KR101573938B1 - compressor - Google Patents

Abstract

The present invention relates to a compressor that compresses a refrigerant while rotating in a state in which a rotating member is suspended from a stationary member. More particularly, the present invention relates to a compressor that is installed to suspend a rotating member from a first stationary member, So that the refrigerant can be sucked and discharged in the axial direction even if the rotating member is provided on the outer surface of the fixing member. Therefore, the height of the product can be reduced have.

Compressor, fixing member, rotary member, fixed shaft, eccentric portion, cylinder, rotor, roller, vane, upper bearing, lower bearing

Description

COMPRESSOR

The present invention relates to a compressor that compresses a refrigerant while rotating while a rotary member is suspended from a fixing member while being supported on a bearing. In particular, not only structural stability but also assemblability can be improved, And more particularly, to a compressor capable of effectively sucking and discharging refrigerant.

2. Description of the Related Art Generally, a compressor is a mechanical device that receives power from an electric motor or a power generating device such as a turbine and compresses air, refrigerant or various other operating gases to increase its pressure. Or widely used throughout the industry.

Such a compressor is broadly classified into a reciprocating compressor that compresses the refrigerant while linearly reciprocating the piston inside the cylinder so as to form a compression space in which a working gas is sucked and discharged between the piston and the cylinder. A rotary compressor for compressing the working gas in a compression space formed between a roller and a cylinder to be eccentrically rotated and a rotary compressor for compressing the working gas in a compression space formed between a roller and a cylinder, And a scroll compressor that compresses the refrigerant while rotating the orbiting scroll along the fixed scroll so that a compression space in which the working gas is sucked and discharged is formed in the scroll compressor.

Reciprocating compressors have excellent mechanical efficiency, but these reciprocating movements cause severe vibration and noise problems. Because of this problem, rotary compressors have been developed due to their compactness and excellent vibration characteristics.

The rotary compressor is configured such that a motor portion and a compression mechanism portion are mounted on a drive shaft in a hermetically sealed container. The roller located around the eccentric portion of the drive shaft is located in a cylinder forming a cylindrical compression space, And extends between the compression spaces to divide the compression space into a suction region and a compression region, and the roller is positioned eccentrically in the compression space. Generally, the vane is configured to be supported by a spring on the recessed portion of the cylinder so as to press the surface of the roller, and by this vane, the compression space is divided into the suction region and the compression region as described above. The suction region gradually increases in accordance with the rotation of the drive shaft, so that the refrigerant or the working fluid is sucked into the suction region and the compressed region is gradually reduced, thereby compressing the refrigerant or the working fluid therein.

In such a conventional rotary compressor, since the motor portion and the compression mechanism portion are stacked vertically, there is a problem that the height of the compressor inevitably increases as a whole. In addition, in the conventional rotary compressor, since the weight of the motor portion and the compression mechanism portion are different from each other, a difference in inertial force is generated, and inevitably unbalance occurs on the upper and lower sides around the drive shaft. Therefore, in order to compensate for the unbalance between the motor unit and the compression mechanism unit, a weight member can be added to the weight member having a relatively small weight. However, this results in an additional load applied to the rotating member, . In addition, in the conventional rotary compressor, since the eccentric portion is formed in the drive shaft in the compression mechanism, the eccentric portion is rotated together with the rotation of the drive shaft to drive the roller outside the eccentric portion. As a result, in the eccentric rotation of the drive shaft and eccentric portion There is a problem that the vibration due to the vibration is inevitably generated. Further, in the conventional rotary compressor, the eccentric portion of the drive shaft rotates continuously and slidingly contacts the inner surface of a stationary cylinder to which the roller is fixed, and also continuously slides on the end surface of the vane, Since there is a high relative speed between the sliding contact elements, friction loss is generated. This leads to a reduction in the efficiency of the compressor. Furthermore, there is a possibility that the refrigerant leaks from the contact surface between the sliding contact vane and the roller So that the mechanical reliability is lowered.

The conventional rotary compressor has a configuration in which a drive shaft rotates inside a fixed cylinder, while in Japanese Unexamined Patent Publication Nos. 62-284985 and 64-100291, a shaft having an intake port in the axial direction and a shaft larger than the shaft A fixed shaft integrally formed with a piston eccentric in diameter and having a port communicating with a suction port of the shaft in a radial direction; A vane that is installed so as to be able to be run; A rotor rotatable about said vane; An upper bearing having a discharge port; Lower bearing; A permanent magnet having a hollow cylindrical shape having a height greater than a difference between an outer diameter and an inner diameter, the permanent magnet being fixed to the lower bearing; And a coil that is not rotated on the outer periphery of the permanent magnet. By configuring the upper and lower rotors so as to be rotatable by sequentially connecting the rotor and the lower bearing, the space between the rotor, the upper bearing and the lower bearing, And a rotary compressor.

In the rotary compressor disclosed in Japanese Unexamined Patent Publication (KOKAI), since the hollow cylindrical permanent magnet is located inside the stator, and the rotor and the compression mechanism section including the vane are located inside the permanent magnet, the motor section and the compression mechanism section It is possible to solve the problem that occurs.

However, since the rotary compressor disclosed in the above Japanese Patent Laid-open Publication No. Hei 10-24185 is resiliently supported by the rotor in which the vane rotates, and is in sliding contact with the outer surface of the eccentric portion (piston portion) There is still a problem that there is a possibility of refrigerant leakage at the contact surface between the vane and the eccentric portion which is in sliding contact as well as friction loss due to the existence of a high relative speed difference as in the rotary compressor. In addition, the rotary compressor disclosed in the above Japanese Laid-Open Patent Publications does not disclose any realizable structure for the suction and discharge flow of the operating fluid, the lubrication oil supply in the compression mechanism portion, and the mounting of the bearing member. It is not reaching to the extent possible.

Alternatively, U.S. Patent Publication No. 7,217,110 discloses a rotary compressor in which a fixed shaft and an eccentric portion are integrally formed, and a compression space is formed between an outer surface of a roller rotatably positioned in an eccentric portion and an inner surface of a rotating rotor . Here, the rotational force of the rotor is transmitted to the roller through a vane fixed to the upper and lower plates of the rotor rotating integrally with the rotor. By using the pressure inside the sealed container and the pressure difference inside the compression space, And the working fluid and the lubricating oil are introduced into the compression space through the formed longitudinal flow passage.

Therefore, the rotary compressor disclosed in the above-mentioned U.S. Patent Application Publication No. 2000-227558 also can solve the problems due to the fact that the motor unit and the compression mechanism unit are installed in the height direction in the conventional rotary compressor because the compression mechanism is formed inside the rotor. Further, unlike the Japanese Laid-Open Patent Publications, there is no difference in relative speed between the rotors, the vanes and the rollers because they rotate integrally, and there is no fear of frictional loss caused thereby.

However, since the one end of the fixed shaft is fixed to the hermetically sealed container, the other end of the fixed shaft is formed to be suspended from the hermetically sealed container while being separated from the hermetically sealed container, so that the center of the fixed shaft is assembled And is very vulnerable to lateral vibration due to inevitable eccentric rotation due to the nature of the rotary compressor. Thus, there is a problem in that it is difficult to actually manufacture the compressor and the assembling productivity is poor. In addition, since the vane is formed inwardly from the rotor and the vane groove is formed in the roller so as to guide the movement locus of the vane, the volume of the roller inevitably becomes large for forming the vane groove and a roller of a relatively large volume There is a problem that oscillation in the lateral direction is excited by eccentric rotation. However, in the case of a structure using lubricating oil, it is necessary to use lubricating oil in the inside of the sealed container and the pressure difference in the compression space, In this case, not only a lot of lubricating oil is inevitably incorporated in the working fluid but also the lubricating performance is deteriorated because the compressor can be escaped with the working fluid, because the lubricating oil is drawn into the compression space and circulated together with the working fluid.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a compressor which can easily assemble components to a hermetically sealed container and improve structural safety.

It is another object of the present invention to provide a compressor that not only reduces lateral vibration due to eccentric rotation but also facilitates actual production and assembly.

Another object of the present invention is to provide a compressor capable of effectively lowering the height of a product and simultaneously sucking and discharging refrigerant.

According to an aspect of the present invention, there is provided a compressor including: a sealed container in which a refrigerant is sucked and discharged; A stator fixed in the hermetically sealed container; A first fixing member including an upper end fixed to the hermetically sealed container so as not to move, an eccentric portion formed to be eccentric with respect to the fixed shaft, the fixed shaft extending long into the hermetically sealed container; A second fixing member formed to be spaced apart from a lower end of the first fixing member and installed so as not to move under the airtight container; A cylindrical rotor rotatable about a fixed axis by a rotating electromagnetic field from the stator, a rotating shaft rotatable about the eccentric portion, and a cylindrical rotor rotatable about the eccentric portion, And a vane for transmitting a rotational force from the cylindrical rotor to the roller and partitioning the compression space into a suction pocket for suctioning the refrigerant and a compression pocket for compressing and discharging the refrigerant, A rotatable member supported as far as possible; And a refrigerant suction passage provided on the upper portion of the fixed shaft and the eccentric portion and the roller so that the refrigerant is sucked into the compression space.

In addition, in the present invention, the rotating member further includes upper and lower bearing covers that form upper and lower portions of the compression space and rotate about the fixed shaft together with the cylindrical rotor, and the lower bearing cover includes a lower shaft cover And a lower cover portion coupled with the cylinder to form a lower portion of the compression space.

Further, in the present invention, the lower shaft portion is formed to extend from the lower end of the fixed shaft, and the end portion of the lower shaft portion is rotatably supported while applying a load of the rotary member to the second fixing member.

According to the present invention, the second fixing member includes a cylindrical bearing portion having a stepped portion inside, the lower end portion of the lower shaft portion is supported by the step difference of the second fixing member, and the outer surface of the lower shaft portion is journaled on the inner surface of the cylindrical bearing portion. .

Further, in the present invention, at least one of the upper and lower bearing covers is fastened to the cylindrical rotor by a fastening member.

Further, in the present invention, the refrigerant suction path includes a vertical suction flow path vertically communicated along the central axis direction of the fixed shaft and the eccentric portion, a horizontal suction flow path horizontally communicated along the radial direction of the eccentric portion so as to communicate with the vertical suction flow path A ring-shaped suction guide passage formed between the eccentric portion and the roller so as to communicate with the horizontal suction passage; and an inlet formed in the roller to communicate the suction guide passage suction passage and the compression space.

Further, in the present invention, a plurality of horizontal suction passages are provided.

Further, in the present invention, the suction guide passage is a groove portion formed along at least one of the circumferential surface of the eccentric portion and the inner circumferential surface of the corresponding roller.

Further, in the present invention, the suction port of the roller is located close to the vane.

Further, in the present invention, the cylindrical rotor further includes upper and lower bearing covers which form upper and lower portions of the compression space and rotate about the fixed shaft together with the cylindrical rotor, and one of the upper and lower bearing covers And a discharge port through which the compressed refrigerant is discharged from the compression space and a discharge valve for opening and closing the compressed refrigerant are provided.

Further, in the present invention, the discharge port of the upper bearing cover is located close to the vane.

Further, in the present invention, the rotary member further includes a muffler coupled in the axial direction of the upper bearing cover to reduce noises, and the muffler is provided with a discharge port through which the refrigerant between the upper bearing cover and the muffler can escape .

Further, in the present invention, the hermetically sealed container is provided with a discharge pipe for allowing the high-pressure refrigerant to escape to the outside.

Further, in the present invention, the eccentric portion is characterized by protruding in all the radial directions of the fixed shaft.

The compressor according to the present invention configured as described above is assembled so that the rotary member is suspended from the fixing member, then the fixing member is fixed to the upper bearing and the rotary member is rotatably supported on the lower bearing, and the upper and lower bearings are sealed Since the components are fixed to the container, the components can be easily assembled to the airtight container so that the structural safety and assemblability can be improved.

In the compressor according to the present invention, even when the eccentric portion is eccentric from the axial center of the fixed shaft, the compressor rotates about the fixed shaft while the cylindrical rotor rotates about the eccentric portion The eccentric rotation is not generated because the cylindrical rotor and the roller rotate around the respective axes. As a result, in order to reduce the lateral vibration due to the eccentric rotation and to reduce the vibration due to the eccentric rotation, It is possible to omit it, and the efficiency can be increased.

Further, the compressor according to the present invention is characterized in that, even if the compressor is installed so as to hang the rotary member on the outer circumferential surface of the fixing member, the refrigerant suction passage is axially provided on the fixed shaft of the fixing member, Since the rotary member is provided on the outer periphery of the fixing member, even if the height of the compressor is reduced, effective suction and discharge of the refrigerant can be achieved.

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

1 to 3 are a side sectional perspective view and an exploded perspective view and a side sectional view showing an example of a compressor according to the present invention.

An example of the compressor according to the present invention includes a sealed container 110, a stator 120 fixed in the sealed container 110, and a rotating electromagnetic field from the stator 120, as shown in Figs. 1 to 3, A rotary member 130 installed to be rotatable inside the rotary shaft 120 to compress the refrigerant and a rotary member 130 installed to hang on the outer circumferential surface of the rotary shaft 130. Upper and lower ends of the rotary shaft 141 are moved to the closed container 110 An upper bearing 150 which fixes the upper end of the fixed shaft 141 to the inside of the closed container 110 and a lower bearing 150 which is spaced from the lower end of the fixed shaft 141, And a lower bearing 160 which is fixed to the inside of the hermetically sealed container 110 so as to be rotatably supported on the upper surface. Here, the transmission mechanism for providing the power through the electric action includes the rotor 131 of the rotary member 130 including the stator 120, and the compression mechanism for compressing the refrigerant through the mechanical action includes the rotary member 130 (Not shown). Therefore, by providing the transmission mechanism and the compression mechanism in the radial direction, the overall compressor height can be reduced.

The hermetically sealed container 110 includes a cylindrical body 111 and upper and lower shells 112 and 113 coupled to the upper and lower portions of the body 111. A rotary member 130 and a fixing member 140 ) Can be stored up to an appropriate height. In the embodiment of the present invention, the upper shell 112 is provided with a high pressure type. In the center of the upper shell 112, for example, a suction shaft (not shown) through which the refrigerant is sucked is directly exposed to the fixing shaft 141, And a discharge pipe (114) through which refrigerant can be discharged is provided at a predetermined position. Of course, depending on whether the inside of the closed container 110 is filled with the compressed refrigerant or filled with the refrigerant before being compressed, the high pressure type or the low pressure type is determined, so that the suction pipe and the discharge pipe may be changed. In the embodiment of the present invention, the fixed shaft 141, which is a high-pressure type suction pipe, protrudes outside the hermetically sealed container 110. However, it is not necessary that the fixed shaft 141 is excessively protruded to the outside of the hermetic container 110, and it is preferable that an appropriate fixing structure is provided outside the hermetic container 110 so as to be connected to the external refrigerant pipe. In addition, the upper shell 112 is provided with a terminal 115 for supplying power to the stator 120.

The stator 120 is composed of a core and a coil that is concentratedly wound around the core, and is fixed to the inside of the body 111 of the closed container 110 by heat shrinkage. The core employed in the conventional BLDC motor has nine slots along the circumference whereas in the preferred embodiment of the present invention the diameter of the stator 120 is relatively large such that the core of the BLDC motor has twelve slots along the circumference . As the number of slots of the core increases, the number of windings of the coil increases. Therefore, in order to generate the electromagnetic force of the conventional stator 120, the height of the core may be reduced.

The rotating member 130 includes cylindrical rotors 131 and 132, a roller 133, a vane 134, a bush 135, an upper bearing cover 136 and a muffler 137, a lower bearing cover 138 ). The cylindrical rotors 131 and 132 include a rotor 131 having a plurality of permanent magnets in the axial direction so as to rotate by a rotating electromagnetic field from the stator 220 and a rotor 131 located inside the rotor 131, The rotor 131 and the cylinder 132 may be formed separately and formed into a single body in the form of a laminate in which a powder sintered body or a steel piece is laminated, . The roller 133 is rotatably mounted in a cylindrical shape on the outer circumferential surface of the eccentric portion 142 of the fixing member 140 to be described later so that a lubricant structure is applied between the roller 133 and the eccentric portion 142 . At this time, between the roller 133 and the eccentric portion 142, there are suction guide passages 133A and 142C through which the refrigerant can be sucked, and the roller 133 is provided with suction holes (not shown) communicating with the suction guide passages 133A and 142C 133a. The vane 134 is integrally provided on the outer circumferential surface of the roller 133 so as to be positioned at one side of the suction port 133a of the roller 133 and is integrally provided on the inner circumferential surface of the cylindrical rotor 131 or 132 or the cylinder 132 And is fitted to the vane mount 132H. The bush 135 is installed to support both sides of the end of the vane 134 fitted in the vane mount 132H of the cylindrical rotors 131 and 132. Of course, a lubrication structure is applied so that the vane 134 smoothly moves between the vane mount 132H and the bush 135 of the cylindrical rotors 131, 132.

The upper bearing cover 136 and the muffler 137 and the lower bearing cover 138 are coupled to the cylindrical rotors 131 and 132 in the axial direction and between the cylindrical rotors 131 and 132 and the roller 133 and the vane 134 And is provided so as to contact the journal bearing or the thrust bearing at a portion abutting the fixing member 140. [ The upper bearing cover 136 is provided with a discharge port (not shown) through which the compressed refrigerant can be discharged in the compression space and a discharge valve 136A installed therein. In order to reduce the dead volume, It is preferable that the vane 133 is positioned adjacent to the vane 133. [ The muffler 337 is coupled to the upper surface of the upper bearing cover 136 and is provided with a discharge chamber capable of reducing the opening and closing noise of the discharge valve 136A and the flow noise of the high-pressure refrigerant, (Not shown) provided in the cover 136 and the muffler 137, respectively. The upper bearing cover 136 and the muffler 137 are coupled to the upper surfaces of the cylindrical rotors 131 and 132 and the lower bearing cover 137 is coupled to the lower surfaces of the cylindrical rotors 131 and 132. The lower ends of the cylindrical rotors 131 and 132 ) At one time by a fastening member such as a long bolt or the like.

The fixing member 140 includes a fixed shaft 141 provided in a cylindrical shape and a fixed shaft 141 in a radial direction of the fixed shaft 141 so as to have a cylindrical shape with a larger diameter than the cylindrical shape of the fixed shaft 141 And an eccentric portion 142 eccentrically formed on the fixed shaft 141. The first oil supply passage 141A through which the oil stored in the hermetically sealed container 210 can be supplied is formed in the lower portion of the fixed shaft 141 while the low pressure refrigerant can be sucked into the upper portion of the fixed shaft 141 Since the vertical suction passage 141B is formed and the first oil supply passage 141A and the vertical suction passage 141B are formed to be isolated from each other, the oil can be prevented from escaping with the refrigerant. The eccentric part 142 is formed to extend in all the radial directions of the fixed shaft 141 and extends in the radial direction of the eccentric part 142 so as to communicate with the vertical suction passage 141B of the fixed shaft 141 A horizontal suction passage 142B is provided. Of course, since the roller 133 rotates along the outer circumferential surface of the eccentric portion 142 and the annular suction guide flow paths 133A and 142C are provided between the inner circumferential surface of the roller 133 and the outer circumferential surface of the eccentric portion 142, The vertical suction passage 141B of the fixed shaft 141, the horizontal suction passage 142B of the eccentric portion 142, the suction guide flow paths 133A and 142C between the roller 133 and the eccentric portion 142, To the compression space along the suction port 133a. Since the upper and lower surfaces of the eccentric portion 142 abut against the upper and lower bearing covers 136 and 137 to act as a thrust surface, it is preferable that a supply passage for the lubricant is formed on the upper and lower surfaces of the eccentric portion 142 And the roller 133 is provided so as to abut against the outer circumferential surface of the eccentric portion 142 so as to be rotatable. Therefore, it is preferable that a lubricant supply passage extending to the outer circumferential surface is formed on the inner side of the eccentric portion 142.

The upper and lower bearings 150 and 160 fix the fixing shaft 141 to the hermetically sealed container 110 so as not to move, and rotatably support the rotary member 130. The upper bearing 150 is fixed to the upper shell 112 of the sealed container 110 by welding or the like after the upper portion of the fixed shaft 141 is fitted. At this time, the upper bearing 150 is formed to be smaller in the radial direction than the lower bearing 160, in order to prevent interference with the discharge tube 114 or the terminal 115 provided in the upper shell 112. Meanwhile, the lower bearing 160 is separated from the lower portion of the fixed shaft 141, the shaft portion of the lower bearing cover 136, which surrounds the lower portion of the fixed shaft 141, is rotatably supported by the thrust bearing 161, And is fixed to the side of the body 111 of the closed container 110 by heat shrinking or three-point welding. The vane 133, the upper and lower bearing covers 135 and 136, the fixed shaft 141 and the eccentric portion 142 are all cast by cast iron, and then the upper and lower bearings 150 and 160 are formed by press working. Grinding and further machining.

The upper and lower bearing covers 136 and 138 are rotatably installed on the fixing member 130 and the lower bearing 160. The upper and lower bearing covers 136 and 138 are rotatably mounted on the fixing member 140. [ More specifically, the upper bearing cover 136 includes an upper shaft portion 136a having an inner circumferential surface surrounding the upper portion of the fixed shaft 141 and a journal bearing, and an upper cover 136b having a thrust bearing on a lower surface thereof, And the upper cover portion 136b is bolted to the bottom surface of the cylindrical rotor 131 or 132. [ The lower bearing cover 138 includes a lower shaft portion 138a having a journal bearing on an inner circumferential surface surrounding the lower portion of the fixed shaft 141 and a lower cover portion 138b having a thrust bearing on an upper surface contacting the bottom surface of the eccentric portion 142 138b. The lower bearing 160 includes a stepped cylindrical bearing portion 160a surrounding the lower shaft portion 138a and a mounting portion 160b extending in the radial direction of the bearing portion 160a to be welded and fixed to the inside of the closed container 110 ). A journal bearing for supporting the outer circumferential surface of the lower shaft portion 138a is provided on the inner circumferential surface of the bearing portion 160a and a thrust bearing for supporting the lower end of the lower shaft portion 138a is provided on the stepped bottom surface of the bearing portion 160a. Or a separate plate-shaped thrust bearing 161 may be interposed therebetween.

Therefore, when the upper and lower bearing covers 136 and 138 are coupled to the cylindrical rotors 131 and 132 and the fixing member 240 in the axial direction, the bottom surface of the upper cover portion 136b of the upper bearing cover 136 contacts the cylindrical rotor And the cover portion 138b of the lower bearing cover 138 is bolted to abut the bottom surface of the cylindrical rotors 131 and 132. As shown in FIG. At this time, since the upper shaft portion 136a is journal-bearing supported on the upper portion of the fixed shaft 141 and the upper cover portion 136b is supported on the upper surface of the eccentric portion 142, The lower bearing portion 138a is supported by the journal bearing under the fixing shaft 141 and the lower cover portion 138b is supported by the lower surface of the eccentric portion 142 so that the lower bearing cover 138 is rotatably supported. Is rotatably provided with respect to the fixing member (140). The lower bearing portion 138a of the lower bearing cover 138 is fitted to the bearing portion 160a of the lower bearing 160. Since the lower bearing cover 138 is supported by the journal surface or the thrust surface, And is rotatably supported with respect to the lower bearing 160.

4 is a plan view of the vane mounting structure of the compressor according to the present invention.

Referring to FIG. 4, the mounting structure of the vane 134 may include a vane mounting hole 132H, which is formed in the inner peripheral surface of the cylindrical rotor 131, 132 in a radial direction and passes through in the axial direction, A pair of bushes 135 are fitted in the bushes 135 and 132 and 132H and then a vane 134 integrally formed on the outer circumferential surface of the roller 133 is inserted between the bushes 135. [ At this time, a compression space is provided between the cylindrical rotors 131 and 132 and the roller 133, and the compression space is divided into the suction pocket S and the compression pocket D by the vane 134. The suction port 133a of the roller 133 is located at one side of the vane 134 so as to be in communication with the suction pocket S and is located at the discharge port of the upper bearing cover 136 136A (shown in FIG. 2) is located on the other side of the vane 134 in communication with the compressed pocket D, and is preferably located in close proximity to the vane 134 to reduce the corpuscular mass. As described above, in the compressor of the present invention, the vane 134 integrally formed with the roller 133 is assembled so as to be slidable between the bushes 135 by the use of a roller or a vane separately manufactured from the cylinder in the conventional rotary compressor It is possible to eliminate the friction loss due to the sliding contact caused by being supported by the spring and to reduce the refrigerant leakage between the suction pocket S and the compression pocket D. [

Therefore, when the cylindrical rotors 131 and 132 receive the rotational force by the rotating magnetic field with the stator 120 (shown in Fig. 1), the cylindrical rotors 131 and 132 rotate. The rotating force of the cylindrical rotors 131 and 132 is transmitted to the roller 133 while the vane 134 is fitted in the vane mount 132H of the cylindrical rotors 131 and 132. At this time, ) Reciprocate linearly between the bushes (135). That is, the inner circumferential surfaces of the cylindrical rotors 131 and 132 have portions corresponding to each other on the outer circumferential surface of the roller 133. The portions corresponding to the cylindrical rotors 131 and 132 include cylindrical rotors 131 and 132, The suction pocket S is gradually enlarged while repeating the process of contacting and moving away from each other. As the suction pocket S gradually increases, the refrigerant or the working fluid is sucked into the suction pocket S and the compression pocket D gradually decreases, Compressed, and then discharged.

5 is a plan view showing an operation cycle of the compression mechanism in the example of the compressor according to the present invention.

(A), (b), (c), and (d) as the cylinder type rotors 131 and 132 and the roller 133 rotate as shown in FIG. 5 It shows one cycle in which the relative position changes. More specifically, when the cylindrical rotors 131 and 132 and the rollers 133 are positioned at (a), the refrigerant or the working fluid is sucked into the suction pocket S through the suction port 133a of the roller 133, Compression occurs in the discharged compressed pockets D partitioned by the vane S and the vanes 134. Even when the cylindrical rotors 131 and 132 and the roller 133 are rotated and arrive at the position b, the suction pocket S is extended and the compression pocket D is reduced while the refrigerant or the working fluid is sucked into the suction pocket S , And compression continues in the compressed pocket (D). When the cylindrical rotors 131 and 132 and the roller 133 arrive at the position (c) while rotating, they are continuously sucked into the suction pocket S and when the pressure of the refrigerant or the working fluid in the compressed pocket D becomes equal to or higher than the set pressure The refrigerant or working fluid is discharged through the discharge port of the upper bearing cover 136 (shown in Fig. 2) and the discharge valve 136A (shown in Fig. 2). (d), the suction and discharge of the refrigerant and the working fluid are almost completed.

FIG. 6 is a side cross-sectional view illustrating a refrigerant flow of the compressor according to the present invention, and FIG. 7 is an exploded perspective view illustrating a refrigerant suction path of the compressor according to the present invention.

1, 6, and 7, a high-pressure compressor according to an embodiment of the present invention will be described with reference to FIGS. 1, 6, and 7, And a discharge tube 114 through which the refrigerant can be discharged is provided on the upper portion of the sealed vessel 110. [

A vertical suction passage 141B is provided in an axial direction in an upper portion of the fixed shaft 141 and a vertical suction passage 141B is formed in the upper portion of the fixed shaft 141 to communicate with the vertical suction passage 141B, Shaped suction guide flow passages 142C and 133A are provided between the outer circumferential surface of the eccentric portion 142 and the inner circumferential surface of the roller 133 so as to communicate the horizontal suction passage 142B with the compression space, And a suction port 133a penetrating the roller 133 so as to communicate with the guide passages 142C and 133A. At this time, the horizontal suction passage 142B may be formed obliquely in the radial direction of the eccentric portion 142, or may be formed in various shapes and numbers. It is preferable that the suction guide flow paths 142C and 133A are formed only of a ring-shaped groove 142C formed along the center of the outer circumferential surface of the eccentric part 142 which is relatively thick and easy to machine, Shaped groove portion 133A formed along the center of the inner circumferential surface of the eccentric portion 142 and the grooved portion 133A of the roller 133 and the groove portion 142C of the eccentric portion 142 may be combined. The vertical suction passage 141B and the horizontal suction passage 142B and the suction guide passage 142C and 133A through which the refrigerant flows are connected to the oil supply passages 142A and 142B provided in the fixed shaft 141 and the eccentric portion 142, (141A, 142A). In addition, the suction port 133a of the roller 133 is preferably formed in the vicinity of the vane 134 so that suction can be continuously performed even if the roller 133 is rotated. Of course, since the roller 133 and the vane 134 move together, the suction port 133a of the roller 133 rotates together while maintaining the relative position with respect to the vane 134.

A discharge port and a discharge valve 136A are provided in the upper bearing cover 136 so as to communicate with the compression space and the inner space of the sealed container 110 for discharging the refrigerant and a muffler A discharge port 137h is provided in the hermetically sealed container 137 and a discharge pipe 114 is provided outside the upper surface of the sealed container 110 so as to communicate with the inner space of the hermetic container 110. [ At this time, the discharge port of the upper bearing cover 136 and the discharge valve 136A are preferably located close to the vane 134 so as to be partitioned by the suction port 133a of the roller 133 and the vane 134 Do. However, it is preferable that the discharge port 137h of the muffler 137 is located in a direction different from the discharge port of the upper bearing cover 136 and the discharge valve 136A. This is because the compressed refrigerant The discharge valve 136A provided in the discharge port of the upper bearing cover 136, as well as the flow noise of the high-pressure refrigerant, is discharged through the discharge port 136A of the upper bearing cover 136 and the muffler 137, Closing noise is reduced in the space between the upper bearing cover 136 and the muffler 137. Of course, since the upper bearing cover 136 moves along with the roller 133 and the vane 134, the discharge port of the upper bearing cover 136 and the discharge valve 136A are connected to the suction port 133a of the roller 133 and the vane 134 134 while keeping their relative positions the same.

The rotor 131, the muffler 137, the stationary shaft 142, and the oil separator 180 are disposed so as to be positioned directly above the muffler 131 in order to prevent the oil from being mixed with the compressed refrigerant, As shown in FIG. At this time, the oil separator 180 is provided with a plurality of holes 180h through which the oil separated refrigerant can escape into the space inside the closed container 110. The holes 180h are formed in the circumferential portion at regular intervals .

Accordingly, when the low-pressure refrigerant is sucked along the vertical suction passage 141B of the fixed shaft 141, the horizontal suction passage 142B of the eccentric portion 142, the suction guide between the eccentric portion 142 and the roller 133 (S shown in Fig. 4) of the compression space through the flow paths 142C, 133A and the suction port 133a of the roller 133. [ At this time, the eccentric portion 142 remains stopped, but the cylindrical rotors 131 and 132 and the upper and lower bearing covers 136 and 138 are rotated about the fixed shaft 141, and the vane integrated rollers 133 and 134 are rotated The refrigerant is compressed while the volume of the suction pocket (S: see FIG. 4) and the compression pocket (D: shown in FIG. 4) gradually change as described above because it rotates about the deep portion 142. 4), the discharge valve 136A provided in the upper bearing cover 136 is opened, and the compressed refrigerant is supplied to the upper bearing cover 136 ) Through the discharge port. At this time, the open / close noise of the discharge valve 136A and the flow noise of the high-pressure refrigerant are reduced in the space between the upper bearing cover 136 and the muffler 137, and the compressed refrigerant exits the discharge port 137h of the muffler 137 And then the oil is separated from the refrigerant while bumping against the oil separator 180. Thus, only the separated refrigerant is filled in the hermetically sealed container 110 through the holes 180h of the oil separator 180 and escapes through the discharge pipe 114 of the hermetically sealed container 110 to the outside.

In the foregoing, the present invention has been described in detail by way of examples on the basis of the embodiments of the present invention and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the content of the following claims.

1 is a side sectional perspective view showing an example of a compressor according to the present invention.

FIG. 2 is an exploded perspective view showing an example of a compressor according to the present invention. FIG.

3 is a side sectional view showing an example of a compressor according to the present invention.

4 is a plan view showing a vane mounting structure of a compressor according to the present invention.

5 is a plan view showing the operation cycle of the compression mechanism in the compressor according to the present invention.

6 is a side sectional view of a refrigerant flow of a compressor according to the present invention.

7 is an exploded perspective view illustrating a refrigerant suction path of the compressor according to the present invention.

Claims (14)

A sealed container in which a refrigerant is sucked and discharged; A stator fixed in the hermetically sealed container; A first fixing member including an upper end fixed to the hermetically sealed container so as not to move, an eccentric portion formed to be eccentric with respect to the fixed shaft, the fixed shaft extending long into the hermetically sealed container; A second fixing member formed to be spaced apart from a lower end of the first fixing member and installed so as not to move under the airtight container; A cylindrical rotor rotatable about a fixed axis by a rotating electromagnetic field from the stator, a rotating shaft rotatable about the eccentric portion while receiving rotation of the cylindrical rotor, and rotating about the eccentric portion to form a compression space with the cylindrical rotor And a vane for transmitting rotational force from the cylindrical rotor to the roller and dividing the compression space into a suction pocket for sucking the refrigerant and a compression pocket for compressing and discharging the refrigerant, and is rotatable while applying a load to the second fixing member A rotating member supported by the rotating member; And, And a refrigerant suction flow path provided on the upper portion of the fixed shaft and the eccentric portion and the roller so that the refrigerant is sucked into the compression space, The rotating member further comprises upper and lower bearing covers that form upper and lower portions of the compression space and rotate about the fixed shaft together with the cylindrical rotor, The lower bearing cover includes a lower shaft portion surrounding the fixed shaft and a lower cover portion coupled with the cylinder to form a lower portion of the compression space, Wherein at least one of the upper and lower bearing covers is fastened to the cylindrical rotor by a fastening member. delete The method according to claim 1, Wherein the lower shaft portion is formed so as to extend beyond the lower end of the fixed shaft and the end portion of the lower shaft portion is rotatably supported while applying a load of the rotary member to the second fixing member. The method of claim 3, The second fixing member includes a cylindrical bearing portion having a stepped portion therein, The lower end portion of the lower shaft portion is thrust-supported at the step of the second fixing member, And the outer surface of the lower shaft portion is journal-supported on the inner surface of the cylindrical bearing portion. delete A sealed container in which a refrigerant is sucked and discharged; A stator fixed in the hermetically sealed container; A first fixing member including an upper end fixed to the hermetically sealed container so as not to move, an eccentric portion formed to be eccentric with respect to the fixed shaft, the fixed shaft extending long into the hermetically sealed container; A second fixing member formed to be spaced apart from a lower end of the first fixing member and installed so as not to move under the airtight container; A cylindrical rotor rotatable about a fixed axis by a rotating electromagnetic field from the stator, a rotating shaft rotatable about the eccentric portion while receiving rotation of the cylindrical rotor, and rotating about the eccentric portion to form a compression space with the cylindrical rotor And a vane for transmitting rotational force from the cylindrical rotor to the roller and dividing the compression space into a suction pocket for sucking the refrigerant and a compression pocket for compressing and discharging the refrigerant, and is rotatable while applying a load to the second fixing member A rotating member supported by the rotating member; And, And a refrigerant suction flow path provided on the upper portion of the fixed shaft and the eccentric portion and the roller so that the refrigerant is sucked into the compression space, The refrigerant suction flow path includes a vertical suction flow passage vertically communicating with the upper portion of the fixed shaft and the central axis of the eccentric portion, a horizontal suction flow passage horizontally communicated along the radial direction of the eccentric portion so as to communicate with the vertical suction flow passage, Shaped suction guide passage formed between the eccentric portion and the roller and an inlet formed in the roller so as to communicate the suction guide passage and the compression space. The method according to claim 6, And a plurality of horizontal suction passages. The method according to claim 6, Wherein the suction guide passage is a groove portion formed along at least one of an outer circumferential surface of the eccentric portion and an inner circumferential surface of the corresponding roller. The method according to claim 6, Wherein the inlet of the roller is located proximate to the vane. A sealed container in which a refrigerant is sucked and discharged; A stator fixed in the hermetically sealed container; A first fixing member including an upper end fixed to the hermetically sealed container so as not to move, an eccentric portion formed to be eccentric with respect to the fixed shaft, the fixed shaft extending long into the hermetically sealed container; A second fixing member formed to be spaced apart from a lower end of the first fixing member and installed so as not to move under the airtight container; A cylindrical rotor rotatable about a fixed axis by a rotating electromagnetic field from the stator, a rotating shaft rotatable about the eccentric portion while receiving rotation of the cylindrical rotor, and rotating about the eccentric portion to form a compression space with the cylindrical rotor And a vane for transmitting rotational force from the cylindrical rotor to the roller and dividing the compression space into a suction pocket for sucking the refrigerant and a compression pocket for compressing and discharging the refrigerant, and is rotatable while applying a load to the second fixing member A rotating member supported by the rotating member; And, And a refrigerant suction flow path provided on the upper portion of the fixed shaft and the eccentric portion and the roller so that the refrigerant is sucked into the compression space, The cylindrical rotor further includes upper and lower bearing covers which form upper and lower portions of the compression space and rotate about the fixed shaft together with the cylindrical rotor, Wherein one of the upper and lower bearing covers is provided with a discharge port through which the compressed refrigerant is discharged from the compression space and a discharge valve which opens and closes the compressed refrigerant. 11. The method of claim 10, And the discharge port of the upper bearing cover is located close to the vane. 11. The method of claim 10, The rotating member further includes a muffler coupled in the axial direction of the upper bearing cover to reduce noise, Wherein the muffler is provided with a discharge port through which the refrigerant between the upper bearing cover and the muffler can escape. 11. The method of claim 10, Wherein the hermetically sealed container is provided with a discharge pipe for allowing the high-pressure refrigerant to escape to the outside. A sealed container in which a refrigerant is sucked and discharged; A stator fixed in the hermetically sealed container; A first fixing member including an upper end fixed to the hermetically sealed container so as not to move, an eccentric portion formed to be eccentric with respect to the fixed shaft, the fixed shaft extending long into the hermetically sealed container; A second fixing member formed to be spaced apart from a lower end of the first fixing member and installed so as not to move under the airtight container; A cylindrical rotor rotatable about a fixed axis by a rotating electromagnetic field from the stator, a rotating shaft rotatable about the eccentric portion while receiving rotation of the cylindrical rotor, and rotating about the eccentric portion to form a compression space with the cylindrical rotor And a vane for transmitting rotational force from the cylindrical rotor to the roller and dividing the compression space into a suction pocket for sucking the refrigerant and a compression pocket for compressing and discharging the refrigerant, and is rotatable while applying a load to the second fixing member A rotating member supported by the rotating member; And, And a refrigerant suction flow path provided on the upper portion of the fixed shaft and the eccentric portion and the roller so that the refrigerant is sucked into the compression space, And the eccentric portion protrudes in all radial directions of the fixed shaft.

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