KR20120021573A - Compact rotary vane compressor for low rotation-resistance - Google Patents

Abstract

PURPOSE: A small rotary vane compressor is provided to prevent a continuous increase of frictional force by rotating a roller at a constant angle in case that the friction force against a vane is over a constant value after installing the rotatable roller with respect to an inner wall of a cylinder. CONSTITUTION: A small rotary vane compressor comprises a cylinder(30), a bearing(31), a roller(40), a non-eccentric shaft(50), a rotor(60), and a vane(61). A cylindrical compression space is formed inside the cylinder. The bearing is arranged to adjoin an inner wall of the cylinder. The roller is rotated by the bearing. The non-eccentric shaft is inserted at an eccentrical position from the center of the roller. The rotor is joined to the external diameter of the non-eccentric shaft and is in linear contact with part of the cylinder's inner wall. The vane goes in and out according to a contact pressure between the roller and the inner wall.

Description

Compact rotary vane compressor for low rotation-resistance

The present invention relates to a small rotary vane compressor with reduced rotational resistance, and more particularly, to a small rotary vane compressor with reduced rotational resistance due to friction of vanes and minimizing power consumption.

In general, a rotary compressor has a structure in which a roller is coupled to an eccentric rotary shaft, rotates in a cylinder, and compresses refrigerant or air by the eccentric roller.

When using the eccentric rotary shaft, vibration is generated by the rotation of the rotary shaft itself, and the generation of noise due to the vibration is intensified.

Vibration generated in the rotary compressor using the eccentric rotary shaft is also transmitted to the connection pipe connected to the rotary compressor, etc., can weaken the coupling of the connection pipe, this problem is more prominent in a small installation.

In addition, the noise caused by the noise pollution occurs when operating the refrigerant circulation circuit or compressor using the compressor due to the continuous noise.

In a large rotary compressor, various dust treatments may be performed to reduce such noise. However, in a small rotary compressor, especially a small rotary compressor manufactured to be portable, there is a problem that noise damage may be more concerned.

And the conventional small rotary compressor is relatively small in size, the vane is not easy to return due to the pressure of the oil involved in the protrusion of the vane, so that the friction between the vane and the cylinder inner wall increases, the increase of the friction of the motor Increasing the rolling resistance may cause a problem of high power consumption.

This increase in power consumption can easily predict problems such as shortening the driving distance by increasing the consumption of battery power, which is the power source of the electric vehicle, when applied to an electric vehicle cooling system, which is an application field where a small rotary compressor can be applied. Can be.

The problem to be solved by the present invention in view of the above problems is to provide a miniature rotary vane compressor that reduces the rotational resistance to minimize the occurrence of vibration and noise, and also reduce the frictional resistance during operation.

In addition, another object of the present invention is to provide a compact rotary vane compressor having reduced rotational resistance which can improve durability by minimizing wear of the rotor and vanes in contact with the inner surface of the cylinder.

In addition, another problem to be solved by the present invention is to provide a compact rotary vane compressor to reduce the rotational resistance is easy to manufacture, assembly and maintenance by simplifying the coupling structure.

In addition, another object of the present invention is to provide a compact rotary vane compressor having reduced rotational resistance that can facilitate heat dissipation of heat generated from the compressor and the motor according to the miniaturization and the motor-integrated structure.

In order to solve the above problems, the rotary vane compressor having reduced rotational resistance includes a cylinder providing a cylindrical compression space therein, a bearing positioned in contact with an inner wall surface of the cylinder, and rotating by the bearing. A cylindrical roller, an uneccentric shaft penetratingly inserted at a position eccentric from the center of the roller, a rotor fastened to an outer diameter of the non-eccentric shaft and linearly contacting a portion of the inner wall of the cylinder, and an outer diameter side of the rotor. And a vane inserted into and out of the roller according to the contact pressure with the inner wall of the roller.

As described above, the present invention has a roller which is rotatable with respect to the inner wall of the cylinder, and is fixed to the rotor of the non-eccentric shaft in the roller so as to be compressed while being in contact with the inner wall of the roller. When the frictional force becomes greater than a predetermined frictional force, the roller rotates at a predetermined angle, thereby preventing the continuous increase of the frictional force, thereby reducing power consumption.

In addition, the present invention is a non-eccentric rotary shaft is located through the position eccentric from the center of the cylinder, one or two or more vanes to the non-eccentric rotary shaft in the rotor of the garden ring, the vanes installed on the inner wall of the cylinder By rotating while in contact to cause compression, there is an effect that can reduce the vibration and noise.

As it is possible to proceed the compression stroke using the non-eccentric rotating shaft as described above, it is easier to maintain a stable fastening state of the connection pipe, it is possible to simplify the device and reduce the manufacturing cost without the need for a separate dustproof treatment It works.

In addition, the present invention reduces the wear resistance by reducing the rotational resistance of the vane, there is an effect that can prevent the shortening of life.

In addition, the present invention can easily dissipate heat generated during operation of the compressor by placing a heat dissipation fin on the outside of the case, and the pin for supplying power to the motor can be combined with the case and bolt the case made of aluminum In combination with the structure, the compressor can be easily maintained and repaired.

1 is a partial plan view of a rotary vane compressor having a reduced rolling resistance according to a preferred embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along AA in FIG. 1.
3 is a partial cross-sectional view of a rotary vane compressor having reduced rotational resistance according to a preferred embodiment of the present invention including a supply line of a fluid.
4 is an exploded perspective view of a rotary vane compressor having a reduced rolling resistance according to an exemplary embodiment of the present invention.
FIG. 5 is a cross-sectional view of the coupled state of FIG. 4.

Hereinafter, various embodiments of the rotary vane compressor having reduced rotational resistance of the present invention configured as described above will be described in detail with reference to the accompanying drawings.

FIG. 1 is a partial plan view of a rotary vane compressor having reduced rotational resistance according to a preferred embodiment of the present invention, and FIG. 2 is a cross-sectional view of AA in FIG. 1. 3 is a partial cross-sectional view of a rotary vane compressor having reduced rotational resistance according to a preferred embodiment of the present invention including a supply line of a fluid.

1 to 3, the rotary vane compressor with reduced rotational resistance according to the preferred embodiment of the present invention is provided in contact with the cylinder 30 and the inner wall of the cylinder 30 to provide a cylindrical compression space. A bearing 31, a cylindrical roller 40 rotatable along the inner wall of the cylinder 30 by the bearing 31, and a vertically penetrating installation at an eccentric position from the center of the compression space of the cylinder 30; Rotor 60 is fastened to the non-eccentric shaft 50, the outer surface of the non-eccentric shaft 50 is rotated in accordance with the rotation of the non-eccentric shaft 50, and in line contact with a portion of the roller 40 And a vane 61 inserted into and out of the vane insertion groove 62 provided in the rotor 60 so as to contact the end of the roller 40 to compress the fluid supplied into the roller 40. It is configured to include.

Hereinafter, the configuration of the rotary vane compressor with reduced rotational resistance according to a preferred embodiment of the present invention configured as described above will be described in more detail.

First, the cylinder 30 is a structure having an inner space of a garden shape in plan view, and the inner space is defined as a cylindrical shape by the lower bearing and the upper bearing described later. In addition, unlike the conventional compressor cylinder, the cylinder 30 communicates with the bottom surface of the cylinder 30 without the inflow hole 32 through which the fluid compressed from the side flows into the cylinder 30. It has a shape for supplying a fluid to the bottom surface by the connecting hole 33.

The connection hole communicates with the fluid supply passage 21 provided in the lower bearing 20, and the fluid is supplied to the inside of the roller 40 through the fluid supply passage 21.

As will be described in more detail later, the fluid supply bypassing the roller 40 because the fluid can not be directly supplied to the compression space that is the space between the roller 40 and the rotor 60 by the installation of the rotating roller 40 Provide the path.

The bearing 31 is located on the entire inner wall of the cylinder 30. At this time, it is preferable that the bearing 31 uses a needle bearing.

The roller 40 has a cylindrical structure, and the outside fluid is introduced into the inside, and the vane 61 rotating together with the rotor 60 is contacted so that the fluid introduced therein is compressed, and there is a space to be discharged. to provide.

In addition, when the vane 61 is introduced into the rotor 60, the contact pressure with the rotor 60 is increased, and together with the bearing 31 along the rotational direction of the rotor 60 is predetermined It is possible to reduce the rotational resistance which is the contact pressure with the vane 61 while rotating angularly.

The non-eccentric shaft 50 for rotating the rotor 60 is a hollow tubular shape, and also serves as a supply line of oil to be described in more detail later. The non-eccentric shaft 50 may support the rotor 60 in an uneccentric state or may be provided integrally with the rotor 60, and may not be located at the center of the roller 40 to compress the fluid. The inner diameter surface of the roller 40 and the outer diameter surface of the rotor 60 are in line contact with each other.

By using the non-eccentric shaft 50 and the rotor 60 in this way, noise and vibration can be reduced, as described above, when the contact pressure between the vane 61 and the roller 40 increases during rotation, the roller It is possible to prevent the increase in the amount of power used by reducing the rotational resistance by rotating the 40 together.

4 is an exploded perspective view of a rotary vane compressor having a reduced rolling resistance according to an exemplary embodiment of the present invention, and FIG. 5 is a cross-sectional configuration diagram of the coupled state of FIG. 4.

4 and 5, the rotary vane compressor with reduced rotational resistance according to a preferred embodiment of the present invention, provides a cylindrical inner space of the lower portion is sealed and stores the oil, the fluid supply portion 11 on the side The coupling hole 12 to which the coupling is provided is provided, the lower case 10 having the heat dissipation fins 13 protruded from the outside, and inserted into the lower case 10, and the fluid supply passage 21 is provided. And a lower bearing 20 having an insertion hole 22 into which one end of the uneccentric shaft 50 is inserted in the center, and inserted into the lower case 10 so as to be in contact with an upper portion of the lower bearing 20. A cylinder 30 having an inlet hole 32 communicating with the fastening hole 12 of the lower case 10 and including a connection pipe 33 connected to the fluid supply path 21, The bearing 31 which is installed in close contact with the inner diameter surface of the cylinder 30 and the inner diameter surface of the bearing 31 are in contact with each other. A roller 40 defining a compression space at an inner side thereof, and a rotor 60 linearly contacting an inner surface of the roller 40 at an outer side thereof, and having a plurality of oil supply holes 64 at an outer side thereof. The oil is supplied by pumping oil located between the lower case 10 and the lower bearing 20 when the shaft 50 and the non-eccentric shaft 50 are rotated to be inserted into the shaft 50 and the non-eccentric shaft 50. An oil propeller (63) discharged through the ball (64) and a through hole (73) through which the other side of the non-eccentric shaft (50) penetrates are provided, and a bearing (31) and a roller (40) in the cylinder (30). And an upper bearing 70 which seals the upper surface of the cylinder 30 in a state where the rotor 60 including the vanes 61 is retracted, and has a discharge hole, and is compressed in the roller 40. A discharge valve 71 and a discharge retainer 72 for opening and closing the discharge hole according to the pressure of the fluid, and an upper portion of the upper bearing 70. A motor 80 including a stator 82 and a rotor 81 coupled to the uneccentric shaft 50, which rotates the uneccentric shaft 50, and a discharge port 92 of the compressed fluid. ) Is provided, and is coupled to the lower case 10 to seal the structures and to the upper case 90 having the heat dissipation fin 93 protruding from the outside, and fastened to an upper end of the upper case 90. An upper cap 91 including an electrode 94 for supplying power to the motor 80 is included.

Hereinafter, the overall structure of the rotary vane compressor having reduced rotational resistance according to a preferred embodiment of the present invention configured as described above will be described in more detail.

First, the lower case 10 is provided with a fastening hole 12 on the side, a cylindrical space is provided inside. In addition, the heat dissipation fins 13 and 93 are provided on the surfaces of the lower case 10 and the upper case 90 to facilitate heat dissipation.

The fastening hole 12 may be screwed to the fluid supply unit 11 to which a line such as metal is fastened from the outside, and may include a sealing member such as an O-ring to prevent leakage. This coupling method is easier to connect the equipment than the existing method of connecting the external line by welding, and also easy to separate and easy maintenance.

The bottom surface of the lower case 10 reduces the wear of the compressor and is filled with oil to help heat dissipation, the oil is along the oil propeller 63 is inserted into the hollow non-eccentric shaft 50 After being supplied to the inside of the eccentric shaft 50, it is discharged to the outside of the non-eccentric shaft 50 through the oil supply hole 64 of the side.

The oil discharged as described above is supplied to the vane insertion groove 62 to push out the vanes 61 inserted into the vane insertion groove 62 to the outside.

The lower bearing 10 is inserted into the lower bearing 21 provided with the fluid supply passage 21, and the cylinder 30 is inserted into the upper case. At this time, the inlet hole 32 of the cylinder 30 receives the fluid supplied through the fluid supply unit 11 coupled to the fastening hole 12 of the lower case 10, the connection pipe 33 and the fluid supply The fluid supplied through the furnace 21 can be supplied into the compression space defined by the roller 40.

Bearing 31 is located between the cylinder 30 and the roller 40, the roller 40 is configured to rotate or stop in accordance with the contact pressure between the vane 61 and the roller 40.

The fluid thus supplied is compressed by the rotor 60 rotating together with the vanes 61 protruding by the oil. The rotor 60 is coupled to a part of the non-eccentric shaft 50 and rotates, and compresses the fluid by changing the volume of the space where the ends of the vanes 61 and the inner surface of the roller 40 contact.

In this case, since the pressure acts in the direction in which the vane 61 protrudes by the oil as described above, the vane 61 may not be easily drawn in the compression process, and the rollers 40 rotate together by a predetermined angle. To reduce the frictional force.

The compressed fluid as described above is discharged through the discharge hole provided to the upper side of the upper bearing (70). At this time, in order to adjust the pressure of the compressed fluid, the upper surface of the discharge hole is covered with a plate-shaped discharge valve 71 and the discharge retainer 72.

The plate-shaped discharge retainer 72 and the discharge valve 71 are kept closed when the pressure of the fluid is less than a certain pressure to allow the fluid to be compressed, the upper side when the pressure of the fluid reaches a certain pressure To open the discharge hole so that the compressed fluid is discharged.

The compressed fluid discharged as described above moves along the gap of the stator 82 and is discharged through the discharge port 92 of the upper case 90.

The upper surface of the upper case 90 is provided with a fastening hole, the upper cap 91 is coupled to the fastening hole. The upper cap 91 is inserted with a plurality of electrodes 94 insulated from the upper cap, it is possible to supply power to the motor 80 through the electrode 94.

Without using the upper cap 91, it is possible to install an electrode insulated in the upper case 90, but the operation is not easy, it may not be easy to check and maintain when the power supply abnormality.

The upper case 90 is provided with a heat dissipation fin 93, it can be easily released heat generated from the motor 80 and the like along with the heat dissipation fin 13 of the lower case (10). In addition, the upper case 90 and the lower case 10 may be fastened with each other by bolts without being welded, thus facilitating coupling and maintenance.

In addition, although the upper case 90 and the lower case 10 are conventionally used by welding, this may not only be easy to maintain, but may also cause a problem that the motor is damaged by heat generated during welding.

In this way, the present invention can be produced in a compact to compress the fluid of 10cc or less by using the non-eccentric shaft 50, reducing vibration and noise, simplifying the coupling structure, such as a personal cooling device, a small refrigerator, a small air conditioner It can be utilized in portable cooling equipment that requires weight reduction.

In addition, the inner wall side of the cylinder in contact with the vane is configured to rotate above a predetermined friction force, it is possible to reduce the power consumption by reducing the rotational load of the motor rotating by the battery.

It will be apparent to those skilled in the art that the present invention is not limited to the above embodiments and can be practiced in various ways without departing from the technical scope of the present invention. will be.

10: lower case 11: fluid supply unit
12: Fastener 13: Heat radiation fin
20: lower bearing 21: rapeseed supply passage
22: insertion hole 30: cylinder
31: bearing 32: inflow ball
33: connector 40: roller
50: uneccentric shaft 60: rotor
61: vane 62: vane insertion groove
63: oil propeller 70: upper bearing
80: motor 90: upper case

Claims (5)

A cylinder providing a cylindrical compression space therein;
A bearing positioned in contact with an inner wall surface of the cylinder;
A cylindrical roller rotating by the bearing;
An uneccentric shaft penetrated into a position eccentric from the center of the roller;
A rotor fastened to an outer diameter of the uneccentric shaft and linearly contacting a portion of an inner wall of the cylinder; And
Small rotary vane compressor is inserted into the outer diameter side of the rotor, reducing the rolling resistance including a vane entering and exiting in accordance with the contact pressure with the inner wall of the roller.
The method of claim 1,
Lower and upper bearings are fastened to the lower and upper parts of the cylinder and the roller, respectively, to maintain the airtightness of the lower and upper parts.
Compact rotary vane compressor with reduced rolling resistance, characterized in that the fluid to be compressed is supplied to the inner portion of the roller through a fluid supply path provided in the lower bearing.
The method of claim 2,
The vane is inserted into the vane insertion groove provided in the rotor,
A small rotary vane compressor having a reduced rolling resistance, characterized in that the pressure is applied to the outside by the lubricating oil supplied to the inside of the non-eccentric shaft to contact the inner wall of the roller.
The method of claim 1,
The non-eccentric shaft,
The small size is reduced by the rotation resistance is inserted into the inside of the case divided into the upper case and the lower case is fastened to the rotor of the stator and the rotor coupling structure to generate a rotational driving force supplied with the DC power of the battery Rotary vane compressor.
The method of claim 4, wherein
Small rotary vane compressor to reduce the rolling resistance, characterized in that a plurality of heat radiation fins are provided on the outer surface of the upper case and the lower case.

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