JPH0610868A - Scroll compressor - Google Patents

Abstract

PURPOSE:To moderate a motion speed of a delivery valve by arranging a valve spring connected between the delivery valve and a fixed scroll. CONSTITUTION:A valve spring 10 is arranged to be connected between a delivery valve 9 and a fixed scroll 7. The valve spring 10 is constituted so as to press the delivery valve 9 in an upward direction. Pressing force of the valve spring 10 is set smaller than force by a difference between a pressure Ps in a compression chamber and a delivery pressure Pd. When exceeding a communication angle, down-facing force acts on the delivery valve 9 by a difference between a compression space pressure and the delivery pressure. On the other hand, since the downward facing force can be moderated by applying upward facing force by the valve spring 10, a speed at seating time of the delivery valve 9 is decreased, and a crack of the delivery valve 9 can be prevented. Since a delivery port 7b is closed by the delivery valve 9 by a differential pressure between the delivery port pressure Pd and the compression chamber internal pressure Ps at the time of stopping a compressor, reversing of the compressor can be prevented. In this way, the scroll compressor of high reliability can be obtained.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scroll compressor suitable for use as a refrigerant or an air compressor in a refrigerating apparatus, an air conditioner or the like.

[0002]

2. Description of the Related Art FIG. 5 is a sectional view showing an entire conventional scroll compressor, and FIG. 6 is a sectional view showing an essential part of the same scroll compressor. In the figure, 1 is a shell having a discharge pipe hole 2, A main shaft 3 is provided inside the shell 1 and has an oil supply hole 4 and an eccentric hole 5. Reference numeral 6 denotes an orbiting scroll, which is supported in an eccentric hole 5 of the main shaft 3 through an orbiting bearing, is accommodated inside the shell 1, and further has an orbiting shaft 6b on a scroll end plate 6a thereof. is there. Reference numeral 7 denotes a fixed scroll which is eccentrically combined with the orbiting scroll 6 and has a scroll end plate 7a.
It has a discharge port 7b. 8 is the discharge port 7b
Is a discharge valve housed in the valve retainer 8, and 10 is a valve spring disposed between the discharge valve 9 and the valve retainer 8.

Reference numerals 11 and 12 denote an upper bearing support and a lower bearing support, and the main bearing 1 is fitted with a spigot.
The spindle is supported via 3,14. Reference numeral 15 is a motor stator fixed to the lower bearing support 12, and 16 is a motor rotor provided inside the motor stator 15 and fixed to the main shaft 3. Further, 17 is a compression chamber formed by the scrolls 6 and 7, 18 is an oil reservoir,
Is an inhalation tube.

Next, the operation will be described. When the main shaft 3 rotates due to the rotation of the motor rotor 16, the orbiting scroll 6 orbits. At this time, the fluid in the compression chamber formed by the scrolls 6 and 7 is gradually compressed and discharged as a high-pressure fluid. The pressure change in the compression chamber at this time will be described with reference to FIGS. 7 and 8.

FIG. 8 shows a compression chamber formed by both scrolls. In the figure, 17c is the final pressure chamber, 1
7b is a second compression chamber. In the figure, θ indicates the rotation angle of the orbiting scroll. FIG. 7 shows a pressure change in the final compression chamber 17c. The volume in the final compression chamber 17c in which the oscillating scroll oscillates is reduced, and the pressure in the final compression chamber 17c rises. The pressure Ps in the final compression chamber 17c is
If it becomes larger than the sum of the discharge port pressure Pd and the pressing force f by the valve spring 10, an upward force acts on the discharge valve 9, the discharge valve 9 moves upward, the discharge port 7b opens, and the high pressure. The fluid is ejected.

If the rotation angle further advances and the compression chambers 17b and 17c communicate with each other as shown in FIG. 8D, the final compression chamber 17
The pressure of c rapidly decreases to Ps <Pd, and the discharge valve 9
A downward force acts on this to move downward, and the discharge valve 9 closes the discharge port 8b. FIG. 9 shows the movement of the discharge valve 9. In the figure, χ is the displacement amount of the discharge valve 9, χ ₁ is the position where the discharge valve 9 closes the discharge port 8b, and χ ₂ is the valve retainer 8.
It is the position pressed by.

[0007]

In the conventional scroll compressor described above, the pressure Ps in the compression chamber during the high compression ratio operation is high.
And the discharge port pressure Pd increase, the force acting on the discharge valve 9 increases, and the movement speed of the discharge valve 9 also increases. Especially when the compression chambers 17c and 17b are in communication, the pressure P in the compression chamber
Since the change of s is rapid, the downward force acting on the discharge valve 9 becomes large and the movement speed of the discharge valve 9 becomes large.
There is a problem that the discharge valve 9 is cracked by the impact force when the discharge valve 9 is seated on the valve seat 7c.

The present invention has been made in order to solve the above-mentioned problems, and it is possible to reduce the movement speed of the discharge valve and thereby prevent the discharge valve from cracking. The purpose is to provide a compressor.

[0009]

A scroll compressor according to the present invention includes a shell having a discharge pipe hole that opens in the axial direction, and an orbiting scroll that is operated by a motor housed in the shell via a main shaft. , A scroll compression which is provided with a fixed scroll which is combined with the orbiting scroll and has a discharge port which communicates with the discharge pipe hole, a discharge valve which opens and closes the discharge port, and a valve retainer which guides the discharge valve. In the machine, a valve spring is arranged between the discharge valve and the fixed scroll.

Further, a shell having a discharge pipe hole opened in the axial direction, an orbiting scroll operated by a motor housed in the shell via a main shaft, and the discharge pipe combined with the orbiting scroll. In a scroll compressor having a fixed scroll having a discharge port communicating with a hole, a discharge valve for opening and closing the discharge port, a valve retainer for guiding the discharge valve, and the like, a damper mechanism is provided for the valve retainer. The damper valve is configured to support the discharge valve.

Further, a shell having a discharge pipe hole opened in the axial direction, an orbiting scroll operated by a motor housed in the shell via a main shaft, and the discharge pipe combined with the orbiting scroll. A fixed scroll having a discharge port communicating with the hole, a discharge valve for opening and closing the discharge port, a valve retainer for guiding the discharge valve, and the like, and a scroll compressor fixed to the discharge valve in the scroll compressor. A valve spring is provided between the scroll and between the discharge valve and the valve retainer, and the discharge valve is supported by the valve spring so as to open and close the discharge port.

[0012]

With the above structure, in the present invention, the valve spring is provided between the discharge valve and the fixed scroll,
Since the upward spring force acts on the discharge valve to reduce the downward force due to the pressure difference, the movement speed of the discharge valve can be reduced.

Further, in the case of a structure in which a damper mechanism is provided on the valve retainer and the discharge valve is supported by this damper mechanism, since a resistance force proportional to the speed of the discharge valve acts, the movement speed of the discharge valve Can be relaxed.

Further, valve springs are provided between the discharge valve and the fixed scroll, and between the discharge valve and the valve retainer, and the valve springs support the discharge valve so as to open and close the discharge port. With this configuration, the downward spring force acts when the discharge valve approaches the valve retainer, and the upward spring force acts when the discharge valve approaches the fixed scroll. Can be reduced as well as the impact velocity of the valve retainer can be mitigated.

[0015]

【Example】

Example 1. FIG. 1 shows an embodiment of the scroll compressor according to claim 1. The structure other than the main part of the present invention is the same as that of the above-described conventional embodiment, and the description thereof is omitted. In FIG. 1, 7 is a fixed scroll, 7c is a valve seat, 8 is a valve retainer,
9 is a discharge valve, 10 is a valve spring, and the valve spring 10 is configured to press the discharge valve 9 upward. The pressing force f of the valve spring 10 is set to be smaller than the force due to the difference between the pressure Ps in the compression chamber and the discharge pressure Pd. That is,
f <S (Pd-Ps), where S is the area of the discharge valve 9.

Next, the movement of the discharge valve 9 according to the present invention when seated will be described. When the communication angle θ is exceeded, the discharge valve 9
A downward force is applied to the pressure difference due to the difference between the compression space pressure and the discharge pressure. On the other hand, since the valve spring 10 exerts an upward force and can moderate the downward force, the discharge valve 9
The downward speed at the time of seating is reduced, and the discharge valve 9 can be prevented from cracking. Further, when the compressor is stopped, the discharge valve 9 closes the discharge port 7b due to the differential pressure between the discharge boat pressure Pd and the compression chamber pressure Ps, so that the reverse rotation of the compressor can be prevented.

Example 2. FIG. 2 shows an embodiment of the scroll compressor according to claim 2. In this embodiment, a damper mechanism is provided on the valve retainer. That is, in FIG. 2, 9 is a discharge valve, 8 is a valve retainer, 20 is a cylinder, 21 is a piston, 21a is an orifice provided in the piston 21, 22 is a working fluid, and 23 is a connecting valve for connecting the discharge valve 9 and the piston 21. It is a rod. Further, 24 is a seal member provided between the connecting rod 23 and the valve retainer 8 and leaks the working fluid inside the cylinder 20 to the outside. The damper mechanism is composed of the above components.

With such a structure, a force f that impedes the movement of the discharge valve 9 acts on the discharge valve 9. That is, when the discharge valve 9 moves upward, a downward force acts, and when it moves upward, a downward force acts.

The magnitude of the force f is expressed by the following equation. f =
C · dx / dt, that is, a damping force f that is proportional to the movement speed of the check valve acts on the check valve. Here, the viscous damping coefficient C is given by the following equation according to the viscosity of the working fluid and the diameter of the orifice. C = 8πμl · A ⁴ / a ⁴ , A is the cylinder diameter, a is the orifice diameter, l is the flow path length of the orifice, and μ is the kinematic viscosity of the working fluid.

As described above, when the movement speed of the discharge valve 9 is high, a large damping force acts and the movement speed of the discharge valve 9 can be reduced, so that the collision speed of the discharge valve 9 against the valve seat 7c is reduced. It can be delayed, and thus the discharge valve 9 can be prevented from cracking.

FIG. 3 shows an embodiment of the scroll compressor according to the present invention. In FIG. 3, 9 is a discharge valve, 8 is a valve retainer, and 10a and 10b are valve springs. Valve spring 10a
And 10b are configured to generate an upward spring force when the discharge valve 9 is in the vicinity of the fixed scroll 7 and a downward spring force when the discharge valve 9 is in the vicinity of the valve retainer 8. is there.

An example of such a configuration will be described with reference to FIG. In the figure, χ indicates the position of the discharge valve 9, and χ ₁ indicates the discharge valve 9.
Is in contact with the fixed scroll 7, χ ₂ is the discharge valve 9
Shows a state in which is in contact with the valve retainer 8. The vertical axis represents the spring force, and the upward force is positive. In the figure, the broken line is the spring force of 10a, the dashed-dotted line is the spring force of 10b, and the solid lines are 10a and b.
Shows the resultant force. When the discharge valve 9 is in the vicinity of the fixed scroll 7, the spring length of 10a becomes short, and a strong upward force is generated. Further, when the discharge valve 9 is near the valve retainer 8, the spring length becomes long and the upward spring force becomes weak.

On the other hand, 10b produces a strong downward force when the discharge valve 9 is near the valve retainer 8 because the spring length becomes short. Further, when the discharge valve 9 is in the vicinity of the fixed scroll 7, the spring length becomes long, and the downward spring force becomes weak.
If 10a and 10b are configured in this way, 10a and 10b
The resultant force of b acts downward when the discharge valve 9 is near the valve retainer 8, while the discharge valve 9 is fixed scroll 7
If it is in the vicinity, it acts upward.

According to this structure, when the discharge valve 9 is seated on the valve seat 7C of the fixed scroll 7, the upward panel acts on the downward pressure due to the discharge pressure and the pressure difference in the compression chamber. Therefore, the downward speed can be moderated. Further, when the discharge valve 9 collides with the valve retainer 8, the downward spring force acts on the upward force due to the flow of the discharge gas, so that the upward speed can be moderated.

As described above, the fixed scroll 7 of the discharge valve 9
It is possible to reduce the speed of collision of the valve seat with the valve seat 7c and the speed of collision with the valve retainer 8. As a result, it is possible to prevent the valve from cracking when the discharge valve 9 is seated, and it is possible to prevent noise due to collision with the valve retainer 8 and abnormal friction of the valve retainer 8.

[0026]

As described above, according to the present invention, since the valve spring is arranged between the discharge valve and the fixed scroll, the seating speed of the discharge valve can be slowed and the crack of the discharge valve can be prevented. It is possible to obtain a scroll compressor with high reliability.

According to the second aspect of the present invention, the damper mechanism is provided in the valve retainer, and the discharge valve is supported by the damper mechanism. Therefore, the seating speed of the discharge valve can be slowed down. It is possible to prevent the discharge valve from cracking and obtain a highly reliable scroll compressor.

According to the invention described in claim 3, between the discharge valve and the fixed scroll, and between the discharge valve and the valve retainer,
Since the valve springs are respectively provided and the discharge valves are supported by the valve springs so that the discharge ports can be opened and closed, the seating speed of the discharge valve and the collision speed of the valve retainer can be slowed down. It can prevent valve cracking, prevent abnormal friction of the valve retainer, and prevent noise.
It is possible to obtain a highly reliable scroll compressor.

[Brief description of drawings]

FIG. 1 is a first embodiment of the present invention. 3 is a cross-sectional view showing the main parts of the scroll compressor according to FIG.

FIG. 2 is a second embodiment of the present invention. 3 is a cross-sectional view showing the main parts of the scroll compressor according to FIG.

FIG. 3 is a third embodiment of the present invention. 3 is a cross-sectional view showing the main parts of the scroll compressor according to FIG.

FIG. 4 is a relationship diagram showing the acting force of the valve spring according to the embodiment of the present invention.

FIG. 5 is a sectional view showing a conventional scroll compressor.

FIG. 6 is a sectional view showing a main part of a conventional scroll compressor.

FIG. 7 is a relationship diagram showing a pressure change in a final compression chamber of a conventional scroll compressor.

FIG. 8 is an explanatory diagram showing a compression chamber of the scroll compressor.

FIG. 9 is a relational diagram showing movement of a discharge valve of a conventional scroll compressor.

[Explanation of symbols]

 1 Shell 3 Spindle 6 Oscillating Scroll 7 Fixed Scroll 7b Discharge Port 8 Valve Hold 9 Discharge Valve 10 Valve Spring

Claims (3)

[Claims] 1. A shell having a discharge pipe hole opened in the axial direction, an orbiting scroll operated by a motor housed in the shell via a main shaft, and the discharge pipe combined with the orbiting scroll. In a scroll compressor having a fixed scroll having a discharge port communicating with a hole, a discharge valve for opening and closing the discharge port, a valve retainer for guiding the discharge valve, and the like, a valve provided between the discharge valve and the fixed scroll. A scroll compressor having a spring. 2. A shell having a discharge pipe hole opened in the axial direction, an orbiting scroll which is operated by a motor housed in the shell via a main shaft, and the discharge pipe combined with the orbiting scroll. In a scroll compressor having a fixed scroll having a discharge port communicating with a hole, a discharge valve for opening and closing the discharge port, a valve retainer for guiding the discharge valve, and the like, a damper mechanism is provided for the valve retainer. A scroll compressor, wherein the discharge valve is supported by a damper mechanism. 3. A shell having a discharge pipe hole opening in the axial direction, an orbiting scroll operated by a motor housed in the shell via a main shaft, and the discharge pipe combined with the orbiting scroll. In a scroll compressor provided with a fixed scroll having a discharge port communicating with the hole, a discharge valve for opening and closing the discharge port, a valve retainer for guiding the discharge valve, and the like, between the discharge valve and the fixed scroll, A scroll compressor is provided with a valve spring between the discharge valve and the valve retainer, and the valve spring supports the discharge valve so as to open and close the discharge port.