KR0173577B1 - Low pressing-high capacity scroll type fluid machinery - Google Patents

Abstract

In the present invention, the positions of the suction port and the discharge port are arranged opposite to each other to improve durability of various components and to increase freezing efficiency, and do not use fastening mechanisms such as bolts, so that vertical movement of the fixed scroll upper surface by scroll internal pressure during operation is prevented. A scroll type fluid machine having a suction port on an upper portion of a compressor having a suppressing effect. The suction port and a discharge port are arranged in order to suppress vertical movement of a fixed scroll upper surface by a decrease in conventional refrigeration efficiency and scroll internal pressure. And the new suction fluid is suppressed in direct contact with the components inside the heated compressor by changing the configuration and at the same time has the effect of compressing a large amount of fluid by enlarging the volume of the central portion of the pocket.

Description

Low Compression High Capacity Scroll Fluid Machine

1 is a partial cross-sectional view showing the configuration of the present invention.

* Explanation of symbols for main parts of the drawings

10: discharge flow path 30: fixed scroll

31: fixed scroll upper surface 32: fixed scroll outer peripheral surface

33: suction port 34: pocket

40: turning scroll 41: discharge port

42, 45: scroll wrap 43: groove

44: end plate 50: upper frame

51: upper frame circumferential surface 60: upper chamber

61: suction hole 62: seal member

63: back pressure chamber 70: rotating shaft

71: seal member 72: shafter protrusion

73: center pocket 80: old box coupling

90: intermediate chamber 91: discharge tube

110: back pressure flow path

The present invention relates to a low compression high capacity scroll fluid machine, and more particularly, to a scroll fluid machine capable of compressing a large amount of fluid while requiring a low compression ratio.

In general, a scroll compression device includes a circular end plate and one scroll member forming a spiral or involute wrap, the two scroll members being fitted together with each other with 180 ° rotation of the scroll member relative to the other scroll member, thereby providing a plurality of spaces between the sides of each cover. A line contact portion is formed. In addition, one scroll member has an eccentric axis with respect to the other scroll member and an outer box coupling function to prevent rotation, so that a certain member forms a sealing surface between the two scroll members by an axial bias, so that the fluid in the two members Removable closed crescent shaped pockets are made. Ideally there is no relative rotation between the two members in operation. In other words, the movement is a curved translational movement. The fluid pockets include fluid that is processed from any one area of the scrollable device containing the suction fluid to the area of any discharge port that contains the discharge pressure. As the sealing pocket moves toward the discharge port, the volume of the sealing pocket changes. At any moment, when there are at least one pair of sealing pockets, and when there are several pairs of sealing pockets at the same time, each pair of pockets has a different volume.

At this time, in the scroll apparatus, the pressure of the region of the discharge port is higher than the pressure of the region including the suction fluid. Here, the contact portion between the two scroll members is a moving line contact caused by radial force between the side or spiral surfaces of the two scroll members, ie tangential tangential contacts extending in the axial direction between the sides, Expressed as a seal surface contact that results in axial compliance between the leading edges and the seal surface, it forms a mobile sealed crescent fluid pocket between the scroll members. Thus, effective sealing of the two types of contacts is a necessary requirement to obtain high refrigeration efficiency. The advantage of the scroll device is that no re-expansion occurs in the intervolume of the reciprocating compressor, and the fluid leakage during compression effectively seals the two adhesion surfaces, thereby minimizing fluid leakage and having high volumetric efficiency, and all fluid flow Simultaneous compression in these multiple opposing pockets results in less vibration during fluid compression because of unidirectionality, and a change in starting torque of about 1/10 of the reciprocating compressor improves the durability of the drive motor. Quiet, low vibration and a remarkably small number of parts to be used have the advantage of being light and compact compared to a predetermined capacity.

Conventional scroll fluid machines have a discharge port on the upper side and a suction port on the side to suck the fluid and then discharge it through compression, expansion or pumping operation. Since there is no separate suction tube at the suction port, the new suction fluid passes directly through the sealed space of the working compressor, making contact with the components heated by the compressed high pressure and high pressure fluid. Constant expansion results in lower compression efficiency. In addition, the axial restoring force is generated by axially biasing the swinging scroll member toward the fixed scroll member by using the compressed fluid, which is caused by the restoring force and the rotational movement of the scroll member to parallel the axial separation force between the two scroll members. There is a problem of overcoming the inertial load, and there is a need for a device that balances the inclined moment on the swinging scroll member caused by the pressure generating radial forces, which makes it effective only at a constant rotational speed of the axis of rotation. Therefore, there was a problem in that the axial parallel force must be relatively large. At the same time, in order to increase the volumetric efficiency without requiring a high compression ratio, there is no need to use a conventional high compression compressor, and thus a compressor capable of increasing the capacity in such a special case is required.

Therefore, the present invention has been devised to solve the above problems, and the positions of the suction port and the discharge port are opposite to each other to improve the durability of various components and to increase the freezing efficiency, and do not use fastening mechanisms such as bolts. It is an object of the present invention to provide a low compression high capacity scroll fluid machine capable of maximizing capacity while reducing the compression ratio while suppressing the vertical movement of the fixed scroll upper surface by the internal scroll pressure.

The present invention for achieving the above object is a new suction fluid is heated by different arrangement and configuration of the suction port and the discharge port in order to suppress the vertical movement of the fixed scroll upper surface by the conventional refrigeration efficiency decrease and scroll internal pressure Direct contact with the components inside the compressor is avoided, and the fixed scroll is assembled in the slip state without the use of fastening mechanisms such as bolts to suppress the vertical movement of the upper surface of the fixed scroll by the internal pressure of the scroll during operation. At the same time, it is characterized in that it is made to compress a large amount of fluid by enlarging the volume of the central portion of the pocket portion.

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

1 shows an embodiment according to the present invention, showing a cross section of a fluid compression portion that is the top of a compressor. The fixed scroll 30 is fixed to the upper frame 50 with a fixed scroll outer circumferential surface 32 by a fixed scroll 30 above the discharge flow path 10 of the compressed fluid elongated in the center inner vertical direction, and the fixed scroll upper surface 31. The upper upper chamber 60 is assembled at regular intervals. Relative rotation by forming spiral pocket portions 34 having a volume change therein by the spiral scroll wraps 42 and 45 at right angles on the end plates 44 of the fixed scroll 30 and the revolving scroll 40. Sealed and assembled to allow movement, the discharge port 41 for discharging the compressed fluid of the pocket portion 34 is connected to the discharge passage 10 through the central pocket portion 73 to open the intermediate chamber 90. It is discharged through the discharge pipe 91. A recess 43 is provided between the swinging scroll 40 and the rotational shaft 70, and is pressed around the inner side of the compressor under the scroll member to be slip fixed with the outer circumferential surface 32 of the fixed scroll 30 instead of the fastening bolt. The upper frame 50 having the upper frame circumferential surface 51 supports the scroll member. The upper chamber 60 surrounding the outer upper surface of the compressor is sealed under pressure with the intermediate chamber 90, and the suction chamber 61 passes through the upper chamber 60 so that the suction port 33 passes through the upper chamber 60. ), One side of the tubular suction port 33 passes through the suction hole 61 to the inlet of the pocket. The sealing member 62 is annularly fitted to seal between the upper chamber 60 and the fixed scroll 30, and communicates with the back pressure chamber 63 formed between the upper chamber 60 and the upper groove of the fixed scroll 30. The back pressure flow path 110 is connected to the pocket portion 34 so as to be provided. There is a passage for the discharge passage 10 in the center of the compressor, the seal member 71 is fitted to the rotary shaft 70 formed in a hollow in some longitudinal direction, and the rotary shaft 70 is fixed to the bottom just below the turning scroll 40 Rotating shaft projections 72 having a length are formed, and a central pocket portion 73 having a constant volume in the center of the pocket portion is located on the upper surface of the rotating shaft 70, and the old coupling 80 is fixed scroll 30 And between the scroll members to prevent instability of the movement due to the relative rotational movement between the swing scroll and the swing scroll 40.

In the scroll fluid machine according to the present invention configured as described above, the cool fluid flowing into the compressor passes through the suction hole 61 provided in the upper part of the compressor, passes through the suction port 33, and does not come into contact with the heating elements inside the compressor. It flows into the inlet of the pocket part 34 formed in the member. At this time, the new suction fluid does not cause a rise in its own temperature due to the heating elements, thereby preventing expansion thereof, thereby increasing the cooling efficiency in the pocket part 34. The fluid introduced into the scroll is compressed by the relative rotation of the two scroll members and moves to the center while the volume changes spirally along the crescent-shaped pocket 34. At this time, the compressed fluid collects a large amount of fluid in the central pocket portion 73 through the discharge port 41, is concentrated in the space between the intermediate chambers 90 through the discharge passage 10, and then passes through the discharge tube 91. Is discharged out of the compressor. At this time, the fluid discharged by being moved to the center of the turning scroll 40 along the plurality of crescent-shaped pockets 34 is discharged in an unstable state causing a predetermined pulsation or the pressure is uniformly maintained while remaining in the intermediate chamber 90. To form a quieter, more consistent fluid.

In another embodiment, the present invention is a method of assembling the fixed scroll 30 with the upper frame 50 without using a fastening mechanism such as a bolt, so that the fixed scroll outer circumferential surface 31 and the upper frame circumferential surface 51 slip together. Are assembled. When the compressor operates, scroll internal pressure is generated, and when the fixed scroll 30 moves upward, further movement is suppressed by the lower surface of the upper chamber 60. At this time, while the compressed fluid is moved to the center of the pocket part 34, a part of the compressed fluid flows into the back pressure chamber 63 communicating with the back pressure flow path 110 formed on the sealing surface of the fixed scroll 30, and the constant pressure of the back pressure chamber 63 is reached. Since the fixed scroll 30, which has been moved upward when the pressure is greater than the scroll internal pressure, is moved downward, the unbalanced force caused by the pressure generated in the scroll member can be eliminated. In addition, the seal member 62 sealing the back pressure chamber 63 to balance the back pressure chamber 63 allows the fixed scroll 30 to more stably maintain the movement in the vertical direction of the axis. The fixed scroll 30 and the upper frame circumferential surface 51 are machined to smoothly move to each other in order to prevent the fixed scroll 30 from moving left and right and to stably move vertically during this axial movement. The left and right rocking of the fixed scroll 30 is prevented due to the surface contact of the scroll member.

In another important aspect of the present invention, the scroll wraps 42 and 45 are formed at right angles to the circular end plate 44 of the revolving scroll 40 so as to rotate the driving force of the rotational shaft 70. The inner diameter of the groove 43 is assembled to the outer diameter of the rotation shaft 70 to be delivered to each other, and when compressed, the fluid moves from the outer edge of the circular end plate 44 to the center of the crescent-shaped pocket and discharge port 41. Finally collected in the central pocket 73 and discharged. At this time, the rotation shaft 70 has a protrusion 72 serves to stabilize the unstable movement of the rotation shaft 70.

Scroll type fluid machine having a suction port in the upper portion of the compressor according to the present invention as described above to improve the durability and refrigeration efficiency of the various components by changing the position of the suction port, a constant pressure in the space for collecting the compressed air in the intermediate chamber It is possible to obtain a fluid and at the same time, since it does not use a fastening mechanism such as a bolt, it is effective to suppress the vertical movement of the fixed scroll upper surface by the scroll internal pressure during operation, and at the same time, it is possible to compress a high capacity fluid with low compression.

Claims (2)

A low compression high capacity scroll type fluid machine comprising a scroll member having a large central volume to collect compressed fluid at the center, and a reduction in the number of sealed volumes, and a constant volume for final compressed fluid at the center. A central pocket portion, a discharge port passing before the compressed fluid collects in the central pocket portion, a rotation shaft having a circumferential protrusion for stabilizing the axial rotational force, and supporting to transmit the axial rotational force to the scroll member Low compression high capacity scroll type fluid machine, characterized in that consisting of a groove. The low compression high capacity scroll type fluid machine according to claim 1, wherein the groove portion is formed in the same direction as the scroll member so that the compressed fluid can also pass through the groove portion.