Patent Application
20080107556
The present invention relates to a rotary compressor, and more particularly, to a rotary compressor that can be operated at different compression capacities and enables a precise location change of components every compressive capacity.
In general, compressors are machines that are supplied power from a power generator such as electric motor, turbine or the like and apply compressive work to a working fluid, such as air or refrigerant to elevate the pressure of the working fluid. Such compressors are widely used in a variety of applications, from electric home appliances such as air conditioners, refrigerators and the like to industrial plants.
The compressors are classified into two types according to their compressing methods: a positive displacement compressor, and a dynamic compressor (a turbo compressor).
The positive displacement compressor is widely used in industry fields and configured to increase pressure by reducing its volume. The positive displacement compressors can be further classified into a reciprocating compressor and a rotary compressor.
The reciprocating compressor is configured to compress the working fluid using a piston that linearly reciprocates in a cylinder. The reciprocating compressor has an advantage of providing high compression efficiency with a simple structure. However, the reciprocation compressor has a limitation in increasing its rotational speed due to the inertia of the piston and a disadvantage in that a considerable vibration occurs due to the inertial force.
The rotary compressor is configured to compress working fluid using a roller eccentrically revolving along an inner circumference of the cylinder, and has an advantage of obtaining high compression efficiency at a low speed compared with the reciprocating compressor, thereby reducing noise and vibration.
However, in spite of the aforementioned advantages, the rotary compressor has a structural limitation not allowing the roller to revolve in both directions. In other words, the conventional rotary compressor is provided with only a single suction port and a single discharge port, which communicate with the cylinder. The roller performs its rolling motion from an inlet side to an outlet side along the inner circumference of the cylinder to compress the working fluid, such as refrigerant. Accordingly, when the roller performs its rolling motion in a reverse direction, i.e., from the outlet side to the inlet side, it is impossible to compress the working fluid.
Furthermore, the aforementioned structure of the conventional compressor makes it impossible to vary its compression capacity. Recently, there are appearing compressors in which the compression capacity is variably changed so as to correspond to a variety of operational conditions of air conditions. However, the conventional rotary compressor has a limitation in its application since it has only a single compression capacity.
Accordingly, the present invention is directed to a rotary compressor that substantially obviates one or more problems due to limitations and disadvantages of the related art.
An object of the present invention is to provide a rotary compressor enabling operations to obtain different refrigerant compression ratios.
Another object of the present invention is to provide a rotary compressor in which oil inflow into the compression chamber is in advance cut off to prevent the compression efficiency from being lowered.
A further object of the present invention is to provide a rotary compressor in which a dead area that may be incurred in the compression space is completely eliminated to obtain a desired compression efficiency with accuracy.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.
To achieve these objects and other advantages and according to the purpose of the invention, as embodied and broadly described herein, there is provided a rotary compressor. The rotary compressor includes: a cylinder having a vane for partitioning an inner space of the cylinder into a compression section and a suction section; upper and lower bearings respectively disposed on top and bottom of the cylinder, for defining a compression chamber by hermetically sealing the inner space of the cylinder; a crankshaft installed to penetrate the cylinder, the upper bearing, and having an eccentric portion at an outer circumference thereof; at least one discharge port communicating with the compression chamber, and through which compressed refrigerant is discharged; and a valve assembly having at least one suction port for selectively supplying refrigerant through two different positions inside the compression chamber according to the rotational direction of the crankshaft, and at lease one refrigerant flowing portion for feeding the refrigerant to the suction port.
In other words, the rotary compressor of the present invention is designed to operate in a variety of modes having different compression capacities. In particular, a fluid passage through which refrigerant flows is formed in the valve assembly itself, thereby enabling a smooth refrigerant supply to a selected location.
It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principle of the invention.
In the drawings:
Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
Referring first to
The cylinder 100 is provided therein with an inner space. A vane 110 is elastically mounted on an inner circumference of the cylinder 100 defining the inner space, so as to be protruded inwardly. The vane 110 always contacts an outer circumference of the roller 400 and thereby it is configured to divide the inner space of the cylinder 100 into a refrigerant compression section and a refrigerant suction section.
The upper and lower bearings 210 and 220 are respectively disposed above and below the cylinder 100 to define a compression chamber by sealing the inner space, while supporting the crankshaft 300.
The discharge port includes first and second discharge ports 610 and 620, and is configured to penetrate the upper bearing 210 from the upper side of the cylinder 100.
Especially, the discharge ports 610 and 620 are disposed adjacent to the vane 110 on both spaces of the vane in the respective portions of the cylinder 100.
Respectively disposed in the discharge ports 610 and 620 are valves 611 and 621 for selectively discharging a compressed refrigerant.
The valve assembly operates such that a compression capacity of a refrigerant compressed in the compression chamber can be varied according to the rotational direction of the crankshaft 300.
The valve assembly may be provided between the lower bearing 220 and the cylinder 100, as well as between the upper bearing 210 and the cylinder 100. In this embodiment, the valve assembly is provided only between the lower bearing 220 and the cylinder 100.
In particular, the valve assembly includes a hollow stationary valve 810, and a rotational valve 820 having a penetration hole 829 through which the crankshaft 300 penetrates. The valve assembly will be described in more detail hereinafter.
The hollow stationary valve 810 is fixed between the outer peripheries of the lower bearing 220 and the cylinder 100, and the rotational valve 820 is rotatably mounted on an inner circumference of the stationary valve 810.
The rotation of the rotational valve 820 is affected and thus realized by a rolling motion of the roller 400.
In other words, when the roller 400 disposed on top of the rotational valve 820 rolls along the inner circumference of the cylinder 100, fluid existing between a bottom of the roller 400 and a top of the rotational valve 820 flows in a direction where the roller 400 rolls. At this point, due to viscosity of the fluid, the rotational valve 820 rotates in the rotational direction of the roller 400.
The fixing and rotational valves 810 and 820 are configured to have a predetermined thickness.
The fixing and rotational valves 810 and 820 are provided with at least one suction port(s) through which the refrigerant can be selectively fed to the different two sections of the compression chamber 101. The fixing and rotational valves 810 and 820 are further provided with a refrigerant flowing portion.
In the above, the suction port includes first and second suction ports 710 and 720 formed in the rotational valve 820, and a third suction port 730 formed in the stationary valve 810. The first and second suction ports 710 and 720 are formed by cutting away portions of an outer circumference of the rotational valve 820, and are spaced apart from each other by a predetermined distance. The third suction port 730 is formed by indenting a portion of an inner circumference of the stationary valve 810. The distance between the first and second suction ports 710 and 720 may be varied depending on a desired compression ratio that may be varied according to applications of the compressor.
For example, in order to obtain a compression efficiency followed by compressing a refrigerant having a relatively large compression capacity, the compression should be carried out at the closest location to the vane 110. When considering this, the first suction port 710 for a large capacity is positioned in the closest position to one side of the vane 110, and the second suction portion 720 for a small capacity is positioned near the vane at the other side of the vane 110.
Accordingly, the suction ports 710 and 720 are spaced from each other by such a distance that the respective corresponding suction ports 710 and 720 are positioned at the aforementioned locations when the rotational valve 820 is rotated according to the rotational direction of the crankshaft 300.
Furthermore, the third suction port 730 is formed to be placed adjacent to one side of the vane 110 with respect to the installation location of the vane 110, and is supplied with refrigerant from, for example, an accumulator, through a first communication hole 102 formed on the cylinder.
Formed on a lower-inner circumference of the stationary valve 810 is a hook step 811 protruded inwardly, a thickness of which is less than that of the stationary valve 810. Formed on an outer circumference of the rotational valve 820 are at least one, for instance, first stopper 821 and second stopper 822 that are hooked on the hook step 811 according to its rotational direction of the rotational valve 820. In other words, when the rotational valve 820 rotates for an operation of a high capacity refrigerant compression ratio, the first stopper 821 is hooked on the hook stopper 811, and when the rotational valve 820 rotates for an operation of a lower capacity refrigerant compression ratio, the second stopper 822 is hooked on the hook stopper 811.
The first stopper 821 is adjacently disposed between the first and second suction ports 710 and 720, and the second stopper 822 is spaced apart from the first stopper 821 by a predetermined circumferential distance.
Meanwhile, as shown in
The first and second refrigerant flowing portions 823 and 824 are defined by grooves formed along a circumference periphery of a bottom of the rotational valve 820.
The refrigerant flowing portion further includes a third refrigerant flowing portion 221 formed on the top of the lower bearing 220. The third refrigerant flowing portion 221 is designed corresponding to the location of the second stopper 822 of the rotational valve 820 when the rotational valve 820 is rotated to the low capacity operational mode. In other words, in the low capacity operational mode, the third refrigerant flowing portion 221 allows the third suction port 730 of the stationary valve 810 to communicate with the second suction port 720 of the rotational valve 820.
The operation of the above-described rotary compressor will be described in more detail with reference to
The rotary compressor is designed to selectively operate in either one of low and high capacity operational modes.
When the operation mode of the rotary compressor is set to the high capacity operational mode, the crankshaft 300 rotates counterclockwise in a state where the valve assembly is varied to a state shown in
At this point, the refrigerant fed into the compressor is directed to the third suction port 730 through the first communication hole 102, and the roller 400 mounted around an eccentric portion 310 of the crankshaft 300 eccentrically rotates from a state shown in
By the rotation of the roller 400, fluid between the bottom of the roller 400 and the rotational valve 820 flows in the rotational direction (counterclockwise) of the roller 400.
At this point, viscosity of the fluid allows the rotational valve 820 to rotate in the rotational direction of the roller 400.
Furthermore, when the first stopper 821 of the rotational valve 820 is caught by the hook step 811 formed on the inner circumference of the stationary valve 810 in the course of moving along the inner circumference of the stationary valve 810, the rotation of the rotational valve 820 stops.
When the rotational valve 820 rotates counterclockwise as described above, the first suction port 710 of the rotational valve 820 communicates with the third suction port 730 of the stationary valve 810. As a result, the refrigerant fed to the third suction port 730 through the first communication hole 102 of the cylinder 100 is directly supplied to the first suction port 710 formed on the rotation valve 820.
At this point, the second suction port 720 formed on the rotational valve 820 and opened to the compression chamber 101 is maintained in a closed state.
Accordingly, the refrigerant fed to the first suction port 710 is directed to the compression chamber 101 by a pressure difference, and is then further gradually compressed as the roller 400 eccentrically rotates together with the crankshaft 300 and the eccentric portion 310 as shown in
When the compression of the refrigerant is completely realized as shown in
A series of above-described operating processes are continued unless the operation of the compressor is stopped or reversed.
When the operation mode is converted into the low capacity operational mode, the valve assembly is rotated to a state shown in
The rotation of the crankshaft 300 allows the roller 400 to roll along the inner circumference of the compression chamber 101, by which the fluid between the bottom of the roller 400 and the rotational valve 820 flows in the rotational direction of the roller 400. At this point, viscosity of the fluid lets the rotational valve 820 rotate in the rotational direction of the roller 400.
The above process is identical to that in the high capacity operational mode except for the rotational direction of the roller 400 and the flowing direction of the refrigerant.
When the second stopper S21 of the rotational valve 820 is caught by the hook step 811 formed on the inner circumference of the stationary valve 810 in the course of moving along the inner circumference of the stationary valve 810, the rotation of the rotational valve 820 stops.
When the rotational valve 820 rotates clockwise as described above, the space for receiving the refrigerant is defined at a right side of the vane 110 and the space for compression is defined at a left side of the vane 110.
The second suction port 720 of the rotational valve 820 is disposed adjacent to the right side of the vane 110, and the first suction port 710 of the rotational valve 820 is located on a portion corresponding to the hook step 811 of the stationary valve 810 as shown in
At this point, the second suction port 720 communicates with the third suction port 730 of the stationary valve 810 by the first refrigerant flowing portion 823, and the first suction port 710 communicates with the third suction port 730 of the stationary valve 810 by the second refrigerant flowing portion 824 and the third refrigerant flowing portion 221 formed on the top of the lower bearing 220.
Accordingly, the refrigerant fed to the third suction port 730 through the first communication hole 102 of the cylinder 100 is directed to the second suction port 720 through the first refrigerant flowing portion 823 formed on the rotational valve 820, and is further directed to the compression chamber 101 through the second and third refrigerant flowing portions 824 and 221.
The compression of the refrigerant fed into the compression chamber 101 starts from a point where the roller 400 passes the first suction port 720.
At this point, the refrigerant fed into the compression chamber 101 through the second suction port 720 prevents the inner space of the compression chamber 101 from being under vacuum until it reaches a position where the first suction port 710 communicates after it passes through a position where the vane 110 is located, thereby reducing noise caused by vacuum and improving the compression efficiency.
As shown in
A series of above-described operating processes are continued unless the operation of the compressor is stopped or reversed.
Meanwhile, during operation in the high capacity operational mode, there may be a dead area as the second suction port 720 of the rotational valve 820 is located in the compression chamber 101.
Particularly, when considering the second suction port 720 is communicating with the first refrigerant flowing portion 823, the dead area may also be formed on the first refrigerant flowing portion 823, reducing the compression efficiency.
Therefore, in a second embodiment of the present invention, a second suction port 720 disposed out of the compression chamber 101 is proposed.
In other words, the second embodiment provides a valve assembly having a central axis, which is eccentric with respect to a central axis of the crankshaft 300. The second embodiment will be described in more detail with reference to
The valve assembly of this embodiment comprises rotational and stationary valves 820 and 810 that are similar to those of the first embodiment.
In other words, the rotational valve 820 is provided with first and second suction ports 710 and 720, first and second stoppers 821 and 82′, first and second fluid flowing portions 823 and 824, and a hook step 811.
The rotational valve 820 is further provided with a penetration hole 829 having a diameter greater than that of the crankshaft 300 by an eccentric distance of the valve assembly. The greater diameter of the penetration hole 829 enables the crank-shaft to smoothly rotate.
The eccentric distance of the valve assembly is designed such that the second suction port 720 of the rotational valve 820 is located out of the compression chamber 101 in the high capacity operational mode and is located in the compression chamber 101 in the low capacity operational mode.
The third refrigerant flowing portion 221 formed on the top of the lower bearing 220 is formed on a location displaced by the eccentric distance so that the third suction port 730 of the stationary valve 820 and the second refrigerant flowing portion 824 of the rotational suction port 730 can communicate with each other.
The operation of the rotary compressor of this embodiment will be described in more detail hereinafter.
In the high capacity operational mode, the crankshaft 300 rotates counterclockwise and the roller 400 eccentrically rotates in the compression chamber 101 in association with the rotation of the crankshaft 300.
At this point, the refrigerant fed into the compressor is directed to the third suction port 730 through a first communication hole 102 of the cylinder 100, and the roller 400 mounted around the eccentric portion 310 of the crankshaft 300 eccentrically rotates (i.e., rotates from a state shown in
As the roller rotates, fluid between the bottom of the roller 400 and the rotational valve 820 flows in the rotational direction of the roller.
At this point, viscosity of the fluid allows the rotational valve 820 to rotate in the rotational direction (counterclockwise) of the roller 400.
When the first stopper 821 is caught by the hook step 811 formed on the inner circumference of the stationary valve 810 in the course of moving along the stationary valve 810, the rotation of the rotational valve 820 stops.
When the rotational valve 820 rotates counterclockwise, the first suction port 710 of the rotational valve 820 is located communicating with the third suction port 730 of the stationary valve 810.
As a result, the refrigerant fed to the third suction port 730 through the first communication hole 102 of the cylinder 100 is directly directed to the first suction port 710 formed on the rotational valve 820.
However, as the valve assembly is mounted to be eccentric with respect to the central axis of the crankshaft 300 (or a central axis of the compression chamber 101) by a predetermined distance in a predetermined direction, the second suction port 720 is closed in a state where it is disposed out of the compression chamber 101.
Accordingly, the refrigerant fed to the first suction port 710 is directed into the compression chamber 101 by a pressure difference, and is then gradually compressed as the roller eccentrically rotates together with the rotation of the crankshaft 400 and the eccentric portion 310 as shown in
When the compression is completed as shown in
A series of above-described operating processes are continued unless the operation of the compressor is stopped or reversed.
When the operation mode is converted into the low capacity operational mode, the crankshaft 300 rotates clockwise from a state shown in
The rotation of the crankshaft 300 allows the roller 400 to rotate, by which the fluid between the bottom of the roller 400 and the rotational valve 820 flows in the rotational direction of the roller 400. At this point, viscosity of the fluid lets the rotational valve 820 rotate in the rotational direction of the roller 400.
The above process is identical to that in the high capacity operational mode except for the rotational direction of the roller 400 and the flowing direction of the refrigerant.
When the second stopper 821 of the rotational valve 820 is caught by the hook step 811 formed on the inner circumference of the stationary valve 810, the rotation of the rotational valve 820 stops.
When the rotational valve 820 rotates clockwise as described above, the space for receiving the refrigerant is defined at a right side of the vane 110, and the space for compression is defined at a left side of the vane 10.
The second suction port 720 of the rotational valve 820 is disposed adjacent to the right side of the vane 110, and the first suction port 710 of the rotational valve 820 is located on a portion corresponding to the hook step 811 of the stationary valve 810.
At this point, the second suction port 720 communicates with the third suction port 730 of the stationary valve 810 by the first refrigerant flowing portion 823, and the first suction port 710 communicates with the third suction port 730 of the stationary valve 810 by the second refrigerant flowing portion 824 and the third refrigerant flowing portion 221 formed on the top of the lower bearing 220.
Accordingly, the refrigerant fed to the third suction port 730 through the first communication hole 102 of the cylinder 100 is directed to the second suction port 720 through the first refrigerant flowing portion 823 formed on the rotational valve 820 and is further directed to the compression chamber 101 through the second and third refrigerant flowing portions 824 and 221.
The compression of the refrigerant fed into the compression chamber 101 starts from a point where the roller 400, eccentrically rotating and rolling, passes the first suction port 720, and it gradually proceeds as shown in
At this point, the refrigerant fed into the compression chamber 101 through the second suction port 720 prevents the inner space of the compression chamber 101 from being under vacuum until it reaches a position where the first suction port 710 communicates after it passes through a position where the vane 110 is located, thereby reducing noise caused by vacuum and improving the compression efficiency.
As shown in
A series of above-described operating processes are continued unless the operation of the compressor is stopped or reversed.
Ideally, no oil should be contained in the refrigerant to be compressed to improve the compression efficiency. However, a small amount of oil will be contained in the refrigerant fed into the cylinder 100 from an accumulator or the like, deteriorating the compression efficiency.
Particularly, in the high capacity operational mode, since the first suction port 710 of the rotational valve 820 is directly communicated with the third suction port 730, the fluid is poured into the compression chamber 101 without being discharged to the outside.
Furthermore, since an amount of refrigerant fed to the third suction port 730 is varied due to the uneven pouring pressure of the accumulator, an amount of the refrigerant fed into the compression chamber 101 through the first suction port 710 is also varied, as a result of which desired compression efficiency cannot be obtained.
Therefore, a third embodiment of the present invention is proposed to solve the above-described problems of the second embodiment.
In the third embodiment, as shown in
The valve assembly of this embodiment comprises rotational and stationary valves 820 and 810 that are identical to those of the second embodiment.
The refrigerant storing portion 500 is connected to an outer refrigerant storing container such as an accumulator by a refrigerant tube 11. The lower bearing 220 is provided with at least one second communication hole 222 communicating with an inner space of the refrigerant storing portion 500.
The second communication hole 222 is formed corresponding to the third suction port 730 of the stationary valve 810.
It is also possible that the lower bearing 220 is provided with a communication hole (not shown) disposed corresponding to a position where the first suction port 710 of the rotational valve 820 is located during the operation in the high capacity operational mode, and another communication hole (not shown) disposed corresponding to a position where the first suction port 710 of the rotational valve 820 is located during the operation in the low capacity operational mode.
The refrigerant is first fed from the outer refrigerant storing member into the refrigerant storing portion 500 through the refrigerant tube 11, and is then directed to the third suction port 730 through the second communication hole 222. The refrigerant directed to the third suction port 730 is further directed to the second refrigerant flowing portion 824 or directly to the first suction port 710 of the rotational valve 820. The refrigerant is then fed into the compression chamber 101 through the second suction port 720 by the first refrigerant flowing portion 823.
At this point, although the refrigerant flowing into the refrigerant storing portion 500 contains a predetermined amount of oil, the refrigerant and the oil are separated from each other in the refrigerant storing portion 500 due to a difference in their specific gravities. In other words, the oil is disposed beneath the refrigerant in the storing portion 500. Therefore, only the refrigerant is discharged to the third suction port 730.
Accordingly, little oil is contained in the refrigerant fed into the compressing chamber 101, improving the compression efficiency.
Furthermore, even when the refrigerant is unevenly supplied from the accumulator, since the refrigerant is discharged after being stored in the storing chamber, the refrigerant can be evenly fed to the third suction port 730.
Particularly, since the refrigerant storing portion functions as the accumulator, a separate accumulator can be omitted.
Here,
In the third embodiment, the refrigerant storing portion 500 is applied to a compressor designed as in the second embodiment having the eccentric valve assembly. However, in this fourth embodiment, the refrigerant storing portion 500 is applied to a compressor designed as in the first embodiment.
In this fourth embodiment, since the valve assembly is not eccentric with respect to the central axis of the compression chamber 101, the problem of the dead area remains. However, as the mixture of oil with the refrigerant can be minimized, the compression efficiency can be improved when compared with the first embodiment.
Furthermore, the disposition of the valve assembly is not limited to the above-described embodiments. In other words, the valve assembly can be disposed between is the cylinder 100 and the upper bearing 210.
As described above, the rotary container of the present invention has a following variety of advantages.
First, since the container is designed to operate in a variety of modes each having a different compression capacity, it can be applied to a variety of applications, i.e., by simply converting the rotational direction of the crankshaft the container can operate in either high or low capacity operational modes.
Second, since the dead area can be eliminated by the eccentric valve assembly, the compression efficiency can be remarkably improved;
Third, since the refrigerant can be uniformly supplied to the compression chamber by adding the refrigerant storing portion, the desired compression efficiency can be obtained.
Fourth, by separating oil from the refrigerant fed from the compression chamber as large as possible, the deterioration of the compression efficiency, which may be caused by the oil, can be prevented.
It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention. Thus, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2003-0030308 | May 2003 | KR | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/KR04/00956 | 4/26/2004 | WO | 00 | 2/12/2007 |
