KR100590493B1 - The compressing apparatus of orbiter compressor - Google Patents

Abstract

The present invention relates to a swing vane compressor, and more particularly, to allow the suction of gas through the lateral suction port formed in the cylinder of the compressor to be more flexibly introduced into the inner compression chamber side of the circular vane, the discharge pressure and the suction pressure It is a compression device of a swing vane compressor that can eliminate the axial close contact between the slider and the circular vane due to the pressure difference of the circular vane, the circular operating space of which one side is disconnected by the closing part in the cylinder It is formed, the one side end and the other end of the working space is formed with a lateral suction port and the inner and outer discharge port, one side end of the circular vane inserted into the working space is shorter than the working space of the suction port side A suction flow path is formed between the vane and the working space, and the other end of the circular vane is pressurized by the airtight means. By configured to be a seal between the chamber there is an effect that can talk to improve the reliability of the compression efficiency and the device.

Closed part, working space, slider, spring, gas discharge hole, round vane, cylinder

Description

The compressing apparatus of orbiter compressor

1 is a longitudinal cross-sectional view showing the overall configuration of a typical swing vane compressor.

Figure 2 is an exploded perspective view showing the compression device of Figure 1;

3 is an operating state diagram showing the compression process of FIG.

4 is a plan sectional view showing a first embodiment of the present invention.

5 is a plan sectional view showing a second embodiment of the present invention;

6 is a plan sectional view showing a third embodiment of the present invention.

7 is a plan sectional view showing a fourth embodiment of the present invention.

8 is a plan sectional view showing a fifth embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

110: operating space 110a: closed

120: suction passage 130: airtight means

131: sliding surface 132: arc-shaped slider

133: linear slider 133a: slide guide surface

134: gas discharge hole 135: spring

The present invention relates to a swing vane compressor, and more particularly, to allow the suction of gas through the lateral suction port formed in the cylinder of the compressor to be more flexibly introduced into the inner compression chamber side of the circular vane, the discharge pressure and the suction pressure The present invention relates to a compression device of a swing vane compressor capable of eliminating partial close contact between a slider and a circular vane due to a pressure difference of and a friction loss.

In general, the swing vane compressor is configured such that the inner and outer compression chambers are formed inside the cylinder by the swinging movement of the vanes. FIG. 1 is a low pressure type proposed by the present inventors to be applicable as a sealed refrigerant compressor such as a refrigerator or an air conditioner. Hermetic swing vane compressor.

In the low pressure swing vane compressor, the driving unit (D) and the compression unit (P) form a sealed shape in one shell (1), and the driving unit (D) and the compression unit (P) have upper and lower ends. Interconnected by a vertical crankshaft 8 rotatably supported by the mainframe 6 and the subframe 7 so that the power of the drive unit D through the crankshaft 8 to the compression unit P side. It is configured to be delivered.

The driving unit D includes a stator 2 fixed between the main frame 6 and the subframe 7, and a crank shaft vertically penetrated by an applied power provided inside the stator 2. Rotor (3) for rotating (8), the balance weight (3a) is formed symmetrically with each other in the upper and lower parts of the rotor 3, the rotational imbalance of the crank shaft (8) by the crank pin 81 It is supposed to prevent.

The compression portion P is the inside of the cylinder (4) by the swing vane 5, the lower side of the boss 55 is coupled to the crank pin 81 to the pivoting motion inside the cylinder (4) It is configured to compress the introduced refrigerant gas, the cylinder (4) includes an inner ring (41) protruding to the lower side, the turning vane (5) is such that the circular vanes (51) protrude vertically on the upper side It is formed to make a pivoting movement in the annular space 42 formed between the inner ring 41 and the inner wall of the cylinder (4), the inner and outer center around the circular vanes (51) by the pivoting movement A compression chamber is formed in the compression chamber, and the refrigerant gas compressed in the compression chamber is configured to be discharged to the outside of the cylinder 4 through the inner and outer discharge ports 44 and 44a of the upper cylinder 4. .

In addition, an old dam ring (9), which is a rotation preventing mechanism, is provided between the main frame (6) and the turning vane (5), and the oil passage (82) is formed to penetrate up and down inside the crank shaft (8). The oil supply to the compression unit (P) is made by the operation of the oil pump 83 installed on the lower end of the crankshaft (8).

In the swing vane compressor of the present invention, the refrigerant gas compressed by the compression unit P is discharged to the upper high pressure chamber 12 through the inner and outer discharge ports 44 and 44a of the cylinder 4. As a low pressure swing vane compressor, a discharge tube (13) is installed in the high pressure chamber (12) through a shell (1), and a lower side of the discharge tube (13), that is, at one side of the main frame (6). The suction tube 11 is installed through the shell 1.

According to the present invention configured as described above, first, the rotor 3 of the driving unit D is rotated by an applied power source so that the crankshaft 8 is rotated, and the crank of the crankshaft 8 is rotated by the rotation of the crankshaft 8. The turning vane 5 of the compression part P, in which the lower side boss 55 is eccentrically coupled to the pin 81, is pivoted along the rotation radius.

Accordingly, the circular vanes 51 of the swing vanes 5 inserted into the annular space 42 between the inner wall of the cylinder 4 and the inner ring 41 also pivot together and the inside of the annular space 42. Compressed refrigerant gas is compressed to the inside of the annular space (42), the inner and outer compression chambers are respectively formed around the circular vanes (51), the compressed refrigerant gas is in communication with the respective compression chambers The inner and outer discharge ports 44 and 44a of the cylinder 4 are discharged to the upper high pressure chamber 12 so that the high-temperature and high-pressure refrigerant gas is discharged through the discharge tube 13.

2 is an exploded perspective view illustrating the compression unit of FIG. 1.

As shown in the drawing, the compression unit P includes a pivot vane 5 coupled to the crank shaft 8 at an upper end of the main frame 6 rotatably supporting the upper side of the crank shaft 8. And a cylinder 4 coupled to the main frame 6 on an upper side of the swing vane 5, and the cylinder 4 has a suction port 43 formed in a lateral direction, and the suction port 43 Inner and outer discharge ports 44 and 44a are formed on the upper surface of the other side cylinder 4 of FIG.

 In addition, the circular vane 51 of the upper side of the swing vane 5 allows the refrigerant gas sucked through the suction port 43 of the cylinder 4 to be sucked into the circular vane 51. The through hole 52 is formed to be open to the upper side and the slider 54 side of the 51, the slider 54 is mounted in the opening 53 of the circular vane 51 to the low pressure and high pressure side Function to distinguish confidentially.

Here, reference numeral 9 is an Oldham ring.

3 is an operating state diagram showing the compression process of FIG.

As shown in the present invention, when the turning vane 5 of the compression unit P is driven by receiving power from the driving unit D through the crankshaft 8 (see FIG. 1), the cylinder 4 The circular vanes 51 of the turning vanes 5 inserted into the annular space 42 rotate in the annular space 42 formed between the inner wall of the cylinder 4 and the inner ring 41 as shown by the arrow. While compressing the refrigerant gas sucked into the interior of the annular space 42 through the suction port 43.

That is, the initial operating state (0 °) is the suction of the refrigerant gas into the inside of the inner suction chamber (A1) through the through hole 52 of the suction port 43 and the circular vane 51, the circular vane Compression starts in the state in which the outer compression chamber B2 is blocked from the inlet 43 and the outer discharge port 44a, and the inner compression chamber A2 simultaneously compresses and discharges the refrigerant gas.

In the 90 ° rotated state, the compression of the outer compression chamber B2 of the circular vane is continuously in progress, and the inner compression chamber A2 of the circular vane is almost completely discharged from the compressed refrigerant gas through the inner discharge port 44. Then, the outer suction chamber (B1) that did not exist in the previous step is generated and the suction of the refrigerant gas through the suction port 43.

In the rotated state by 180 °, the inner suction chamber A1 existing in the previous step disappears, and instead, the inner suction chamber A1 becomes the inner compression chamber A2 and starts compression. B2) communicates with the outer discharge port 44a, and the discharge of the compressed refrigerant gas proceeds.

In the state of rotating 270 °, the outer compression chamber B2 of the circular vane almost completely discharges the compressed refrigerant gas through the outer discharge port 44a, and the inner compression chamber A2 continues to compress the outer surface. Compression to the suction chamber (B1) is started, and when rotated further 90 degrees in the above state, the outer suction chamber (B1) that existed in the previous step becomes the outer compression chamber (B2) to the outer compression chamber (B2). By returning to the initial state while the compression is performed, the cycle based on one rotation of the crankshaft is continuously repeated.

However, the conventional swing vane compressor has a structure in which the refrigerant gas is sucked in the lateral direction of the cylinder, and it is difficult to suck the refrigerant gas toward the inner compression chamber of the circular vane, which causes suction loss and additionally overcomes it. There was a problem that the processing of the compression unit is required.

In addition, due to the pressure difference between the suction pressure and the discharge pressure, there is a problem in that the compression efficiency and the reliability of the device are reduced due to the frictional loss caused by the slider being closely adhered to the tip of the suction-side circular vane.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, the object is to allow the intake of gas through the suction port formed in the cylinder to be more flexibly introduced into the inner compression chamber side of the circular vane, discharge It is to eliminate the partial adhesion between the slider and the circular vane due to the pressure difference between the pressure and the suction pressure and the friction loss.

In order to achieve the object of the present invention, a rotary vane compressor in which a compression chamber is formed inside and outside of a circular vane inside a cylinder by a pivoting motion of the swing vane. A circular working space is formed in which one side is disconnected, and an inlet and an inner and outer discharge ports are formed at one end and the other end of the working space, and one end of the circular vane inserted into the working space is smaller than the working space at the suction port side. The suction vane is formed between the circular vane and the working space by shortening the length, and the other end of the circular vane is configured to seal between the inner and outer compression chambers by an airtight means. An apparatus is provided.

In addition, the airtight means is characterized in that the end of the circular vanes along the trajectory of the sliding surface to form a sliding surface forming a trajectory on the inner wall of the closed portion.

In addition, the airtight means allows one side of the slider to contact the circular vane end on the discharge port side, and the slider allows the discharge pressure to be acted upon by the gas discharge hole formed in the other working space to seal between the slider and the end of the circular vane. Characterized in that configured to be made.

In addition, the airtight means has one side of the slider in contact with the circular vane end of the discharge port side, the slider is elastically supported to the circular vane side by the spring provided in the other operating space between the end of the circular vane and the slider Characterized in that configured to be sealed in.

In addition, the slider is characterized in that the arc-shaped slider.

In addition, the slider is characterized in that the linear slider to perform a linear movement along a pair of slide guide surface formed in parallel to the inner wall of the working space on the discharge port side.

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

4 is a plan sectional view showing a first embodiment of the present invention.

In general, the swing vane compressor is configured to form an inner and an outer compression chamber inside the cylinder by rotating the vane of the swing vane, which receives power from the driving device through the crankshaft, by turning the cylinder.

In this swing vane compressor, the present invention forms an operating space 110 of the circular vane 140 in the interior of the cylinder 4, the one side is disconnected by the closing portion (110a) the operating space 110 It is formed to form a circle, and the lateral suction port 43 and the inner and outer discharge ports 44, 44a are formed at one end and the other end of the working space 110, respectively.

In addition, the circular vane 140 shortens the length of the end of the suction port 43 to the working space 110 so that the suction passage 120 is between the end of the shortened circular vane 140 and the working space 110. ), And the end portion of the discharge port side is configured to seal between the inner and outer compression chambers A2 and B2 by the airtight means 130.

In the airtight means 130, a sliding surface 131 is formed at the closing portion 110a such that an end of the discharge opening side circular vane is in sliding contact with the inside of the discharge opening side closing portion 110a, and the sliding surface 131 is formed. ) Is formed as a curved surface forming a turning trajectory so that interference does not occur in the turning movement of the circular vane 140.

According to the present invention configured as described above, the suction passage 120 is secured between the end of the inlet side circular vane 140 and the working space 110 so that the refrigerant to the inner compression chamber A1 in the compressor having a lateral suction structure. The inhalation of the gas is made flexible so that the intake loss can be minimized.

In addition, the inlet 43 and the inner and outer discharge ports 44 and 44a are blocked by the closing part 110a, and there is no slider interposed between the openings of the circular vanes 140. Due to the pressure difference of the pressure, there is also an advantage that the pressure loss can be eliminated as the slider is in close contact with the end side of the inlet side circular vane 140.

5 is a plan sectional view showing a second embodiment of the present invention.

As shown in the present invention, as in the first embodiment of the present invention, the working space 110 is formed in a circular shape in which one side is cut off by the closing portion 110a, and one side end and the other side of the working space 110 are formed. Lateral suction ports 43 and inner and outer discharge ports 44 and 44a are formed at ends, respectively.

In addition, the circular vane 140 shortens the length of the end of the suction port side to the working space 110 to form the suction passage 120 between the end of the shortened circular vane 140 and the working space 110. The end portion of the discharge port side is configured to seal between the inner and outer compression chambers A2 and B2 by the airtight means 130.

The airtight means 130 is provided with one side of the arc-shaped slider 132 in contact with the end of the circular vane 140 of the discharge port side, the other side of the arc-shaped slider 132 gas in communication with the working space 110 The arc-shaped slider 132 is in close contact with the end side of the discharge port-side circular vane 140 by the discharge pressure 134 formed by the discharge pressure introduced into the working space 110 through the gas discharge hole 134. It is configured to seal between the inner and outer compression chambers A2 and B2.

6 is a plan sectional view showing a third embodiment of the present invention.

As shown in the present invention, as in the first embodiment of the present invention, the working space 110 is formed in a circular shape in which one side is cut off by the closing portion 110a, and one side end and the other side of the working space 110 are formed. Lateral suction ports 43 and inner and outer discharge ports 44 and 44a are formed at ends, respectively.

In addition, the circular vane 140 has a suction end 120 formed between the end of the shortened circular vane 140 and the working space 110 by making the end of the suction port side shorter than the working space 110. The end portion of the discharge port side is configured to seal between the inner and outer compression chambers A2 and B2 by the airtight means 130.

The airtight means 130 is provided with one side of the arc-shaped slider 132 in contact with the end portion of the circular vane 140 of the discharge port side, the other side of the arc-shaped slider 132 is always circular arc By mounting a spring 135 to elastically support the vane 140 side by the elastic force of the spring 135, the arc-shaped slider 132 is in close contact with the end side of the discharge port side circular vane 140 to compress the inner and outer It is comprised so that sealing between threads A2 and B2 may be performed.

7 is a plan sectional view showing a fourth embodiment of the present invention.

As shown in the present invention, as in the first embodiment of the present invention, the working space 110 is formed in a circular shape in which one side is cut off by the closing portion 110a, and one side end and the other side of the working space 110 are formed. Lateral suction ports 43 and inner and outer discharge ports 44 and 44a are formed at ends, respectively.

In addition, the circular vane 140 has a suction end 120 formed between the end of the shortened circular vane 140 and the working space 110 by making the end of the suction port side shorter than the working space 110. The end portion of the discharge port side is configured to seal between the inner and outer compression chambers A2 and B2 by the airtight means 130.

The airtight means 130 forms a pair of slide guide surfaces 133a parallel to each other on the inner wall of the cylinder 4 of the discharge port side working space 110, and one side of the discharge guide side circular vanes on the slide guide surface 133a. A linear slider 133 in contact with an end of the 140, and a gas discharge hole 134 communicating with the working space 110 in the cylinder 4 between the linear slider 133 and the working space 110. Is formed so that the linear slider 133 is in close contact with the end side of the discharge port side circular vane 140 by the discharge pressure through the gas discharge hole 134, so that the inner and outer compression chambers A2 and B2 are separated. It is configured to seal.

8 is a plan sectional view showing a fifth embodiment of the present invention.

As shown in the present invention, as in the first embodiment of the present invention, the working space 110 is formed in a circular shape in which one side is cut off by the closing portion 110a, and one side end and the other side of the working space 110 are formed. Lateral suction ports 43 and inner and outer discharge ports 44 and 44a are formed at ends, respectively.

In addition, the circular vane 140 has a suction end 120 formed between the end of the shortened circular vane 140 and the working space 110 by making the end of the suction port side shorter than the working space 110. The end portion of the discharge port side is configured to seal between the inner and outer compression chambers A2 and B2 by the airtight means 130.

The airtight means 130 forms a pair of slide guide surfaces 133a parallel to each other on the inner wall of the cylinder 4 of the discharge port side working space 110, and one side of the discharge guide side circular vanes on the slide guide surface 133a. A spring having a linear slider 133 in contact with the end of the 140, the spring to elastically support the linear slider 133 toward the circular vane 140 at the inside of the other operating space 110 of the linear slider 133 ( 135 so that the linear slider 133 is in close contact with the end side of the discharge port side circular vane 140 by the elastic force of the spring 135 to seal between the inner and outer compression chambers A2 and B2. It is made up.

As described above, the present invention allows the suction of gas through the lateral suction port formed in the cylinder to be more flexibly introduced into the inner compression chamber side of the circular vane, and between the slider and the circular vane due to the pressure difference between the discharge pressure and the suction pressure. It is possible to improve the compression efficiency and the reliability of the device by eliminating partial adhesion and thus frictional losses.

Claims (6)

In a swing vane compressor in which a compression chamber is formed inside and outside of a circular vane inside a cylinder by swinging swing vanes. Inside the cylinder, a circular working space in which one side is cut off by a closing part is formed, and inlet and inner and outer discharge ports are formed at one end and the other end of the working space, and a circular vane inserted into the working space. One end of the suction port is shorter than the working space on the inlet side to form a suction flow path between the circular vane and the working space, and the other end of the circular vane may be sealed between the inner and outer compression chambers by an airtight means. Compressor of the swing vane compressor, characterized in that configured. The method of claim 1, The airtight means has a sliding surface forming a trajectory on the inner wall of the closing portion of the compression vane compressor, characterized in that configured to contact the end of the circular vanes along the trajectory of the sliding surface. The method of claim 1, The airtight means allows one side of the slider to come into contact with the circular vane end of the discharge port side, and the slider may be sealed between the slider and the end of the circular vane by causing the discharge pressure to be applied by a gas discharge hole formed in the other working space. Compressor of the swing vane compressor, characterized in that configured to. The method of claim 1, The airtight means allows one side of the slider to come into contact with the circular vane end on the discharge port side, and the slider is elastically supported to the circular vane side by a spring provided in the other working space to seal between the end of the circular vane and the slider. Compressor of the swing vane compressor, characterized in that configured to be made. The method according to any one of claims 1 to 4, The slider is a compression device of the swing vane compressor, characterized in that the arc-shaped slider. The method according to any one of claims 1 to 4, And the slider is a linear slider which linearly moves along a pair of slide guide surfaces formed parallel to each other on the inner wall of the working space on the discharge port side.

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