod-like outer diameter of the upper and lower ends as shown in FIG. 5 or further away from the discharge port 6c or the bypass hole 6d as shown in FIG. Since the cross-sectional area is formed into a truncated cone shape, it is not necessary to provide a separate valve stop means, and the sealing area can be increased to prevent leakage of the compression chamber refrigerant during normal operation. In addition, the sliding valves 121 to 125 may be formed in a circular cross-sectional shape or an angled cross-sectional shape.

Meanwhile, a separate elastic member (not shown) such as a compression spring may be installed at the rear side of the sliding valves 121 to 125 so that the sliding valves 121 to 125 can be opened at an appropriate time.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

Reference numeral 6c in the figure is a fastening groove.

The bypass device of the scroll compressor of the present invention as described above has the following effects.

That is, when the driving shaft 4 is rotated by applying power to the driving motor 3, the turning scroll 5, which is eccentrically coupled to the driving shaft 4, rotates along a predetermined trajectory, and the turning in this process. The two pairs of compression chambers P formed between the scroll 5 and the fixed scroll 6 continuously move toward the center of the pivoting movement to decrease the volume so that refrigerant gas is continuously sucked and compressed, and then the compression chamber. The refrigerant compressed at (P) passes through the discharge port 6c and pushes up the sliding valve 121 in the center. The sliding valve is pushed up by the compressed refrigerant and the discharge flow path F is opened to cool the refrigerant in the compression chamber. Is discharged to the discharge space S2 of the casing 1 through the discharge passage F.

Here, when the operating pressure ratio of the compressor is lower than the set pressure ratio by installing a valve guide 110 provided with a plurality of sliding valves 121 to 125 on the upper surface of the fixed plate (6) the intermediate compression chamber Part of the refrigerant in (P) is discharged to lower the pressure in the compression chamber to an appropriate pressure, thereby lowering the load on the motor and increasing efficiency. For example, as shown in FIG. 5, when the pressure of the compression chamber P is equal to or higher than a predetermined pressure, the respective sliding valves 122 to 125 provided on the path of the compression chamber P are pushed upwards to bypass the bypass holes. 6d is made to communicate with discharge space S2, and the refrigerant | coolant part of compression chamber P flows out into discharge space S2 through this bypass hole 6d, and the pressure of compression chamber P is set as the pressure ratio. Will be lowered to. At this time, the sliding valve (122 ~ 125) is moved within the range that the upper end surface is caught off the valve stopper (122a ~ 115a) provided in the valve hole (112 ~ 115) of the valve guide (110).

On the other hand, if the starting torque is too large when the compressor is started, the input load of the motor may increase rapidly and the efficiency of the motor may be greatly reduced. Therefore, when the pressure in the initial compression chamber P is higher than or equal to the predetermined pressure, Due to the pressure, the sliding valve 122 close to the suction side is pushed up, and as the sliding valve 122 is pushed up, the discharge flow path F is opened so that a part of the refrigerant in the initial compression chamber is discharged to the discharge space S2 in advance. It leaks and the torque required for starting is reduced.

In the bypass device of the scroll compressor according to the present invention, a valve guide having a plurality of sliding valves is installed on an upper surface of the fixed plate portion of the fixed scroll, so that the pressure in the compression chamber maintains a constant pressure. Simple and easy installation saves material cost and reduces assembly labor.

Claims (8)

Two pairs of compression chambers are formed in engagement with the turning scroll, and at least one bypass hole is formed along the path of the compression chamber so that the compressed gas flows out into the discharge space in advance. A fixed scroll through which one discharge port is formed so as to discharge the compressed refrigerant penetrating into the discharge space; A plurality of support protrusions are formed to maintain a predetermined interval with respect to the surface facing the fixed scroll, and are installed outside the bypass hole of the fixed scroll so that the support protrusions are opened toward the discharge space. A valve guide having a plurality of valve holes respectively corresponding to the bypass hole and one discharge port; And And a plurality of sliding valves slidingly coupled to the valve hole of the valve guide to open and close the bypass hole and the discharge space of the fixed scroll and between the discharge port and the discharge space, respectively. The method of claim 1, And the valve guide is configured to accommodate a plurality of bypass holes and one discharge port together. delete The method of claim 1, Bypass device of the scroll compressor is formed at the end of the valve hole stepped valve stop limiting the opening amount of the sliding valve. The method of claim 1, Bypass device of the scroll compressor is provided on the outer surface of the valve guide is provided with a valve stop plate for limiting the opening amount of the sliding valve by covering the valve hole. delete The method of claim 1, And the sliding valve and the valve hole are formed in a shape having the same cross-sectional area at both ends. The method of claim 1, And the sliding valve and the valve hole are narrower in cross section as they move away from the bypass hole.

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