KR100446215B1 - A Scroll Compressor With Noise Reduction Structure - Google Patents

Abstract

The present invention relates to a scroll compressor having a noise reduction structure that prevents the operation noise inside the compression mechanism from propagating to the outside by forming a blocking layer of different materials on the fixed scroll and the axial movement guide surface of the upper frame.

The scroll compressor having a noise reduction structure according to the present invention is provided in the sealing shell (A) in which the upper chamber (10), the intermediate chamber (12), and the lower chamber are joined to each other via an involute wrap (22) (32). The fixed scroll 20 and the turning scroll 30 are provided, and the high and low pressure separating plate 60 is disposed above the fixed scroll 20, and the fixed scroll 20 is formed around the circumference thereof. In the scroll compressor in which a plurality of protrusion guides 26 are not rotatable in the guide groove 44 of the upper frame 40 fixed inside the sealing shell A, and slidably up and down in the axial direction. Different types of the fixed scroll 20 and the upper frame 40 from the outer surface of the protrusion guide 26 of the fixed scroll 20 or the inner surface of the guide groove 44 of the upper frame 40. It is characterized in that the blocking layer 100 made of a material is formed.

Preferably, the blocking layer 100 is made of a non-metallic material, more preferably made of plastics, most preferably made of Teflon.

According to the scroll compressor having a noise reduction structure of the present invention, by forming a blocking layer of different materials having different vibration frequency characteristics in the guide guide of the fixed scroll and the guide groove of the fixed frame for axial movement of the fixed scroll The noise transmitted from the inside of the compressor to the fixed scroll is mostly absorbed or sounded out in the dissimilar material blocking layer, so that the noise generated inside the compressor is cut off before being transferred to the upper frame and the chamber side, so that the scroll compressor can be more quietly operated. to provide.

Description

Scroll Compressor With Noise Reduction Structure

The present invention relates to a scroll compressor, and more particularly to a noise reduction structure that prevents the operation noise inside the compression mechanism from spreading to the outside by forming a blocking layer of different materials on the fixed scroll and the axial movement guide surface of the upper frame. It relates to a scroll compressor having.

As is well known, the scroll compressor has two scroll members each having an involute-shaped wrap, and opposes the wraps of each scroll member with a certain phase angle, so that one scroll member (fixed scroll member) By rotating the other scroll member (orbiting scroll member) with respect to the compressor to compress the fluid in the process of gradually reducing the volume of the sealed pocket generated between the wrap of the two scroll members.

1 is a view illustrating a typical scroll compressor. The scroll compressor includes an upper chamber 10 at the outermost side and an intermediate chamber 12 at the bottom of the upper chamber 10. The lower chamber (not shown) is provided below this intermediate chamber 12, and it comprises one sealing shell A joined together by the method of welding, etc. The fixed scroll inside this sealing shell A. Compressed fluid between the wraps 22 and 32 is provided with the involute wraps 22 and 32 provided with the 20 and the turning scrolls 30 having a phase difference of 180 degrees. Sealing pocket (B) is formed for.

The fixed scroll 20 is to enable the up and down movement in order to increase the axial stiffness, axial direction that is impossible to rotate to the upper frame 40 which is fixed by welding or the like inside the sealing shell (A), Sliding in the up and down direction is coupled, the swing scroll 30 is by the eccentric shaft 52 of the crankshaft 50 is supported by the bearing 54 to the upper frame 40, and eccentric The rotating motion of the shaft 52 is rotated about the fixed scroll 20 by the coupling 34 which converts the rotational motion of the shaft 52 into a curved translational motion. The high and low pressure separating plate 60 is fixed to the sealing shell A by welding or the like on the upper side of the fixed scroll 20 so that the fixed scroll 20 moves upward by the pressure of the sealed pocket B. The upper frame 40 is fastened to the lower frame not shown by the fastening bolt 42 while being positioned inside the intermediate chamber 12.

Figure 2 shows a guide structure for axial sliding of the fixed scroll 20 described above, which is a cross-sectional view taken along the line I-I of Figure 1, along the circumferential direction to the fixed scroll 20 A plurality of protruding guides 26 are formed at predetermined intervals, and the upper frame 40 is formed with a guide groove 44 which extends the protruding guide 26 side of the fixed scroll 20 for up and high periods. Therefore, the fixed scroll 20 is not rotated by the centrifugal force due to the pivoting motion of the swinging scroll 30, and at the same time, the side surface and the upper frame of the protruding guide 26 when the fixed scroll 20 is axially biased. 40, the side of the guide groove 44 is sliding so that the fixed scroll 20 can move up and down.

In the scroll compressor, compression is performed while the volume of the sealed pocket B is gradually reduced in accordance with the swinging motion of the swinging scroll 30, and the compressed fluid is finally formed in the fixed scroll 20. After being discharged into the upper chamber 10 by passing through the discharge port 24 formed in the center portion and the discharge port 62 formed in the high and low pressure separating plate 60 and the reverse valve 80, the discharge is provided on one side of the upper chamber 10 It is discharged through the pipe 70.

In the process of compressing the fluid as described above, the mechanical friction noise, the operation noise, and the fluid flow noise according to the fluid compression are generated according to the sliding of the swinging scroll 30, such as the swinging movement of each part. The generated series of noises are transmitted to the guide groove 44 of the upper frame 40 along the protruding guide 26 of the fixed scroll 20, and the intermediate chamber of the sealing shell A closely contacted with the upper frame 40. It propagates to the outside through (12). This is because the protrusion guide 26 of the fixed scroll 20 and the side surface of the guide groove 44 of the upper frame 40 are in surface contact, and both of them are made of the same steel such as cast iron. Since they show the same characteristics, noise energy is easily spread to the outside.

Therefore, an object of the present invention is to transfer the fixed scroll from the inside of the compressor by forming a blocking layer of different materials having different frequency characteristics in the protrusion guide of the fixed scroll and the guide groove of the upper frame to guide the axial movement of the fixed scroll. Noise can be reduced to noise transmitted to the upper frame by mostly absorbing or insulating sound in the blocking layer made of dissimilar materials, while also reducing noise due to metal friction between the protrusion guide of the fixed scroll and the guide groove of the upper frame. In providing a scroll compressor having a.

1 is a cross-sectional view showing a typical scroll compressor in the prior art

FIG. 2 is a cross-sectional view taken along line II of FIG.

Figure 3 is an exploded perspective view showing a fixed scroll and the rotating scroll and the upper frame of the scroll compressor according to the first embodiment of the present invention

Figure 4 is an assembled cross-sectional view of Figure 3

5 is a perspective view showing a fixed scroll and a rotating scroll and the upper frame of the scroll compressor according to a second embodiment of the present invention

6 is a cross-sectional view of the assembled state of FIG.

<Explanation of symbols for the main parts of the drawings>

10: upper chamber 12: intermediate chamber

20: fixed scroll 22, 32: involute wrap

24, 62: discharge port 30: turning scroll

34: coupling 40: upper frame

42: fastening bolt 44: guide groove

50: crankshaft 52: eccentric shaft

54: bearing 60: high and low pressure separator

62 discharge port 70 discharge pipe

80: reverse 100: blocking plate

A: sealed shell B: sealed pocket

In order to achieve the above object, a scroll compressor having a noise reduction structure according to the present invention includes a fixed scroll engaged with an involute wrap in a sealing shell (A) in which an upper chamber, an intermediate chamber, and a lower chamber are joined. The swing scroll is provided, and the high and low pressure separation plate is disposed above the fixed scroll, and the fixed scroll has a plurality of protruding guides formed around the circumference thereof in the guide groove of the upper frame fixed inside the sealing shell (A). In the scroll compressor coupled non-rotating in the axial direction, the scroll compressor, wherein the fixed scroll and the upper frame and the outer surface of the protrusion guide of the fixed scroll or the guide surface of at least one of the inner surface of the guide groove of the upper frame and A barrier layer made of different materials is formed.

Preferably, the barrier layer is made of a non-metallic material, more preferably made of plastics, most preferably made of Teflon.

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

The same reference numerals are given to the same parts as in FIG. 1, and repeated descriptions thereof are omitted.

3 and 4 show the configuration of the fixed scroll 20 and the upper frame 40 of the scroll compressor according to the first embodiment of the present invention.

As shown, a plurality of protrusion guides 26 are formed along the circumferential direction of the fixed scroll 20, and the upper frame 40 is positioned at a position corresponding to the protrusion guide 26 of the fixed scroll 20. Since a plurality of guide grooves 44 are formed, both sides of the protruding guides 26 of the fixed scroll 20 are slidably coupled to the inner surfaces of the guide grooves 44 of the upper frame 40 so that the fixed scroll 20 is upward. , While being able to slide in the downward direction, the fixed scroll 20 does not rotate during the pivoting movement of the swinging scroll 30.

In this embodiment, the non-metal blocking layer 100 is formed to have a predetermined thickness on the outer circumference of the protruding guide 26 of the fixed scroll 20. The protrusion guide 26 of the fixed scroll 20 on which the blocking layer 100 is formed is inserted into the guide groove 44 of the upper frame 40 so as to slide upward and downward. When the fixed scroll 20 moves in the up and down directions, the outer side surfaces of the barrier layer 100 formed around the outer side of the protruding guide 26 are upward and downward with respect to the inner side surfaces of the guide groove 44 of the upper frame 40. , Will slide in the downward direction.

In the present invention, the blocking layer 100 is made of a non-metallic material that is different from the fixed scroll 20 and the upper frame 40. Conventionally, both the fixed scroll 20 and the upper frame 40 are made of iron materials such as cast iron, and they all have the same or similar physical properties (for example, natural frequency, vibration frequency characteristics, and sound wave transmission characteristics). However, in the present invention, since the barrier layer 100 is made of a non-metallic material having very different physical properties from the fixed scroll 20 or the upper frame 40, the barrier layer 100 is formed from the protrusion guide 26 of the fixed scroll 20. Sound waves transmitted to the frame 40 are effectively blocked or attenuated by the non-metal blocking layer 100. Here, in the method of forming the blocking layer 100 in the protruding guide 26 of the fixed scroll 20 In general, as is well known, it can be simply formed by coating a non-metallic material by a predetermined thickness around the outer circumference of the protruding guide 26. Alternatively, the non-metallic material corresponding to the blocking layer 100 may be made in advance in a strip shape, and then the strip may be cut by the length of the periphery of the protrusion guide 26 of the fixed scroll 20 and bonded by bonding or the like. . Most preferably, the barrier layer 100 may be formed of a non-metallic material, but may be made of a plastic material, and more preferably made of Teflon.

5 and 6 show a second embodiment of the present invention, in which the blocking layer 100 is formed inside the guide groove 44 of the upper frame 40. Here, Also, a method of forming the blocking layer 100 in the guide groove 44 of the upper frame 40 also includes forming the blocking layer 100 in the protruding guide 26 of the fixed scroll 20 in the first embodiment. Similarly to the method, it is preferable to be formed by coating a predetermined thickness on both the inner wall and the bottom of the guide groove 44. Otherwise, the blocking layer 100 may be formed in a band shape in advance, and then cut by the length of the inside of the guide groove 44 of the upper frame 40 to be bonded by a bonding method or the like. 100 may be formed only on both inner surfaces of the guide groove 100, but it is preferable to form the entire inner surface including the bottom of the guide groove 44 for easy coating as shown.

In the first and second embodiments described above, the blocking layer 100 is illustrated as being formed in one of the protrusion guide 26 of the fixed scroll 20 or the guide groove 44 of the upper frame 40. As will be apparent through, the barrier layer 100 can be formed in both the protrusion guide 26 of the fixed scroll 20 and the guide groove 44 of the upper frame 40, this configuration diagram The claims of the present invention are set forth.

Scroll compressor having a noise reduction structure according to the present invention as described above, to reduce the noise in the scroll compressor is designed to allow the vertical movement of the fixed scroll 20 to increase the axial compliance force when the compression in the scroll compressor proceeds. As a very suitable sphere, one or both of the protruding guide 26 of the fixed scroll 20 or the guide groove 44 of the upper frame 40 for vertical movement of the fixed scroll 20 may be made of a non-metal material. A blocking layer is formed. Therefore, the mechanical friction noise and the fluid flow noise generated in the compressor as the compression progresses is transmitted to the fixed scroll 20, and then the protrusion guide 26 of the fixed scroll 20 and the guide groove of the upper frame 40 ( The propagation guide 26 and the upper frame 40 of the fixed scroll 20 according to the present invention, but to propagate to the outside through the intermediate chamber 12 which is transmitted through the 44 and is in close contact with the upper frame 40. Between the guide grooves 44 of the non-metallic material is interposed between the blocking layer 100 made of a different material, the noise is absorbed or blocked in the blocking layer 100, the upper frame 40 from the fixed scroll 20 The noise transmission path to) can be cut off from the beginning.

As described above, according to the scroll compressor having a noise reduction structure according to the present invention, a barrier layer made of a dissimilar material having different vibration frequency characteristics is provided in the protrusion guide of the fixed scroll and the guide groove of the upper frame to guide the axial movement of the fixed scroll. The noise transmitted from the inside of the compressor to the fixed scroll is absorbed or sounded in the blocking layer made of heterogeneous materials, so that the noise generated inside the compressor is cut off before being transmitted to the outside of the upper frame and the chamber. This possible scroll compressor is provided.

Claims (4)

Fixed scroll 20 and pivoting scroll 30 engaged in involute wraps 22 and 32 in sealing shell A through which upper and lower chambers 10, intermediate chambers 12 and lower chambers are joined, respectively. Is provided, the high and low pressure separating plate 60 is disposed on the upper side of the fixed scroll 20, the fixed scroll 20 is a plurality of protrusion guides 26 formed on the circumference of the sealing shell (A) In the scroll compressor coupled to the up and down sliding in the axial direction while not rotating to the guide groove 44 of the upper frame 40 fixed to the inside, Different from the fixed scroll 20 and the upper frame 40 on the guide surface of at least one side of the outer surface of the protrusion guide 26 of the fixed scroll 20 or the inner surface of the guide groove 44 of the upper frame 40 A scroll compressor having a noise reduction structure, characterized in that the blocking layer 100 made of a material is formed. The method of claim 1, The blocking layer 100 is a scroll compressor having a noise reduction structure, characterized in that made of a non-metal material. The method of claim 2, The blocking layer 100 is a scroll compressor having a noise reduction structure, characterized in that made of plastics. The method of claim 2, The blocking layer 100 is a scroll compressor having a noise reduction structure, characterized in that made of Teflon.