KR20030034804A - A strucrure of deflected rotor bore center line for screw compressor - Google Patents

Abstract

PURPOSE: A screw compressor with a deflected central axis of a rotor is provided to allow a male screw rotor and a female screw rotor to work at optimum position. CONSTITUTION: A screw compressor comprises a male screw rotor(1) formed on a position deflected from an axis between a front bearing and a rear bearing to a direction opposite to a moving direction of circumferential load thereof; and a female screw rotor(2) formed on a position deflected from the axis between the front bearing and the rear bearing to a direction opposite to a moving direction of circumferential load thereof.

Description

Screw refrigerant compressor of deflected rotor bore center line for screw compressor

The present invention is a screw refrigerant compressor in which both bearings and rear bearings are formed at both ends of each of the rotors so that a male screw rotor and a female screw rotor are engaged with each other in the housing to compress the refrigerant gas and support the load of the respective rotors. The center line of the male screw rotor and the female screw rotor is formed at the position eccentrically with a certain tolerance in the axis between the bearing and the rear bearing to cancel the circumferential load of the rotor loaded on the bearing, It relates to the structure of the rotor of the screw refrigerant compressor configured to allow the male screw rotor and the female screw rotor to operate in the optimum position.

In a vapor compression refrigerator producing cold water, it is essential to install a screw refrigerant compressor that compresses the low pressure refrigerant gas evaporated to a high pressure to reuse the refrigerant gas. The screw refrigerant compressor has a male screw rotor connected to a motor inside the housing and a female screw rotor which is rotated in engagement with the male screw rotor in a horizontal direction across the suction part and the discharge part, thereby compressing the sucked refrigerant gas under high pressure and discharging it. At both ends of the male screw rotor and the female screw rotor, slide bearings and ball bearings supporting the loads of the respective rotors are formed.

The conventional screw refrigerant compressor has a structure in which a bearing for supporting the load of each rotor is directly connected to both ends of the center line of the male screw rotor and the female screw rotor for ease of assembly. As a result, the circumferential load is intensively loaded from the male screw rotor and the female screw rotor to the respective bearings during the actual load operation of the screw refrigerant compressor, thereby shortening the life of the respective bearings. There is a problem in that warpage of the male screw rotor and the female screw rotor occurs such that refrigerant gas is leaked and components of the refrigerant screw device are easily worn.

It is an object of the present invention that the center line of the male screw rotor and the female screw rotor is configured at an eccentric position at a constant tolerance in the axis between each of the all bearings and the rear bearings to offset the circumferential load of the rotor loaded on the bearings. The present invention provides a rotor structure of a screw refrigerant compressor configured to allow the male screw rotor and the female screw rotor to operate at an optimal position during actual load operation of the refrigerant compressor.

The male screw rotor and the female screw rotor generate a circumferential load that proceeds in a specific direction due to the rotor's own load and the engagement of the rotor during actual load operation, and the circumferential load is the amount of the male screw rotor and the female screw rotor. Maximized at the end.

Specifically, as shown in FIGS. 3 and 4, the circumferential load of the male screw rotor is in the lower right direction, and the circumferential load of the female screw rotor is in the upper right direction when viewed from all directions of the motor during actual load operation. Therefore, the male screw rotor and the female screw rotor are deflected with a certain tolerance in a direction opposite to the traveling direction of the circumferential load so as to cancel the circumferential load of the rotor proceeding in a specific direction as described above. That is, the center line of the male screw rotor is eccentrically formed in the upper left direction of the bearing axis, and the center line of the female screw rotor is formed eccentrically in the lower left direction of the bearing axis, thereby canceling the circumferential load applied to the bearing at the end of the rotor. have.

1 is a structural diagram of a screw refrigerant compressor

2 is a structural diagram of a suction unit housing of the present invention;

3 is an operation diagram of the circumferential load by the rotor

4 is an action diagram of a circumferential load loaded on a bearing

* Explanation of symbols for the main parts of the drawings

1: mail screw rotor

2: female screw rotor

3: all bearings (a, b)

4: rear bearing (a, b)

5: motor

6: axis of rotation

7: suction part

8: discharge part

11: rotor bore (a, b)

12: all bearing bore (a, b)

13: center bearing bore center (a, b)

14: rotor bore center point (a, b)

The screw refrigerant compressors of the present invention are all of the male screw rotors 1 which are formed at positions deflected from the axis between the bearing 3a and the rear bearing 4a in a direction opposite to the traveling direction of the circumferential load of the rotor 1, and all of them. The female screw rotor 2 is characterized in that it is formed at a position deflected from the axis between the bearing 3b and the rear bearing 4b in a direction opposite to the traveling direction of the circumferential load of the rotor 2.

The present invention will be described in detail with reference to the drawings and examples.

Figure 1 shows the structure of the screw refrigerant compressor, Figure 2 shows the structure of the inlet housing according to the present invention, Figure 3 shows the direction of action of the circumferential load by the rotor of the screw refrigerant compressor and Figure 4 The action direction of the circumferential load loaded on the bearing of the screw refrigerant compressor is shown.

As shown in FIGS. 3 and 4, when the rotating shaft 6 of the motor 5 is rotated clockwise when viewed from all directions of the motor 5, the male screw rotor 1 connected to the rotating shaft 6 is shown. Is rotated clockwise, and the female screw rotor 2 which meshes with the male screw rotor 1 is rotated counterclockwise. When the male screw rotor 1 is rotated in the clockwise direction, the male screw rotor 1 is rotated clockwise by the force MR1 and MR2 of the horizontal force MH1 and MH2 and the vertical force MV1 and MV2. The circumferential load of the screw rotor 1 runs in the lower right direction. When the female screw rotor 2 is rotated in a counterclockwise direction, the hydraulic force FH1 and FH2 in the horizontal direction of the female screw rotor 2 and the force FR1 and FR2 of the vertical force FV1 and FV2 are applied. As a result, the circumferential load of the female screw rotor 2 proceeds in the upper right direction.

As described above, the circumferential load of the male screw rotor 1 which proceeds in the lower-right direction is offset by the male screw rotor (3a) and the rear bearing 4a which support both ends of the male screw rotor 1. 1) is provided so as to be deflected by a certain tolerance in the upper left direction from the axis between the all bearing 3a and the rear bearing 4a. In addition, the female screw rotor 2 offsets the circumferential load of the female screw rotor 2 running in the upper-right direction so that all the bearings 3b and the rear bearing 4b supporting both ends of the female screw rotor 2 cancel each other. (2) is provided so as to be deflected by a certain tolerance in the lower left direction from the axis between the all bearing 3b and the rear bearing 4b.

Specifically, as shown in FIG. 2, in the suction part 7, all bearings 3a supporting one end of the male screw rotor 1 are formed at all bearing bore center points 12a of the bearing bore 12a. One end of the male screw rotor 1 is formed at the rotor bore center point 14a of the rotor bore 11a. Further, all bearings 3b for supporting one end of the female screw rotor 2 are formed at all bearing bore center points 12b of the all bearing bores 12b, and one end of the female screw rotor 2 is formed as a rotor bore. It is formed in the rotor bore center point 14b of (11b).

Also in the discharge part 8, in the structure similar to the said suction part 7, the rear bearing 4a which supports one end of the male screw rotor 1 is formed in the center of the rear bearing bore of the rear bearing bore, One end of the screw rotor 1 is formed at the center of the rotor bore of the rotor bore. Also, a rear bearing 4b supporting one end of the female screw rotor 2 is formed at the rear bearing bore center point of the rear bearing bore, and one end of the female screw rotor 2 is located at the rotor bore center point of the rotor bore. Form.

As described above, when both ends of the male screw rotor 1 and the female screw rotor 2 are installed at the center of the rotor bore of the rear rotor bore and the rear rotor bore, all the bearings 3a and 3b and the rear bearing 4a and 4b are installed. The center lines of the male screw rotor 1 and the female screw rotor 2 are positioned at positions deflected from the axis by a certain tolerance in the direction opposite to the direction of travel of the circumferential load.

As described above, all of the male screw rotor 1 and the female screw rotor 2 have a constant tolerance from the axis between the bearings 3a and 3b and the rear bearings 4a and 4b in the opposite direction to the traveling direction of the circumferential load. When formed in the deflected position by the circumference, the circumferential loads generated by the male screw rotor 1 and the female screw rotor 2 support both ends of the male screw rotor 1 and the female screw rotor 2, respectively. Since all of them are canceled in the bearings 3a and 3b and the rear bearings 4a and 4b, the loads applied to the all bearings 3a and 3b and the rear bearings 4a and 4b are minimized so that the bearings 3a, 3b and 4a, The rated life of 4b) is extended. In addition, due to the deflection of the rotors 1 and 2 during actual load operation, both the male screw rotor 1 and the female screw rotor 2 are connected to the axis between the bearings 3a and 3b and the rear bearings 4a and 4b. Since the male screw rotor (1) and the female screw rotor (2) are operated at an optimal position, they are substantially positioned, thereby minimizing the leakage of refrigerant gas and abrasion of parts and ensuring the efficiency and mechanical performance of the refrigerant compressor. Can be.

In the screw refrigerant compressor according to the present invention, the center lines of the male screw rotor and the female screw rotor are each eccentrically positioned at a constant tolerance in the axis between the bearing and the rear bearing to offset the circumferential load of the rotor loaded on the bearing. As the load on the bearing is minimized, the rated life is extended and the mail screw rotor and the female screw rotor are operated at the optimum position during actual load operation, so the leakage of refrigerant gas and the wear of parts are minimized, and the efficiency of the refrigerant compressor It is effective to secure mechanical performance.

Claims (1)

The male screw rotor (1) and the female screw rotor (2) connected to the motor (5) are engaged with each other in the housing to compress the refrigerant, and the circumferential load of the male screw rotor (1) and the female screw rotor (2) In the screw refrigerant compressor in which both bearings 3a and 3b and rear bearings 4a and 4b are formed at both ends of the rotors 1 and 2 so as to support the The male screw rotor 1 formed at a position which is deflected from the axis between the bearing 3a and the rear bearing 4a in a direction opposite to the traveling direction of the circumferential load of the rotor 1, and the bearing 3b and the rear bearing. The screw refrigerant of the structure in which the center line of the rotor is deflected, characterized in that a female screw rotor 2 is formed which is formed at a position deflected from the axis between 4b in a direction opposite to the traveling direction of the circumferential load of the rotor 2. compressor.