This application claims the benefit of Korean Application No. 2003-50690, filed Jul. 23, 2003, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein by reference.
1. Field of the Invention
The present invention relates, in general, to rotary compressors and, more particularly, to a variable capacity rotary compressor, which is designed such that a compression operation is executed in either of two compression chambers having different capacities, by an eccentric unit mounted to a rotating shaft.
2. Description of the Related Art
Generally, a compressor is installed in a refrigeration system, such as an air conditioner and a refrigerator, which operates to cool air in a given space using a refrigeration cycle. In the refrigeration system, the compressor operates to compress a refrigerant which circulates through a refrigeration circuit. A cooling capacity of the refrigeration system is determined according to a compression capacity of the compressor. Thus, when the compressor is designed to vary a compression capacity thereof as desired, the refrigeration system is operated under an optimum condition considering several factors, such as a difference between a practical temperature and a predetermined temperature, thus allowing air in a given space to be efficiently cooled, and saving energy.
A variety of compressors are used in the refrigeration systems. The compressors are typically classified into two types-i.e., rotary compressors and reciprocating compressors. The present invention relates to the rotary compressor, which will be described in the following.
The conventional rotary compressor includes a hermetic casing, with a stator and a rotor being installed in the hermetic casing. A rotating shaft penetrates through the rotor. An eccentric cam is integrally provided on an outer surface of the rotating shaft. A roller is provided in a compression chamber to be rotated over the eccentric cam.
The rotary compressor constructed as described above is operated as follows. As the rotating shaft rotates, the eccentric cam and the roller execute eccentric rotation in the compression chamber. At the time, a gas refrigerant is drawn into the compression chamber and then compressed, prior to discharging the compressed refrigerant to an outside of the hermetic casing.
However, the conventional rotary compressor has a problem in that the rotary compressor is fixed in a compression capacity thereof, so that it is impossible to vary the compression capacity according to a difference between an environmental temperature and a preset reference temperature.
In a detailed description, when the environmental temperature is considerably higher than the preset reference temperature, the compressor must be operated in a large capacity compression mode to rapidly lower the environmental temperature. Meanwhile, when the difference between the environmental temperature and the preset reference temperature is not large, the compressor must be operated in a small capacity compression mode so as to save energy. However, it is impossible to change the capacity of the rotary compressor according to the difference between the environmental temperature and the preset reference temperature, so that the conventional rotary compressor does not efficiently cope with a variance in temperature, thus leading to a waste of energy.
Accordingly, it is an aspect of the present invention to provide a variable capacity rotary compressor which is constructed so that a compression operation is executed in either of two compression chambers having different capacities by an eccentric unit mounted to a rotating shaft, thus varying a compression capacity as desired.
It is other aspect of the present invention to provide a variable capacity rotary compressor, which is designed to prevent an eccentric bush from being rotated faster than a rotating shaft in a specific range, due to a variance in pressure of a compression chamber as the rotating shaft is rotated.
Additional and/or other aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.
The above and/or other aspects are achieved by providing a variable capacity rotary compressor including upper and lower compression chambers, a rotating shaft, upper and lower eccentric cams, upper and lower eccentric bushes, a slot, a locking pin, an upper brake unit, and a lower brake unit. The upper and lower compression chambers have different interior capacities. The rotating shaft passes through the upper and lower compression chambers. The upper and lower eccentric cams are provided on the rotating shaft. The upper and lower eccentric bushes are fitted over the upper and lower eccentric cams, respectively. The slot is provided at a predetermined position between the upper and lower eccentric bushes. The locking pin functions to change a position of the upper or lower eccentric bush to a maximum eccentric position, in cooperation with the slot. The upper brake unit functions to prevent the upper eccentric bush from slipping over the rotating shaft, and the lower brake unit functions to prevent the lower eccentric bush from slipping over the rotating shaft.
According to an aspect of the invention, the locking pin is projected from the rotating shaft at a position between the upper and lower eccentric cams, the slot is provided between the upper and lower eccentric bushes to engage with the locking pin, the upper brake unit is provided between the upper eccentric cam and the upper eccentric bush, and the lower brake unit is provided between the lower eccentric cam and the lower eccentric bush.
According to an aspect of the invention, the upper brake unit includes an upper pocket formed on an outer surface of the upper eccentric cam, an upper brake ball movably set in the upper pocket, and an upper brake hole formed on an inner surface of the upper eccentric bush to have a smaller diameter than the upper brake ball, so that, when the locking pin contacts a first end of the slot, the upper pocket is aligned with the upper brake hole and the upper brake ball is inserted into the upper brake hole due to a centrifugal force.
According to an aspect of the invention, the lower brake unit includes a lower pocket formed on an outer surface of the lower eccentric cam, a lower brake ball movably set in the lower pocket, and a lower brake hole formed on an inner surface of the lower eccentric bush to have a smaller diameter than the lower brake ball, so that, when the locking pin contacts a second end of the slot, the lower pocket is aligned with the lower brake hole and the lower brake ball is inserted into the lower brake hole due to a centrifugal force.
According to an aspect of the invention, the slot has a length to allow an angle between a first line extending from the first end of the slot to a center of the rotating shaft and a second line extending from a second end of the slot to the center of the rotating shaft, to be 180°, the upper pocket and the upper brake hole are positioned to be aligned with each other when the locking pin contacts the first end of the slot, and the lower pocket and the lower brake hole are positioned to be aligned with each other when the locking pin contacts the second end of the slot.
According to an aspect of the invention, an oil passage is axially provided along the rotating shaft, the upper pocket communicates with the oil passage via an upper connecting passage having a smaller diameter than the upper brake ball, and the lower pocket communicates with the oil passage via a lower connecting passage having a smaller diameter than the lower brake ball, so that oil is fed from the oil passage through the upper and lower connecting passages to the upper and lower pockets, thus allowing an oil pressure to act on the upper and lower brake balls in a radial direction of the rotating shaft.
According to an aspect of the invention, the upper and lower brake holes are respectively formed through the upper and lower eccentric bushes in a radial direction, thus allowing the oil to flow to outsides of the upper and lower eccentric bushes after passing through the oil passage and the upper and lower brake holes.
These and/or other aspects and advantages of the invention will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout.
The compressing unit 30 includes a housing 33, upper and lower flanges 35 and 36, and a partition plate 34. The housing 33 defines upper and lower compression chambers 31 and 32, which are both cylindrical but have different capacities, therein. The upper and lower flanges 35 and 36 are mounted to upper and lower ends of the housing 33, respectively, to rotatably support the rotating shaft 21. The partition plate 34 is interposed between the upper and lower compression chambers 31 and 32 to partition the upper and lower compression chambers 31 and 32 from each other.
The shown upper compression chamber 31 is taller than the lower compression chamber 32. Thus, the upper compression chamber 31 has a larger capacity than the lower compression chamber 32. Therefore, a larger amount of gas is compressed in the upper compression chamber 31 in comparison with the lower compression chamber 32, thus allowing the rotary compressor to have a variable capacity.
Similarly, it is understood according to another aspect of the invention, if the lower compression chamber 32 is taller than the upper compression chamber 31, the lower compression chamber 32 has a larger capacity than the upper compression chamber 31, thus allowing a larger amount of gas to be compressed in the lower compression chamber 32. However, it is understood that the chambers 31, 32 need not have different capacities in all aspects of the invention.
Further, an eccentric unit 40 is placed in the upper and lower compression chambers 31 and 32 to execute a compressing operation in either the upper or lower compression chamber 31 and 32, according to a rotating direction of the rotating shaft 21. Upper and lower brake units 80 and 90 are provided at predetermined positions of the eccentric unit 40 to smoothly operate the eccentric unit 40. The construction and operation of the eccentric unit 40 and the upper and lower brake units 80 and 90 will be described later herein, with reference to
Upper and lower rollers 37 and 38 are placed in the upper and lower compression chambers 31, respectively, to be rotatably fitted over the eccentric unit 40. Upper inlet and outlet ports 63 and 65 (see,
An upper vane 61 is positioned between the upper inlet and outlet ports 63 and 65, and is biased in a radial direction by an upper support spring 61a to be in close contact with the upper roller 37 (see,
Further, a refrigerant outlet pipe 69a extends from an accumulator 69 which contains a refrigerant therein. Of the refrigerant contained in the accumulator 69, only a gas refrigerant flows into the compressor through the refrigerant outlet pipe 69a. At a predetermined position of the refrigerant outlet pipe 69a is installed a path control unit 70. The path control unit 70 functions to open or close an intake path 67 or 68, thus supplying the gas refrigerant to the upper or lower inlet port 63 or 64 of the upper or lower compression chamber 31 or 32 in which a compression operation is executed. A valve unit 71 is installed in the path control unit 70 to be movable in a horizontal direction. The valve unit 71 functions to open either the intake paths 67 or 68 by a difference in pressure between the intake path 67 connected to the upper inlet port 63 and the intake path 68 connected to the lower inlet port 64, thus supplying the gas refrigerant to the upper inlet port 63 or lower inlet port 64.
Further, a predetermined amount of oil 11 is contained in a lower portion of the hermetic casing 10 to lubricate and cool several contact parts of the compressing part 30. An oil passage 12 is axially formed along the rotating shaft 21 to be eccentric from a central axis C1—C1 of the rotating shaft 21, and functions to move the oil 11 upward by a centrifugal force resulting from a rotation of the rotating shaft 21. A plurality of oil supply holes 13 are formed on the rotating shaft 21 in radial directions to communicate with the oil passage 12, thus supplying the oil 11, which flows upward through the oil passage 12, to the contact parts.
The construction of the rotating shaft and the eccentric unit according to an embodiment of the present invention will be described in the following with reference to
The upper and lower eccentric cams 41 and 42 are integrally fitted over the rotating shaft 21 to be eccentric from the central axis C1—C1 of the rotating shaft 21. The upper and lower eccentric cams 41 and 42 are positioned to correspond an upper eccentric line L1—L1 of the upper eccentric cam 41 to a lower eccentric line L2—L2 of the lower eccentric cam 42. In this case, the upper eccentric line L1—L1 is defined as a line to connect a maximum eccentric part of the upper eccentric cam 41, which is maximally projected from the rotating shaft 21, to a minimum eccentric part of the upper eccentric cam 41, which is minimally projected from the rotating shaft 21. Meanwhile, the lower eccentric line L2—L2 is defined as a line to connect a maximum eccentric part of the lower eccentric cam 42, which is maximally projected from the rotating shaft 21, to a minimum eccentric part of the lower eccentric cam 42, which is minimally projected from the rotating shaft 21.
The locking pin 43 includes a threaded shank 44 and a head 45. The head 45 has slightly larger diameter than the shank 44, and is formed at an end of the shank 44. Further, a threaded hole 46 is formed on the rotating shaft 21 between the upper and lower eccentric cams 41 and 42 to be at about 90° with the maximum eccentric parts of the upper and lower eccentric cams 41 and 42. The threaded shank 44 of the locking pin 43 is inserted into the threaded hole 46 in a screw-type fastening method to lock the locking pin 43 to the rotating shaft 21.
The upper and lower eccentric bushes 51 and 52 are integrated with each other by a connecting part 54. The connecting part 54 connects the upper and lower eccentric bushes 51 and 52 to each other. The slot 53 is formed around a part of the connecting part 54, and has a width, which is slightly larger width than a diameter of the head 45 of the locking pin 43. Thus, when the upper and lower eccentric bushes 51 and 52 which are integrally connected to each other by the connecting part 54 are fitted over the rotating shaft 21 and the locking pin 43 is inserted to the threaded hole 46 of the rotating shaft 21 through the slot 53, the locking pin 43 is mounted to the rotating shaft 21 while engaging with the slot 53.
When the rotating shaft 21 is rotated in the first or second direction in such a state, the upper and lower eccentric bushes 51 and 52 are not rotated until the locking pin 43 comes into contact with one of the first and second ends 53a and 53b of the slot 53. When the locking pin 43 comes into contact with the first or second end 53a or 53b of the slot 53, the upper and lower eccentric bushes 51 and 52 are rotated in the first or second direction along with the rotating shaft 21.
In this case, an eccentric line L3—L3, which connects the maximum eccentric part of the upper eccentric bush 51 to the minimum eccentric part thereof, is placed at about 90° with a line which connects the first end 53a of the slot 53 to a center of the connecting part 54. Meanwhile, an eccentric line L4—L4, which connects the maximum eccentric part of the lower eccentric bush 52 to the minimum eccentric part thereof, is placed at about 90° with a line which connects the second end 53b of the slot 53 to the center of the connecting part 54.
Further, the eccentric line L3—L3 of the upper eccentric bush 51 and the eccentric line L4—L4 of the lower eccentric bush 52 are positioned on a same plane, but the maximum eccentric part of the upper eccentric bush 51 is arranged to be opposite to the maximum eccentric part of the lower eccentric bush 52. An angle between a line extending from the first end 53a of the slot 53 to a center of the rotating shaft 21 and a line extending from the second end 53b of the slot 53 to the center of the rotating shaft 21 is 180°. The slot 53 is formed around a part of the connecting part 54.
In the eccentric unit 40 constructed as described above, the upper brake unit 80 is provided between the upper eccentric cam 41 and the upper eccentric bush 51, while the lower brake unit 90 is provided between the lower eccentric cam 42 and the lower eccentric bush 52. The upper brake unit 80 includes an upper pocket 81, an upper brake hole 82, and an upper brake ball 83. The upper pocket 81 is bored on an outer surface of the upper eccentric cam 41 to have a predetermined diameter. The upper brake hole 82 is bored on an inner surface of the upper eccentric bush 51 to have a predetermined diameter. The upper brake ball 83 is set in the upper pocket 81.
The upper brake ball 83 has a slightly smaller diameter than the upper pocket 81 while having a slightly larger diameter than the upper brake hole 82. Thus, the upper brake ball 83 is movably set in the upper pocket 81. When the centrifugal force is generated in such a state, the upper brake ball 83 moves outward to be inserted into the upper brake hole 82, thus preventing the upper eccentric bush 51 from slipping over the upper eccentric cam 41.
The upper pocket 81 is designed to communicate with the oil passage 12 which is axially formed along the rotating shaft 21, via an upper connecting passage 84 which connects the upper pocket 81 to the oil passage 12, to enhance an operational effect of the upper brake ball 83 which prevents the upper eccentric bush 51 from slipping. According to the above-mentioned construction, the oil 11 is supplied from the oil passage 12 through the upper connecting passage 84 to the upper pocket 81. At this time, an oil pressure resulting from the oil 11 acts on the upper brake ball 83 to move the upper brake ball 83 outward. Thus, the upper brake ball 83 comes into closer contact with the upper brake hole 82 of the upper eccentric bush 51, thus effectively preventing the upper eccentric bush 51 from slipping over the upper eccentric cam 41.
Since the upper brake hole 82 is bored from the inner surface of the upper eccentric bush 51 to an outer surface thereof, the oil 11 fed into the upper pocket 81 flows to an outside of the upper eccentric bush 51 through a gap between the upper brake ball 83 and the upper brake hole 82. Such a construction prevents the upper brake ball 83 from being fixed in the upper brake hole 82, by the oil pressure, while allowing a contact part between the upper eccentric bush 51 and the upper roller 37 (see,
When the locking pin 43 contacts the first end 53a of the slot 53, and the upper eccentric cam 41 and the upper eccentric bush 51 are positioned to be maximally eccentric from the rotating shaft 21, the upper pocket 81 and the upper brake hole 82 are positioned in a row.
Assuming that the rotating shaft 21 is rotated in the first direction (counterclockwise in
The general construction of the lower brake unit 90 remains the same as the upper brake unit 80, except that the lower brake unit 90 is provided between the lower eccentric cam 42 and the lower eccentric bush 52.
The lower brake unit 90 includes a lower pocket 91, a lower brake hole 92, and a lower brake ball 93. The lower pocket 91 is bored on an outer surface of the lower eccentric cam 42. The lower brake hole 92 is bored on an inner surface of the lower eccentric bush 52. The lower brake ball 93 is set in the lower pocket 81.
The lower brake ball 93 has a slightly smaller diameter than the lower pocket 91 while having a slightly larger diameter than the lower brake hole 92. Thus, the lower brake ball 93 is movably set in the lower pocket 91. When the centrifugal force is generated in such a state, the lower brake ball 93 moves outward to be inserted into the lower brake hole 92, thus preventing the lower eccentric bush 52 from slipping over the lower eccentric cam 42.
Further, the lower pocket 91 is designed to communicate with the oil passage 12, which is axially formed along the rotating shaft 21, via a lower connecting passage 94 which connects the lower pocket 91 to the oil passage 12. Thus, oil 11 is supplied from the oil passage 12 through the lower connecting passage 94 to the lower pocket 91. At this time, an oil pressure resulting from the oil 11 acts on the lower brake ball 93 to move the lower brake ball 93 outward. Thus, the lower brake ball 93 comes into closer contact with the lower brake hole 92 of the lower eccentric bush 52, therefore effectively preventing the lower eccentric bush 52 from slipping over the lower eccentric cam 42.
Since the lower brake hole 92 is bored from the inner surface of the lower eccentric bush 52 to an outer surface thereof, the oil 11 fed into the lower pocket 91 flows to an outside of the lower eccentric bush 52 through a gap between the lower brake ball 93 and the lower brake hole 92. Such a construction prevents the lower brake ball 93 from being fixed in the lower brake hole 92, by the oil pressure, while allowing a contact part between the lower eccentric bush 52 and the lower roller 38 (see,
Assuming that the rotating shaft 21 is rotated in the second direction (clockwise in
In the compressor constructed in this way, when the locking pin 43 is locked by the first end 53a of the slot 53 and the upper eccentric bush 51 is rotated along with the rotating shaft 21 in the first direction (of course, the lower eccentric bush 52 is also rotated), the maximum eccentric part of the upper eccentric bush 51 contacts the maximum eccentric part of the upper eccentric cam 41, so that the upper eccentric bush 51 is rotated in the first direction while being maximally eccentric from the rotating shaft 21 (see,
At this time, the upper pocket 81 is aligned with the upper brake hole 82 in a row. Thus, the upper brake ball 83 comes into close contact with the upper brake hole 85 by the pressure of the oil 11 fed through the upper connecting passage 84 and the upper pocket 81 and the centrifugal force, so that the upper eccentric bush 51 is rotated while being restrained by the upper eccentric cam 41.
Conversely, when the locking pin 43 is locked by the second end 53b of the slot 53 and the lower eccentric bush 52 is rotated along with the rotating shaft 21 in the second direction, the maximum eccentric part of the lower eccentric bush 52 contacts the maximum eccentric part of the lower eccentric cam 42, so that the lower eccentric bush 52 is rotated in the second direction while being maximally eccentric from the rotating shaft 21 (see,
At this time, the lower pocket 91 is aligned with the lower brake hole 92 in a row. The lower brake ball 93 comes into close contact with the lower brake hole 92 by the centrifugal force, so that the lower eccentric cam 42 and the lower eccentric bush 52 are restrained by each other. Further, the oil 11 is fed to the lower pocket 91 through the oil passage 12 and the lower connecting passage 94, thus pushing the lower brake ball 93 outward.
The operation of compressing a gas refrigerant in the upper or lower compression chamber by the eccentric unit according to an embodiment of the present invention will be described in the following with reference to
As illustrated in
When the locking pin 43 contacts the first end 53a of the slot 53, the maximum eccentric part of the upper eccentric cam 41 is aligned with the maximum eccentric part of the upper eccentric bush 51. In this case, the upper eccentric bush 51 is rotated while being maximally eccentric from the central axis C1—C1 of the rotating shaft 21. Thus, the upper roller 37 is rotated while being in contact with an inner surface of the housing 33 to define the upper compression chamber 31, thus executing the compression operation.
Further, the upper pocket 81 of the upper brake unit 80 is aligned with the upper brake hole 82. The upper brake ball 83 comes into close contact with the upper brake hole 82, by the pressure of the oil 11 fed through the oil passage 12 to the upper connecting passage 84 and the centrifugal force, so that the upper eccentric bush 51 is rotated while being restrained by the upper eccentric cam 41.
As illustrated in
Therefore, when the rotating shaft 21 is rotated in the first direction, the gas refrigerant flowing to the upper compression chamber 31 through the upper inlet port 63 is compressed by the upper roller 37 in the upper compression chamber 31 having a larger capacity, and subsequently is discharged from the upper compression chamber 31 through the upper outlet port 65. On the other hand, the compression operation is not executed in the lower compression chamber 32 having a smaller capacity. Therefore, the rotary compressor is operated in a larger capacity compression mode.
As shown in
When the rotating shaft 21 is further rotated in such a state, the locking pin 43 collides with the first end 53a of the slot 53 to make the upper eccentric bush 51 be rotated at a same speed as that of the rotating shaft 21. At this time, noise may be generated and the locking pin 43 and the slot 53 may be damaged, due to the collision between the locking pin 43 and the slot 53.
However, the eccentric unit 40 according to the present invention is provided with the upper brake unit 80, thus preventing the upper eccentric bush 51 from slipping.
As illustrated in
When the rotating shaft 21 stops rotating, the upper brake ball 83 is not affected by the centrifugal force and the oil pressure. At this time, the upper brake ball 83 is moved into the upper pocket 81. In such a state, when the rotating shaft 21 is rotated in the second direction, the locking pin 43 contacts the second end 53b of the slot 53, thus the compression operation is executed in the lower compression chamber 32. The compression operation executed in the lower compression chamber 32 will be described in the following.
As illustrated in
That is, while the rotating shaft 21 is rotated in the second direction, the locking pin 43 projected from the rotating shaft 21 comes into contact with the second end 53b of the slot 53, thus causing the lower and upper eccentric bushes 52 and 51 to be rotated in the second direction.
In this case, the maximum eccentric part of the lower eccentric cam 42 contacts the maximum eccentric part of the lower eccentric bush 52, thus the lower eccentric bush 52 is rotated while being maximally eccentric from the central axis C1—C1 of the rotating shaft 21. Therefore, the lower roller 38 is rotated while being in contact with the inner surface of the housing 33 which defines the lower compression chamber 32, thus executing the compression operation.
As illustrated in
Therefore, the gas refrigerant flowing to the lower compression chamber 32 through the lower inlet port 64 is compressed by the lower roller 38 in the lower compression chamber 32 having a smaller capacity, and subsequently is discharged from the lower compression chamber 32 through the lower outlet port 66. On the other hand, the compression operation is not executed in the upper compression chamber 31 having a larger capacity. Therefore, the rotary compressor is operated in a smaller capacity compression mode.
As shown in
When the rotating shaft 21 is further rotated in such a state, the locking pin 43 collides with the second end 53b of the slot 53 to make the lower eccentric bush 52 be rotated at a same speed as that of the rotating shaft 21. At this time, noise may be generated and the locking pin 43 and the slot 53 may be damaged, due to the collision between the locking pin 43 and the slot 53.
However, the lower eccentric bush 52 is restrained by the lower brake unit 90 in a same manner as the upper eccentric bush 51 is restrained by the upper brake unit 80 when the rotating shaft 21 is rotated in the first direction, thus preventing the slippage and the collision.
That is, when the lower roller 38 comes into contact with the lower vane 62, some of the gas refrigerant returns to the lower compression chamber 32 through the lower outlet port 66 and is expanded again, thus generating a force Fs. The force Fs acts on the lower eccentric bush 52 in the rotating direction of the rotating shaft 21 which is the second direction, thus the lower eccentric bush 52 slips. However, as illustrated in
When the rotating shaft 21 stops rotating, the lower brake ball 93 is not affected by the centrifugal force and the oil pressure. At this time, the lower brake ball 93 is moved into the lower pocket 91. In such a state, when the rotating shaft 21 is rotated in the first direction, the locking pin 43 contacts the first end 53a of the slot 53, thus the compression operation is executed in the upper compression chamber 31.
As apparent from the above description, the present invention provides a variable capacity rotary compressor, which is designed to execute a compression operation in either of upper and lower compression chambers having different interior capacities by an eccentric unit which is rotated in the first or second direction, thus varying a compression capacity of the compressor as desired. While described in terms of balls 81, 91, it is understood that other shapes could be used in the brake units 80, 90 so long as the shape prevents slipping.
Further, the present invention provides a variable capacity rotary compressor, which has an upper brake unit between an upper eccentric cam and an upper eccentric bush, and has a lower brake unit between a lower eccentric cam and a lower eccentric bush, thus preventing the upper or lower eccentric bush from slipping due to variance of pressure in an upper or lower compression chamber when an eccentric unit is rotated in the first or second direction, therefore allowing the upper and lower eccentric bushes to be smoothly rotated.
Although a few embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in this embodiment without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.
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