This claims priority to Korean Application No. 10-2006-0021469, filed in Korea on Mar. 7, 2006, the entirety of which is incorporated herein by reference.
1. Field
This relates to a compressor, and more particularly, to a scroll compressor.
2. Background
Compressors convert mechanical energy into compressive energy. Compressors may be classified into a variety of different types, including, for example, reciprocating, scroll, centrifugal and vane types. Scroll compressors may be further classified into low pressure and high pressure types, based on whether a suction gas or a discharge gas is filled in a casing thereof. In a scroll compressor, two scrolls perform a relative orbiting motion, and a pair of substantially symmetrical compression chambers are formed between the two scrolls. As the compression chambers consecutively move towards a center of the scroll, a volume of the compression chamber is decreased, thus compressing a refrigerant held therein. The pair of compression chambers may include a high pressure side compression chamber and a low pressure side compression chamber. In some instances, refrigerant inside the high pressure side compression chamber may leak into the low pressure side compression chamber, thus degrading performance of the compressor.
The embodiments will be described in detail with reference to the following drawings in which like reference numerals refer to like elements wherein:
The exemplary high pressure type scroll compressor shown in
When power is supplied to a winding coil 80 of the driving motor 40, a driving shaft 43 is rotated together with a rotor 42, and the orbiting scroll 60 performs an orbiting motion at an upper surface of the main frame 20. The engagement of the wraps 52 and 62 forms a pair of compression chambers P that progressively move towards the center of the scroll as the orbiting scroll 60 orbits, with a volume decreasing as they approach the center, thereby compressing a refrigerant in the compression space P.
A lower surface of a plate 61 of the orbiting scroll 60 is disposed on an upper surface of the main frame 20, thus forming a lower side thrust bearing surface (TS). An outer circumferential surface of an upper surface of the plate 61 comes in contact with a lower surface of a plate 51 of the fixed scroll 50, thus forming an upper side thrust bearing surface (TS). The lower surface of the plate 51 of the fixed scroll 50 contacts the end of the wrap 62 of the orbiting scroll 60, and the end of the wrap 52 of the fixed scroll 50 contacts the upper surface of the plate 61 of the orbiting scroll 60, thereby preventing a refrigerant inside the high pressure side compression chamber from leaking into the lower pressure side compression chamber.
As shown in
The exemplary high pressure type scroll compressor shown in
The main frame 120 may include a shaft hole 121 at a center thereof for supporting a driving shaft 143. A boss portion receiving groove 122 which allows for orbiting motion of a boss portion 163 of the orbiting scroll 160 may be formed at an upper end of the shaft hole 121. A back pressure groove 123 may be formed as a recess with a predetermined depth at an edge of an upper surface of the main frame 120. The back pressure groove 123 may define an inner volume together with a rear surface of the orbiting scroll 160, and may have a ring shape so that refrigerant gas of a middle pressure may be contained within this inner volume.
The involute wrap 152 of the fixed scroll may have the same height and width as that of the involute wrap 162 of the orbiting scroll 160 so that a pair of compression chambers P may be formed between a lower surface of the plate 151, an upper surface of the plate 161, and the wraps 152, 162. An inlet 153 to receive the gas suction pipe SP may be disposed at one side of the plate 151, and an outlet 154 may be disposed at the center of the plate 151 so as to discharge compressed refrigerant from a final compression chamber into the casing 110. A lower surface of the plate 151 of the fixed scroll 150 may be disposed on the same plane as the end of the wrap 152 so that an outer surface thereof may form a thrust bearing surface (TS) together with an upper surface of the plate 161 of the orbiting scroll 160.
As set forth above, the involute wrap 162 is provided at an upper surface of the plate 161, the wrap 162 having the same height and width as that of the wrap 152 and performing an orbiting motion through its engagement with the wrap 152 of the fixed scroll 150. This allows an inner volume of the compression chamber P to be progressively decreased towards a center of the scroll.
As shown in
A portion C of the plate 161 of the orbiting scroll 160 outside the compression chamber P may have a height (HC) between the height (HA) of the outermost compression chamber A and the height (HB) of the final compression chamber B. Accordingly, excessive leakage of a refrigerant through the thrust bearing surface (FS) formed between the fixed scroll 150 and the orbiting scroll 160, and between the wrap 152 and the wrap 162, may be prevented. In certain embodiments, the difference between the height (HA) of the outermost compression chamber A and the height (HC) of the portion C of the plate 161 outside the compression chamber may be in a range of approximately 0.003˜0.03 mm, and, in alternative embodiments, may be less than or equal to or less than approximately 0.02 mm.
It is noted that the term “height” as used herein may describe an overall distance from an uppermost surface of one of the scrolls to its lowermost surface at a particular radial position, when shown in cross section. Likewise, this term may also be used to describe a thickness of one of the plates, measured from an uppermost surface to a corresponding lowermost surface at a particular position when shown in cross section. Similarly, this term may also be used to describe a length of one of the wraps, measured from a distal end to an opposite end adjacent its corresponding plate when shown in cross section.
Operation of the high pressure type scroll compressor in accordance with embodiments as broadly described herein will now be explained.
When power is supplied to a coil 80 of the driving motor 140, the driving shaft 143 rotates, causing the orbiting scroll 160 to orbit a predetermined eccentric distance. While the orbiting scroll 160 progressively moves within the fixed scroll 150, a plurality of paired compression chambers P having decreased volumes towards the center of the scrolls are formed. A refrigerant is sucked into the scrolls, compressed in the chambers, and discharged through the outlet 154 into the casing 110. This process is continuously repeated.
In order for the compressor to generate a desired cooling capacity, manufacturing tolerances of the fixed scroll 150 and the orbiting scroll 160 should be precise so that the wrap 152 of the fixed scroll 150 and the wrap 162 of the orbiting scroll 160 make necessary contact with the respective surfaces of the plates 151 and 161. However, such precise control of manufacturing tolerances increases fabrication cost. Further, over time, the wrap 152 of the fixed scroll 150 and the wrap 162 of the orbiting scroll 160 may be abraded due to continuous operation of the compressor, thus generating a gap through which refrigerant may leak from the high pressure side compression chamber to the low pressure side compression chamber.
To address this problem, as shown in
As shown in
To address this problem, a discharge pressure may be applied to the center of a lower surface of the plate 161 by oil sucked through the driving shaft 143, and a mid-level pressure may be applied to an outer portion of a lower surface of the plate 161 that forms a portion of the back pressure groove 123. In contrast, the center of an upper surface of the plate 161 may be supplied with a discharge pressure at the final compression chamber B, and an outer upper surface of the plate 161 may be supplied with a suction pressure by a refrigerant sucked through the inlet 153.
More specifically, because the plate 151 is fixed, and the plate 161 is not fixed, the plate 161 may be shifted in a shaft direction by this pressure difference. At the time of initial driving of the compressor, the pressures at upper and lower sides of the plate 161 are similar to each other. During operation, the pressure of the lower side of the plate 161 is higher than that of the upper side because the lower side of the plate 161 is divided into a high pressure portion 122 and a middle pressure portion 123 which are sealed from one another. These pressure differentials cause the upper surface of the plate 161 positioned outside the wrap 162 of the orbiting scroll 160 to contact the lower surface of the plate 151 positioned outside the suction chamber of the fixed scroll 150, thereby forming a thrust bearing surface (TS) therebetween and preventing abrasion of the outermost wrap 152a and subsequent leakage of refrigerant.
As shown in
A scroll compressor in accordance with a second embodiment will now be explained. In the scroll compressor of the first embodiment, the thickness of the orbiting scroll 160, and in particular, a thickness of the plate 161 and/or a length(s) of the wrap 162, may vary. However, in the scroll compressor shown in
A scroll compressor in accordance with a third embodiment is shown in
In the second embodiment shown in
In the third embodiment shown in
Referring to
As the wrap of each of the scrolls or the plates may have different heights, a gap between the end of the wrap and the opposite plate can be prevented even if control of tolerances during manufacturing of the fixed scroll 150 and the orbiting scroll 160 is imprecise or the compressor is operated for an extended period of time. Accordingly, performance of the compressor may be enhanced.
Furthermore, even when an edge of the plate of the orbiting scroll is bent due to different pressures applied thereto, excessive contact and/or friction between the thrust bearing surface of the orbiting scroll and the thrust bearing surface of the fixed scroll may be avoided. This may prevent a frictional loss due to an increase in frictional area. Since the thrust bearing surface serves as a lever, refrigerant leakage due to separation between the end of the wrap and the opposite plate may be prevented.
The scroll configuration for a scroll compressor as embodied and broadly described herein has numerous applications in which compression of fluids is required. Such applications may include, for example, air conditioning and refrigeration applications. One such exemplary application is shown in
Another such exemplary application is shown in
Another such exemplary application is shown in
An object is to provide a scroll compressor capable of preventing a refrigerant from being leaked between each wrap end of a fixed scroll and an orbiting scroll and a plate even if the fixed scroll and the orbiting scroll have a low processing precision or each wrap end thereof is abraded.
To achieve these and other advantages and in accordance with the purpose of embodiments broadly described herein, there is provided a scroll compressor, including a frame fixedly-coupled to inside of a casing, a fixed scroll fixedly-coupled to the frame, and having a wrap at a lower surface of a plate, and an orbiting scroll having a wrap at an upper surface of the plate, and performing an orbiting motion by being engaged with the wrap of the fixed scroll so that a compression chamber may have a decreased volume, wherein the plate or the wrap of at least one of the fixed scroll and the orbiting scroll has different heights according to each position.
To achieve these and other advantages and in accordance with the purpose of embodiments broadly described herein, there is provided a scroll compressor, including a frame fixedly-coupled to inside of a casing, a fixed scroll fixedly-coupled to the frame, and having a wrap at a lower surface of a plate, and an orbiting scroll having a wrap at an upper surface of the plate, and performing an orbiting motion by being engaged with the wrap of the fixed scroll so that a compression chamber may have a decreased volume, wherein a wrap of at least one of the fixed scroll or the orbiting scroll has different heights according to each position.
Any reference in this specification to “one embodiment,” “an exemplary,” “example embodiment,” “certain embodiment,” “alternative embodiment,” and the like means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment as broadly described herein. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiments, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments.
Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, numerous variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.
Number | Date | Country | Kind |
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10-2006-0021469 | Mar 2006 | KR | national |
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