KR20010107308A - structure for supporting pressure sharing plate in scroll-type compressor - Google Patents

Abstract

The present invention relates to a pressure separator support structure of a scroll fluid machine, and to maintain the position of the pressure separator plate supported on the upper frame accurately without using a separately made structure and to fix the pressure separator plate supported thereafter. In this case, even if the supported pressure separator is not held as a separate assembly jig, the position shift in the radial direction is hardly caused.

To this end, in the present invention, a plurality of lower legs 101 are formed in a vertical direction upwardly at the periphery of the upper frame 5, and formed in the upper frame 5 at the periphery of the pressure separator plate 12. In the plurality of upper legs 102 formed in a vertically downward state in contact with each lower leg 101, the inner and outer edges of the upper surface of each lower leg 101 formed in the upper frame 5 The stepped portion 103 is formed at one edge portion of the edge portion, and a step groove 104 is formed at one edge portion of the inner and outer edge portions of the lower surface of each upper leg 102 formed on the pressure separator plate 12. It is a pressure separation plate support structure of a scroll fluid machine in which the pressure separation plate 12 is supported by the upper frame 5 while the step 103 is fitted in the step groove 104.

Description

Structure for supporting pressure sharing plate in scroll-type compressor

The present invention relates to the field of scroll fluid machines, and more particularly, a scroll type for supporting the upper frame such that the fixed scroll has an axial stress in the step before fixing the pressure separator separating the high pressure part and the low pressure part during assembly. A pressure separator support structure of a fluid machine.

In general, a scroll fluid machine is a device that sucks and compresses a fluid (refrigerant, air, water, etc.) by using a fixed scroll, which is a pair of scrolls, and a revolving scroll, and then discharges or immediately sucks and pumps. It includes a scroll compressor, an air compressor in which the working fluid is air, and the like. The configuration includes a main body part, which generally constitutes an overall appearance, a power generation unit for generating driving force, and a driving force generated by the power generation unit. It is divided into a compression unit for compressing and then discharging, and the structure of the compression unit has almost the same structure as almost all scroll fluid machines.

In one application example of the scroll type fluid machine, a scroll compressor whose fluid is a refrigerant is used as an element constituting a refrigeration cycle such as a refrigerator, a general air conditioning air conditioner, a car air conditioner, and the like. When a scroll compressor is used as a component of a refrigeration cycle of a refrigerator or a general air conditioner, it is provided separately in the main body. However, when a scroll compressor is used as a component of a refrigeration cycle of a vehicle air conditioner, the engine power of a vehicle is usually used as it is. Therefore, there is no separate power generating unit.

Then, the scroll compressor which is an element constituting the refrigeration cycle of the refrigerator and the general air conditioner for the purpose of understanding the present invention and related art will be described in detail as follows.

A suction pipe 2 for sucking refrigerant to one side of the compressor main body 1 having a space therein is fixed, and the space in the compressor main body 1 includes a stator 3a and a rotor 3b. A motor 3 for generating a driving force is fixed, and a crank shaft 4 is press-fitted to rotate under the driving force of the motor 3 at the center of the rotor 3b constituting the motor. The upper and lower parts are bearing-supported by the upper frame 5 and the lower frame 6 fixed in the compressor main body 1, respectively. The upper end of the crankshaft 4 has an involute pivoting wrap ( The swinging scroll 8 having 8a) is coupled in an eccentric state, and the swinging scroll 8 only rotates between the upper frame 5 and the swinging scroll 8 in accordance with the rotation of the crankshaft 4. The oldham ring (7) is installed The upper frame 5 has an involute-shaped fixed wrap 10a to be engaged with the pivoting wrap 8a of the pivoting scroll 8 to form a compression chamber 9 together with the pivoting scroll 8. Fixed scroll 10 is coupled, the fixed scroll through-hole 11 is formed in the center of the fixed scroll so that the refrigerant compressed in the compression chamber (9) exits the compression chamber, the fixed scroll (10) The pressure separation plate 12 is supported on the upper portion of the pressure separation plate 12 so that the outer periphery is fixed to the upper end of the compressor main body 1 so as to separate the high pressure portion and the low pressure portion, and the discharge chamber 13 is formed on the upper portion of the pressure separation plate. The lower end of the cap 14 is fixed to the compressor main body 1 together with the pressure separating plate 12, and through the fixed scroll hole 11 formed in the fixed scroll 10 at the center of the pressure separating plate 12. The refrigerant exiting the compression chamber 9 continues to be formed by the cap 14. Pressure separation plate through hole 15 is formed to be moved upward toward the chamber 13, the pressure separation plate through hole 15 to exit from the compression chamber (9) on the upper surface of the pressure separation plate (12) A check valve 16 is installed to allow the refrigerant moving upward through the discharge chamber 13 to prevent the refrigerant flowing into the discharge chamber from being flowed back to the discharge chamber 13. A discharge pipe 17 for discharging the refrigerant in the chamber 13 is fixed, and the fixed passage 10 has a moving passage 18 for moving some compressed refrigerant gas in the compression chamber 9 upward. The fixed scroll 10 is formed on the upper surface of the fixed scroll 10 so that the pressure separating plate 12 is supported by the upper frame 5 so that the outer periphery thereof is fixed to the upper end of the compressor body 1. And move between the pressure separation plate (12) A back pressure chamber 19 is formed along the circumference to fill the refrigerant moving upwardly through the furnace 18, and is disposed between the upper surface of the fixed scroll 10 and the lower surface of the pressure separating plate 12. A ring-shaped inner sealing member 20 and an outer sealing member 21 are provided to seal the back pressure chamber 19.

Therefore, when the refrigeration cycle is operated while the scroll compressor is used for a refrigeration cycle of a refrigerator or an air conditioner for general air conditioning, the rotor 3b of the motor 3 fixed to the space part of the compressor main body 1 rotates. Therefore, the crankshaft 4 press-fitted in the center of the rotor also rotates, wherein the turning scroll 8 coupled to the upper end of the crank shaft in an eccentric state is the upper frame 5 and the turning scroll ( 8) to the orbital movement by the old dam ring (7) installed between.

On the other hand, the crankshaft 4 which rotates together by the rotation of the rotor 3b constituting the motor 3, the upper and lower frames 5, the upper and lower parts of which are fixed to the space in the compressor main body 1 Since the bearing is supported by (6), it can be understood that it is stable without being shaken in the rotating process.

When the turning scroll 8 is turned as described above, the turning wrap 8a of the turning scroll 8 and the fixed wrap 10a of the fixed scroll 10 coupled to the upper frame 5 each have a single volute shape. In view of the fact that the compression chamber 9 is formed in engagement with each other, the volume of the compression chamber is changed, and the suction, compression, and discharge strokes are continuously repeated. In this suction stroke, the refrigerant gas is supplied to the compressor main body 1. Is sucked into the compressor main body 1 through a suction pipe 2 fixed to one side of the peripheral surface of the pump, and then sucked into the compression chamber 9 through a passage (not shown). It is compressed at the compression stroke, and the compressed refrigerant gas exits the compression chamber 9 through the fixed scroll through hole 11 formed at the center of the fixed scroll 10 during the discharge stroke.

The high pressure refrigerant exiting the compression chamber 9 through the fixed scroll through hole 11 of the fixed scroll 10 is supported by the upper frame 5 and its outer circumference is fixed to the compressor main body 1 so that the high pressure portion And continues upward through the pressure separating plate through-hole 15 of the pressure separating plate 12 separated by the low pressure part, and then passes through the check valve 16 installed on the upper surface of the pressure separating plate 12. It enters into the discharge chamber 13 formed by 14, and then it is discharged through the discharge pipe 17 fixed in place at the circumferential surface of the cap 14.

On the other hand, when the refrigerant is sucked into the compression chamber 9 formed by the swinging scroll 8 and the fixed scroll 10 and then exits the compression chamber, the fixed pressure is caused by the pressure in the compression chamber 9. The scroll 10 tries to move as far as possible in the axial direction opposite to the turning scroll 8 as proportional to the pressure of the compression chamber 9, if the fixed scroll 10 is opposed to the turning scroll 8. If the maximum movement in the direction between the end of the fixed wrap (10a) of the fixed scroll 10 and the bottom surface of the turning scroll (8) and between the end of the turning wrap (8a) and the bottom surface of the fixed scroll (10) Since the gap of the gap is more than necessary, the refrigerant gas in the compression chamber (9) leaks through the gap between the swing wrap (8a) of the swing scroll (8) and the fixed wrap (10a) of the fixed scroll (10) Is generated.

However, when the refrigerant is compressed in the compression chamber 9 and then discharged, a part of the refrigerant is moved upwardly through the moving passage 18 formed in the fixed scroll 10 to exit the compression chamber 9, The escaped refrigerant is formed along the circumference on the upper surface of the fixed scroll 10 to be filled into the back pressure chamber 19 located between the fixed scroll and the pressure separation plate 12, so that the back pressure chamber is fixed at this time. As the back pressure acts, the fixed scroll 10 has an axial pressing force toward the swing scroll 8, so that the fixed scroll 10 rotates while the refrigerant is compressed in the compression chamber 9 and then discharged. Fixed end 10a of the fixed scroll 10 and the bottom surface of the pivoting scroll 8 and fixed with the tip of the pivoting wrap 8a of the pivoting scroll, as not maximally moved in the axial direction opposite to (8). Bottom side of scroll (10) The gap does not occur more than necessary, which causes the refrigerant gas in the compression chamber 9 to close the gap between the swing wrap 8a of the swing scroll 8 and the fixed wrap 10a of the fixed scroll 10. Easily leak through the problem will not occur.

In addition, when the refrigerant enters and fills the back pressure chamber 19, the pressure of the back pressure chamber is medium pressure, rather than the compressed refrigerant discharge flow path (the fixed scroll hole formed in the fixed scroll and the pressure separator plate formed in the pressure separator plate). Since it is in a low state, the refrigerant in the compressed refrigerant discharge passage tries to leak into the back pressure chamber 19 on the lower pressure side through the gap between the fixed scroll 10 and the pressure separating plate 12 and at the same time in the back pressure chamber 19. The refrigerant is to leak out of the back pressure chamber 19, which is a lower pressure side through the gap between the fixed scroll 10 and the pressure separator plate 12, the inner side between the fixed scroll 10 and the pressure separator plate 12 Since the sealing member 20 and the outer sealing member 21 are installed to seal the inside and the outside of the back pressure chamber 19, the refrigerant on the high pressure side leaks into the back pressure chamber or the inside of the back pressure chamber 19 What is refrigerant leakage low pressure side is almost impossible.

Looking at the process of fixing the pressure separating plate 12 to separate the high pressure and low pressure in the process of assembling each component of the scroll compressor as described above as follows.

The upper frame 5 is fixed to the space in the compressor main body 1 so that the upper frame supports the upper end of the crank shaft 4 press-fitted to the rotor 3b of the motor 3, and the crank shaft Eccentrically fix the swinging scroll (8) to the orbital movement by the old dam ring (7), the upper frame (5) fixed scroll to form a compression chamber (9) between the swinging scroll (8) 10) After the pressure separator plate 12 is placed on the upper frame 5 after the combination, the pressure separator plate is in contact with the upper end of the upper frame 5 at the lower end of the pressure separator plate 12. It is supported by (5).

Then, the cap 14 is placed on the edge of the upper surface of the pressure separator 12 in a state where the lower end is in contact with the upper periphery of the compressor body 1, the outer circumference of the pressure separator 12, and the cap 14 of the cap 14. When the bottom circumference is welded and fixed integrally, the pressure separator 12 is fixed in a state of being supported by the upper frame 5 so that the lower part is a low pressure part and the upper part is a high pressure part, respectively, based on the pressure separator plate 12. When the pressure separating plate 12 is fixed while being supported by the upper frame 5, the fixed scroll 10 is disposed between the fixed scroll and the pressure separating plate 12 so as to secure compliance in the axial direction. Must maintain the predetermined horizontal interval accurately when the refrigerant is sucked into the compression chamber 9 by the rotation of the turning scroll 8 in the process of using the machine after assembly, and then repeatedly compressed and discharged. Refrigerant Filled in Seal 19 Due to the pressure of the fixed scroll (10) smoothly has an axial pressing force toward the turning scroll (8).

Therefore, in a scroll fluid machine such as a scroll compressor, the position of the upper frame when the pressure separating plate is supported on the upper frame 5 or when it is fixed after supporting the pressure separating plate 12 during assembly is fixed. It is understood that it should be kept precisely without moving radially, which requires a pressure separator support structure for supporting the pressure separator 12 to the upper frame 5.

Then, with reference to the accompanying Figures 1 to 2 attached to the conventional pressure separator support structure as follows.

A plurality of lower legs 51 are formed at the periphery of the upper frame 5 upwardly, and each lower leg 51 formed at the upper frame 5 is formed at the periphery of the pressure separating plate 12. A plurality of upper legs 52 are formed in a vertical direction in contact with the lower portion, and the lower concave groove 53 with an upper portion open to an upper surface of each lower leg 51 formed in the upper frame 5. Is formed, the upper concave groove 54 is formed on the lower surface of each upper leg 52 formed in the pressure separating plate 12 with the lower open, each lower leg formed in the upper frame (5) A part of the fitting piece 55 is fitted into the lower recess groove 53 of the 51 and the fitting piece 55 is inserted into the upper recessing groove 54 of each upper leg 52 formed in the pressure separating plate 12. The rest of the structure is fitted.

The process of supporting the pressure separator plate to the upper frame by the conventional pressure separator support structure configured as described above will be described in detail.

When the fitting piece 55 is fitted into the lower recessed groove 53 of each lower leg 51 formed in the state where the upper frame 5 is fixed to the space part in the compressor main body 1, the upper part is vertically upward. Since the height of the fitting piece is higher than the depth of the lower recessed groove 53, the fitting piece 55 is inserted into the lower recessed groove 53 of each lower leg 51 formed only in the upper frame 5. The remaining portion is exposed to the outside.

In this state, if the pressure separation plate 12 is placed on the upper part of the upper frame 5, a fitting piece into which a part is inserted into the lower recessed groove 53 of each lower leg 51 formed in the upper frame 5. The external exposed portion of the 55 is fitted into the upper recessed groove 54 of each upper leg 52 formed in the pressure separating plate 12, and the external exposed portion of the fitting piece 55 is the pressure separating plate 12. Each upper leg 52 formed in the upper frame 5 has each lower leg 51 formed in the pressure separating plate 12 at any moment when it is completely fitted into the upper recess groove 54 of each upper leg 52 formed in Since the pressure separating plate 12 is supported by the upper frame 5 because it is in contact with each other, in the state where the pressure separating plate 12 is supported by the upper frame 5 as described above, A part is fitted into the lower recessed groove 53 of each lower leg 51 formed in the upper frame 5 as well as the fitting piece 55 As the remaining portion of the upper portion is inserted into the upper recessed groove 54 of the upper leg 52 formed in the pressure separator 12, the positional movement in the radial direction occurs even before the pressure separator 12 is fixed. There is nothing to do.

However, the conventional pressure separator support structure is such that the separately made fitting piece is inserted into the lower recess groove of each lower leg formed in the upper frame and the upper recess groove of each upper leg formed in the pressure separator plate, thereby increasing the number of parts and the processing process. This increase, of course, there is a problem in that the manufacturing cost is increased because the lower concave groove formed in each lower leg formed in the upper frame or the upper concave groove formed in each upper leg formed in the pressure separator plate must be accurately dimensioned.

In addition, when a separately made fitting piece is fitted into the lower recessed groove of each lower leg formed in the upper frame and the upper recessed groove of each upper leg formed in the pressure separator, the gap between the fitting piece and the lower leg is inwardly based on the fitting piece. The gap between the fitting piece and the upper leg is also present inside and outside with respect to the fitting piece, even though the pressure separation plate is supported on the upper frame, even if the position is maintained correctly. Thereafter, since the position of the pressure separation plate is fixed in the process of fixing the pressure separation plate, the assembly of the pressure separation plate is used before the operation of fixing the pressure separation plate. There is also a problem that productivity is lowered due to deterioration of assembly workability. The.

The present invention has been made in order to solve the above-mentioned problems, and when the fixed pressure separator is supported while maintaining the position of the pressure separator plate supported on the upper frame without using a separately made structure, Even if the supported pressure separator is not held as a separate assembly jig, the purpose is to prevent the position shift in the radial direction from occurring.

1 is a vertical cross-sectional view showing a scroll compressor having a conventional pressure separator support structure.

Figure 2 is an exploded perspective view showing a part of the conventional pressure separator support structure cut

Figure 3 is a longitudinal sectional view showing a scroll compressor having a pressure separator support structure of an embodiment of the present invention.

Figure 4 is an exploded perspective view showing a part of the pressure separation plate support structure of an embodiment of the present invention

Explanation of symbols for the main parts of the drawings

5. Upper frame 12. Pressure separator

101. Lower Leg 102. Upper Leg

103. Stepped 104. Stepped

According to the embodiment of the present invention for achieving the above object, a plurality of lower legs are formed in a vertically upward state in the circumference of the upper frame, the circumferential portion of the pressure separation plate to be in contact with each lower leg formed in the upper frame In the plurality of upper legs are formed in a vertical direction downward, the upper step is formed on one of the edge portion of the inner and outer edges of the upper surface of each lower leg formed in the upper frame, each upper portion formed on the pressure separator One of the inner and outer edge portions of the lower surface of the leg is provided with a pressure divider support structure of a scroll fluid machine in which a pressure divider is supported on the upper frame by forming a step groove so that the step is fitted in the step groove.

According to another aspect of the present invention for achieving the above object, a plurality of lower legs are formed in a vertically upward state on the circumference of the upper frame, the circumferential portion of the pressure separating plate is in contact with each lower leg formed in the upper frame In the form of a plurality of upper legs in a vertically lowered state, the step formed on one of the edge portion of the inner and outer edges of the lower surface of each upper leg formed in the pressure separation plate, each formed on the upper frame One of the inner and outer edges of the upper surface of the lower leg is provided with a stepped groove so that the pressure separator plate supporting structure of the scroll fluid machine is provided with a pressure separator plate supported by the upper frame with the stepped portion fitted into the stepped groove. .

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

3 is a longitudinal cross-sectional view of a scroll compressor having a pressure separating plate supporting structure according to an embodiment of the present invention, and FIG. 4 is an exploded perspective view showing a partial cutting of the pressure separating plate supporting structure according to an embodiment of the present invention. For example, a plurality of lower legs 101 are formed at the periphery of the upper frame 5 upwardly, and each lower leg formed at the upper frame 5 is formed at the periphery of the pressure separator 12. A plurality of upper legs 102 are formed in a vertically downward state to be in contact with 101, and a step 103 is formed at an outer edge portion of the upper surface of each lower leg 101 formed in the upper frame 5. The upper side of the lower edge of each upper leg 102 formed in the pressure separation plate 12 is formed with a step groove 104 along the circumference to support the pressure separation plate 12 to the upper portion of the pressure separation plate 12. Placed on the frame (5) Standing the stepped structure 103 of each lower leg 101 is formed in the upper frame is fitted with danhom 104 of each upper leg 102 formed in a pressure distribution plate (12).

The process of supporting the pressure separator plate to the upper frame by the pressure separator plate support structure according to the embodiment of the present invention configured as described above is as follows.

When the pressure separating plate 12 is placed on the upper part of the upper frame 5 while the upper frame 5 is fixed to the space in the compressor main body 1, each lower leg formed in the upper frame 5 ( Steps 103 are formed along the periphery of the upper outer edge portion of the upper surface 101, and a step groove along the periphery of the lower outer edge portions of the upper legs 102 formed on the pressure separating plate 12. Considering that the 104 is formed, the step 103 is fitted into the step groove 104, and each upper leg formed at the pressure separation plate 12 at any moment when the step 103 is completely fitted into the step groove 104 is formed. The pressure separating plate because all parts except the step groove 104 part of the lower surface of 101 are in contact with the entire part except the step 103 part of the bottom surface 101 formed in the upper frame 5. (12) is supported on the upper frame (5), the pressure separating plate (12) ) Is supported on the upper frame 5, each step 103 of each lower leg 101 formed on the upper frame 5 is formed on the pressure separating plate 12 as described above. Positioning in the radial direction almost does not occur even when the pressure separating plate 12 is fixed by being fitted into the step groove 102 of the ().

In the embodiment of the present invention described above, the upper surface stepped portion 103 of each lower leg 101 formed in the upper frame 5 is formed at the outer edge portion, and each upper portion formed in the pressure separator plate 12. Although the lower end groove 104 of the leg 102 is formed at the outer edge portion, it is not necessarily limited thereto, and the upper end step 101 of each lower leg 101 formed in the upper frame 5 is The step groove 104 formed in the inner edge part and formed in the lower surface of each upper leg 102 formed in the pressure separator 12 may be formed in the inner edge part along the periphery.

In addition, in an embodiment of the present invention, the stepped portion 103 is formed on the upper surface of each lower leg 101 formed on the upper frame 5, and the lower surface of each upper leg 102 formed on the pressure separating plate 12. Although step grooves 104 are formed therein, they are not necessarily limited thereto, and although not shown, the step 103 is formed on the lower surface of each upper leg 102 formed in the pressure separator 12 as in other embodiments. The step groove 104 may be formed on the upper surface of each lower leg 101 formed in the upper frame 5.

Therefore, the present invention is a structure in which the pressure separation plate is not integrally formed directly on the upper frame for supporting the pressure separation plate and the pressure separation plate without being made of a structure that does not move in the radial direction in the state supported by the upper frame, As the number of parts is reduced, the machining process is simplified, and the manufacturing cost is reduced because it is not necessary to pay much attention to the dimensional control when machining parts.

In addition, when the stepped portion of each lower leg formed in the upper frame is fitted into the step groove of each upper leg formed in the pressure separator, the gap between the upper frame and the pressure separator plate is only between the stepped portion of each lower leg and the stepped groove of each upper leg. Since the upper frame is supported, of course, the pressure separator is hardly moved in a radial direction in the process of fixing after being supported, so that the pressure separator is held by a separate assembly jig when the pressure separator is fixed. Since it is not necessary to increase the productivity due to the improvement of assembly workability.

Claims (2)

A plurality of lower legs are formed vertically upwardly at the periphery of the upper frame, and a plurality of upper legs are formed at the periphery of the pressure separator plate in a vertically downward state to contact each lower leg formed in the upper frame. In that, A stepped portion is formed at either edge of the inner and outer edge portions of the upper surface of each lower leg formed on the upper frame, and the edge portion of the inner and outer edge portions of the lower surface of each upper leg formed on the pressure separator. The pressure separation plate support structure of a scroll fluid machine, characterized in that the pressure separation plate is supported by the upper frame in a state in which the stepped state is fitted in the step groove. A plurality of lower legs are formed vertically upwardly at the periphery of the upper frame, and a plurality of upper legs are formed at the periphery of the pressure separator plate in a vertically downward state to contact each lower leg formed in the upper frame. In that, The stepped portion is formed at one of the edges of the inner and outer edges of the lower surface of each upper leg formed on the pressure separator plate, and the edge of any one of the inner and outer edges of the upper surface of each lower leg formed on the upper frame. The pressure separation plate support structure of a scroll fluid machine, characterized in that the pressure separation plate is supported by the upper frame in a state in which the stepped state is fitted in the step groove.