JPH0733826B2 - Scroll compressor - Google Patents

Description

TECHNICAL FIELD The present invention relates to a fluid compressor, and more particularly to a scroll compressor.

<Prior Art> Two scroll members of two scroll members each having a scroll member fixed on a side plate are superposed so as to be engaged with each other while shifting an angle, and a fluid pocket formed between both scroll members is formed. U.S. Pat. Nos. 3,884,599, 3,924,977 and Japanese Patent Publication No. 3,924,977 are disclosed in which a scroll compressor is moved toward the center and its volume is reduced by the relative circular orbital motion of the scroll member to compress the fluid. An improved scroll compressor structure is proposed in Japanese Patent Laid-Open No. 58-1278, Japanese Utility Model Publication No. 60-12956, and the like.

However, it is possible to prevent the pressure in the liquid pocket from increasing due to the liquid compression that occurs when the liquid refrigerant mixes in the fluid to be compressed, or to drive the orbiting scroll in a circular orbit by a motor driven by an inverter. When the rotation speed is changed, the centrifugal force of the orbiting scroll changes,
It has not been sufficiently solved in order to prevent the pressing force between the scrolls of the orbiting scroll and the fixed scroll from becoming excessive and the problem of the sealing force from occurring.

This point will be described in more detail.
JP-A No. 60-12956 discloses that a frame, a compressor section and electric motor sections arranged on both sides of the frame are housed in a hermetically sealed container, and a spiral body is fixed to the compressor section as a plate. The scroll comprises a scroll and an orbiting scroll in which a spiral body that meshes with the fixed scroll is provided upright. An intermediate bearing member for transmitting the rotational force of the electric motor unit to the orbiting scroll is provided between the orbiting scroll and the electric motor unit. The intermediate bearing member is a balancer of an orbiting scroll, and includes a main body having a boss hole for axially supporting the boss of the orbiting scroll, and a balancer portion, and a drive pin provided at the end of the rotary shaft is fitted to the main body. An eccentric hole that can be fitted is provided, the center of the boss hole of the intermediate bearing member is separated from the center of the rotating shaft by the radius of the circular orbit, and the eccentric distance of the drive pin is greater than the eccentric distance of the eccentric hole and the radius of the circular orbit. The center of the drive pin is orthogonal to the line that connects the center of the boss hole and the center of the rotation axis, and is on the side opposite to the center of the rotation axis with respect to the line that passes through the center of the boss hole and rotates with the center of the boss hole. Disclosed is a structure of a scroll compressor which is provided at a position displaced from the line connecting the centers of the shafts in the rotation direction of the rotating shaft, thereby driving the orbiting scroll, and the structure of the orbiting scroll by the centrifugal force of the balancer portion is disclosed. It is stated that the centrifugal force is offset.

Now, assuming that the center of the rotary shaft is O, the center of the boss hole of the intermediate bearing member is P, and the center of the eccentric hole into which the drive pin is fitted is Q, the force acting on P is as shown in FIG. .
Here, in normal operation, the formula is established and the line contact parts of both scrolls come into contact, and F _B −F _T tan α <F _C −F _S ...... However, F _B : Radial gas load F _{T of the} revolution circle F _T : Tangent gas load on the revolution circle F _C : Orbiting scroll centrifugal force F _S : Balance weight centrifugal force And, at the time of abnormally high pressure operation such as liquid compression, the formula is established and the line contact parts of both scrolls must be separated.

F _B −F _T tan α> F _C −F _S …… The ratio of the radial gas load F _B to the tangential gas load F _T is the tooth height and thickness of the scroll body of the scroll compressor, If the angle etc. is decided, it is decided as a value peculiar to the scroll compressor, so when the scroll body of the scroll compressor is determined, the value of F _B −F _T tan α is the wrap of the scroll. Is proportional to the gas pressure in the fluid pocket surrounded by, while the value of F _C −F _S due to the centrifugal force changes according to this rotation speed when the rotation speed of the rotating shaft changes.

In such a relationship, the equation holds under normal operating conditions, and the equation holds when the liquid refrigerant flows into the fluid pocket to cause liquid compression. , but those determined by the selection of the shape of the hole positions and the spiral body of the intermediate bearing member, the rotational speed of the motor for driving the scroll is changed, when the centrifugal force of the scroll (F _C -F _S) is changed is some If the relationship between the force due to the pressure in the fluid pocket (F _S = F _T tan α) is changed or other mechanism is not used, the equation holds during liquid compression and the equation holds during normal operation. It is difficult to obtain, and if this relationship does not hold well, the contact between the laps does not loosen and the spiral body is damaged by abnormal high pressure operation,
On the contrary, there was a problem that it did not function sufficiently as a gas compressor.

<Problems to be Solved by the Invention> An object of the present invention is to minimize the influence of centrifugal force (change of F _C −F _S ) due to rotation when the number of rotation changes,
The above equations and equations are to be determined substantially by the gas pressure in the fluid pocket.

<Means for Solving the Problems> Therefore, in the present invention, the orbiting scroll and the balance portion smaller than the balance weight for canceling the dynamic unbalance due to the circular orbital motion of the intermediate bearing member are provided to the intermediate bearing member. So that it can be moved.

<Operation> When the rotation speed of the electric motor that drives the orbiting scroll changes, the centrifugal force acting on the balance part is made larger than the change in the centrifugal force acting on the orbiting scroll so that the orbiting scroll swirls with respect to the fixed scroll. The influence of the centrifugal force of the rotating part on the body pressing force is reduced.

<Embodiment> The present invention will be described below with reference to the embodiments shown in FIGS. 1 to 4.

Referring to FIG. 1, the illustrated compressor 1 includes a cylindrical case 2
And an upper lid 3 that closes one end of the cylindrical case 2. A frame 10 having a bearing portion 11 having a ball bearing 12 mounted therein is mounted in the cylindrical case 2. A rotary shaft 7 rotatably supported by a ball bearing 12 has a large diameter portion 8 at its tip, and a drive pin 9 is axially provided on the end face of the large diameter portion 8 at a position deviated from the center. ing. The rotating shaft 7 is the stator 14 of the electric motor unit 13.
It is mounted on a rotor 16 that rotates by energizing the winding 15 of the above, and the rotational force is transmitted to the rotating shaft 7.

A fixed scroll 17, an orbiting scroll 18, an Oldham ring 19 for preventing the orbiting scroll 18 from being automatically operated, and an intermediate bearing member 28 are provided in the cylindrical case 2 above the frame 10.

The fixed scroll 17 is generally formed by a plate body 20, a spiral wrap 21 fixed to one surface of the plate body 20, and an annular wall 22 provided on the outer periphery of the wrap, and the annular wall 22 is formed by the frame 10.
It is fixed by fixing with bolts.

The orbiting scroll 18 comprises a plate 25, a spiral wrap 26 fixed to one surface thereof, and a boss 27 formed on the opposite surface thereof, and the wrap 26 is a spiral wrap of the fixed scroll 17.
Engaged at an angle offset of 21 ° and 180 ° to form a fluid pocket between the wraps.

The intermediate bearing member 28 is formed with a boss hole 29 into which the boss 27 that coincides with the spiral center of the wrap 26 of the orbiting scroll 18 is inserted, and the orbiting scroll 18 is rotatably instructed via a needle bearing 30. The intermediate bearing member 28 has an eccentric hole 34 axially penetrating at a position displaced from the center of the rotary shaft 7.
The drive pin 9 is fitted in the eccentric hole 34 to rotatably support the guide pin 35 provided on the rotary shaft 7 on the same side as the drive pin 9 so as to be loosely fitted. An elliptic hole 36 to be fitted is formed to regulate the swing angle when the intermediate bearing member 28 moves about the eccentric hole 34 as a fulcrum.

In the intermediate bearing member 28, as shown in FIGS. 2 and 3, a recess 33 is formed in a semicircular portion 31 extending in the radial direction, and an elastic holding device 37 is formed in the recess 33. A balance weight 32 that is elastically held by the intermediate bearing member 28 is provided. This elastic holding device 37 is a balance weight.
A bolt 40 that penetrates through the through hole 38 of 32 and is screwed into the screw hole 39 of the intermediate bearing member 28, a locking plate 42 that is stopped by the head 41 of this bolt, and this locking plate and the balance weight 32. And a coil spring 43 that presses the balance weight 32 toward the intermediate bearing member 28 by inserting a bolt 40 between the coil spring 43 and the coil spring 43. The through hole 38 of the balance weight 32 is formed so that the inner diameter dimension is larger than the outer diameter dimension of the bolt 40. The balance weight 32 is configured to overcome the pressing force of the coil spring 43 and move outward.

The balance weight part mainly including the balance weight 32 is provided to reduce the centrifugal force F _C due to the circular orbit operation of the orbiting scroll 18, and the centrifugal force F _S of the intermediate bearing member 28 including the balance weight part is F It is formed to be slightly smaller than _C.

In the state shown in FIG. 4, the length of ▲ ▼ is selected to the above-mentioned raceway radius R _O , and when the drive pin 9 is fitted into the eccentric hole 34, the center Q of the eccentric hole 34 formed in the intermediate bearing member 28. Is ▲ ▼
It is on the same side as O with respect to the line passing through and passing through P, and is located between O and P and is displaced from the line passing through and passing through O in the direction of rotation of this rotating shaft. Chosen to be assembled into.

In the structure of such a drive mechanism, the center P of the intermediate bearing member 28 is centered on the drive pin 9, and therefore its center Q,
It is possible to move on an arc. That is, when the rotary shaft 7 starts to rotate, the intermediate bearing member 28 is pushed by the drive pin 9,
Due to the inertial force, a force that causes the center P of the intermediate bearing member to separate from O acts, and the spiral wrap of the orbiting scroll 18 is wrapped.
26 contacts the side wall of the spiral wrap 21 of the fixed scroll 17. Therefore, the center P of the orbiting scroll 18 is the center O of the rotation axis.
It makes a circular orbit with a radius R _O around. At this time,
Since the orbiting scroll 18 is prevented from rotating by the Oldham ring 19, it does not rotate. This orbital movement of the orbiting scroll 18 causes the fluid pocket to move and compress the fluid, as described above. At this time, the cylindrical case 2 is provided with a fluid suction port 44 for supplying the fluid to be compressed into the closed container 1. On the other hand, in order to discharge the compressed fluid into the discharge muffler body 23, a discharge hole 24 is formed in the central portion of the plate body 20 of the fixed scroll 17, and the discharge pipe 6 for connecting the discharge muffler body 23 to an external fluid circuit. Is provided on the upper lid 3.

When the orbiting scroll 18 is revolved using the intermediate bearing member 28 having such an eccentric hole 34, the pressing force at the line contact portions of the wraps 21 and 26 of both spirals is generated by the combined force of the centrifugal force and the compressive load. Obtained automatically, which ensures the sealing of the fluid pocket. Further, since the center P of the intermediate bearing member 28 can be rotated around the center Q of the drive pin 9, for example, the pitch of the spirals and the wall thickness of the spirals 21 and 26 are changed by the dimensional error of the spiral wraps 21 and 26. However, the O-P distance can be changed accordingly.

The balance weight 32 overcomes the pressing force of the coil spring 43 of the elastic holding device 37 and moves when the rotating shaft 7 is operated by changing the number of rotations by an inverter or the like, and the position of its center of gravity changes. Since the position of the center of gravity of the orbiting scroll 18 does not change, the centrifugal force F _C acting on the orbiting scroll changes compared with only the rotation speed. On the other hand, the centrifugal force F _S acting on the balance weight portion is related to the weight of the balance weight 32 and the spring constant of the coil spring 43, and changes greatly in proportion to the rotational speed and the position of the center of gravity. For this reason, the difference between the centrifugal force F _C acting on the orbiting scroll 18 and the centrifugal force F _S acting on the balance weight portion is made less susceptible to the change in the rotational speed. In other words, the pressing force of the wrap 26 of the scroll of the orbiting scroll 18 against the fixed scroll 17 is maintained regardless of the rotation speed, and the influence of the centrifugal force of the rotating scroll 18 is reduced.

<Effects of the Invention> As described above, in the scroll compressor having the structure of the present invention, the centrifugal force is generated during the steady operation in which the gas pressure in the fluid pocket stops at the rise to a certain pressure due to the setting of the angle α as described above. To secure the pressing force between the wraps (formula established), while pressing the wraps due to the difference in centrifugal force when the liquid pressure is compressed such that the gas pressure in the fluid pocket exceeds a certain pressure. caused by the force (F _C -F _S) gas large force in the fluid pockets than by this force, loose contact wraps, so as not to cause an increase in abnormal gas pressure in the pocket.

Further, according to the present invention, when the rotation speed of the electric motor unit that drives the scroll compressor changes, the centrifugal force acting on the orbiting scroll 18 and the centrifugal force acting on the balance unit are actuated by the action of the balance weight portion held by the spring. And lap so that the pressing force between the wraps due to the centrifugal force is not affected by the rotation speed, and the laps come into contact with or separate from each other due to the gas pressure. It enables protection during abnormally high pressure operation.

[Brief description of drawings]

1 to 4 show the present invention, FIG. 1 is a vertical sectional view of a scroll compressor, FIG. 2 is a plan view showing a state in which an intermediate bearing member is attached to a rotating shaft, and FIG. Figure III-III
FIG. 4 is a schematic view for explaining the action of the intermediate bearing member, taken along the line. 1 ... Airtight container, 7 ... Rotating shaft, 9 ... Drive pin, 10 ...
… Frame, 13 …… Motor part, 17 …… Fixed scroll,
18 ...... Orbiting scroll, 20, 25 ...... Plate, 21, 26 ...... Wrap of spiral body, 27 ...... Boss, 28 ...... Intermediate bearing member, 29 ......
Boss hole, 32 …… balance weight, 33 …… recess, 34 ……
Eccentric hole, 35 …… Guide pin, 43 …… Coil spring.

Claims (1)

[Claims] 1. A fixed scroll in which a frame, a compressor section and an electric motor section arranged on both sides of the frame are housed in a hermetic container, and a spiral scroll is erected on a plate body of the compressor section, An intermediate bearing which is composed of an orbiting scroll in which a spiral body meshing with the fixed scroll is provided upright, and transmits a rotational force of the electric motor unit rotating in the counterclockwise direction to the orbiting scroll between the orbiting scroll and the electric motor unit. Members are provided,
The intermediate bearing member is a balancer for an orbiting scroll, and includes a main body having a boss hole for axially supporting a boss of the orbiting scroll, and a balancer portion having a centrifugal force slightly smaller than the centrifugal force of the orbiting scroll. An eccentric hole into which a drive pin provided at the end of the rotary shaft is fitted is provided, the center of the boss hole of the intermediate bearing member is separated from the center of the rotary shaft by the radius of the circular orbit, and the radius of the circular orbit is the radius of the drive pin. It is shorter than the sum of the eccentric distance and the eccentric distance of the eccentric hole, the center of the drive pin is orthogonal to the line connecting the center of the boss hole and the center of the rotation axis, and the center of the rotation axis is the line passing through the center of this boss hole. It is provided on the same side and at a position that is orthogonal to the line that connects the center of the boss hole and the center of the rotation shaft and that deviates from the line that passes through the center of the rotation shaft in the rotation direction of the rotation shaft. Let me In the scroll compressor described above, the intermediate bearing member is composed of a main body having a boss hole for axially supporting the boss portion of the orbiting scroll, and a balancer portion separately attached to the main body and movably attached to the main body. ,
A scroll compressor in which the balancer portion is held by a spring that presses inward.