JPS60135691A - Scroll hydraulic machine - Google Patents

Abstract

PURPOSE:To permit to uniformize thermal expansion of laps by a method wherein a crank shaft, having a path for cooling agent, is fitted into a chamber, in which the cooling agent stagnates for a while, to seal the chamber with the shaft and cool the central high-temperature part of a rotary scroll. CONSTITUTION:Oil, poured from an oil supplying port 18, is poured into an oil supplying path 14 in the crank shaft 6 from the protuberance 26 of a frame 5a, passes through a radial path 27 to lubricate a rotating bearing 10, subsequently, cools the central high-temperature part of the rotary scroll 1 in an oil reservoir 21 and is discharged out of an oil discharging port 20. The discharged oil is recirculated to the oil supplying port 18 after being cooled in an oil cooler 24. The oil may be substituted by the cooling agent. According to this method, the cooling agent is not forced into the compression chamber or the backside chamber of the rotary scroll 1, the central high-temperature part of the rotary scroll 1 is cooled and the thermal expansions of laps 1b, 2b may be uniformized whereby hydraulic loss of the machine may be reduced.

Description

[Detailed Description of the Invention] [Field of Application of the Invention] The present invention mainly relates to compressors and vacuum pumps among scroll fluid machines (compressors, vacuum pumps, expanders, etc.), and particularly relates to clean compressed gas and clean compressed gas. Scroll fluid machine to obtain vacuum.

[Background of the invention]

Scroll compressors and vacuum pumps operate in the same way, just at different pressure levels. The working chamber of a scroll compressor is shown in the figure. Due to the engagement between the fixed scroll wrap 2b and the orbiting scroll wrap 1b, a plurality of working chambers V are formed.
1#VQ? ..., 'v't'rv2'... are formed. Gas is confined in the outermost working chambers V and V□', and as the orbiting scroll moves, one working chamber moves to the center while decreasing its volume, and is compressed and discharged from the discharge port in the center. . Since the compression process is close to adiabatic change, the temperature of the gas increases as it is compressed.

Therefore, the temperature of the compression chamber is high in the center and decreases toward the outer periphery. The scroll wrap temperature shows a similar distribution. Therefore, the wrap height differs between the central portion and the outer peripheral portion due to thermal expansion. This difference creates an axial gap near the outer periphery at the tip of the wrap, which increases fluid loss and has become a problem. In contrast, as a cooling means for the scroll, a means for cooling the scrolls by circulating a coolant such as oil through both scrolls has been used as disclosed in Japanese Patent Application Laid-Open No. 52-57507. In the case of an oil-free compressor, seal members are provided around the outer peripheries of the end plates of both scrolls to prevent these coolants from entering the working chamber. However, this seal member is an end face seal of a rotating sliding surface. This form of motion has become a problem because its sealing performance is inferior to that of shaft seals and the like, and the contamination of coolant into the working chamber is unavoidable.

[Purpose of the invention]

SUMMARY OF THE INVENTION An object of the present invention is to provide a scroll fluid machine that cools the central portion of an orbiting scroll and does not allow the coolant to mix into the working chamber of the scroll.

[Summary of the invention]

A feature of the present invention is that a room in which the coolant temporarily accumulates is provided on the opposite side of the central wrap of the orbiting scroll, a crankshaft having a coolant passage is fitted into this room, and a shaft seal is used to prevent the coolant from cooling. The reason is to prevent the agent from leaking out of that room and the crankshaft.

[Embodiments of the invention]

An embodiment of the present invention will be described below with reference to FIGS. 1 and 2.

FIG. 1 is an explanatory diagram of a first embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along the line AA.

■ is a fixed scroll, and the wrap 1b that stands upright on the end plate 1a is the wrap 2 that stands upright on the end plate 2a of the orbiting scroll 2.
It is arranged in mesh with b.

The wraps lb and 2b of both scroll members 1 and 2 are formed into an involute or a curved line approximating it,
It has a uniform thickness and a uniform height.

A boat 3 is provided at the center of the end plate 1a of the fixed scroll member 1, and another boat 4 is provided at the outer circumferential side. The boat 3 is a discharge boat in the case of a compressor, and an inflow boat in the case of an expander.

The boat 4 is a suction boat in the case of a compressor, and a discharge boat in the case of an expander.

The frame 5a is fixed to the outer periphery of the end plate of the fixed scroll member 1 by several poles 1-.

The crankshaft 6 has two bearings 7 attached to the frame 5a.
, 8 are supported by the frame 5a. A balance weight 9 is integrally formed on the crankshaft 6. The balance weight 9 may be separate from the crankshaft 6. A crank pin 6a is attached to the head of the crankshaft 6.
are formed integrally and eccentrically. On the other hand, a cylindrical protrusion 2c is provided on the surface opposite to the central wrap of the orbiting scroll end plate 2a, and the orbiting bearing 10 is press-fitted into the inner surface of the cylindrical protrusion 2c. The above-mentioned crank pin 6a is inserted into the orbiting bearing 10, and the rotation of the crankshaft 6 drives the orbiting scroll 2.

The rotation prevention member 20 is the end plate 1a of both scrolls.

It is a crank mechanism installed on the outer periphery of the scroll 2a and has the same eccentricity as the crankshaft 6, and prevents the orbiting scroll 2 from rotating. The rotation prevention member 20 and both scrolls are
They are tightly coupled via bearings 22 and 23. A grease-sealed needle roller bearing or a dry bearing is used for this bearing.

A thrust bearing 16 is provided between the orbiting scroll 2 and the frame 5a, and receives the axial gas force acting on the orbiting scroll 2 and transmits it to the frame. This thrust bearing uses a self-lubricating material (carbon, Teflon, etc.).

The bearings 7 and 8 are lubricated by injecting oil through the oil filler port 17, allowing it to pass through the bearings, and discharging it through the oil drain ports 20,19. The drained oil is cooled by an oil cooler, then pressurized by a pump 28 and circulated to the oil supply 17 again.

Oil seals 12 and 13 seal off leakage of oil from the chambers of the bearings 7 and 8 to the scroll section and to the outside of the compressor, respectively.

Inside the crankshaft 6, there is an oil supply passage 14 and an oil drainage passage 15.
The two passages 14 and 15 communicate with an oil reservoir 21 provided in a cylindrical protrusion 2c provided on the back surface of the orbiting scroll end plate 2a. In the case of the oil supply passage 14, it communicates with the oil reservoir portion 21 via the swing bearing 1o. The oil seal 11 allows this oil to flow through the orbiting scroll 2.
This prevents leakage into the room 25 at the back of the room.

The operation of the present invention will be explained below. The oil injected through the oil filler port 18 is injected from the protrusion 26 of the frame 5a into the oil feed passage 14 in the crankshaft 6, passes through the radial passage 27, lubricates the swing bearing 10, and then flows into the oil reservoir. At 21, the central part of the orbiting scroll is cooled, and the oil passes through the drain passage 15.
The oil is discharged from the oil drain port 2o. The discharged oil is cooled by the oil cooler 24 and then circulated to the oil filler port 18. Oil is replaced by other coolants.

Such a configuration has the effect that the central portion of the orbiting scroll can be cooled without mixing the coolant into the compression chamber or the chamber on the back side of the orbiting scroll.

Further, by using oil as a coolant as in this embodiment, there is an effect that the slewing bearing can be lubricated and cooled at the same time.6 FIG. 3 is a diagram showing a second embodiment of the present invention. Refueling passage 14
opens directly into the oil pool chamber 2I, and the radial passage 27
' is connected to the oil drain passage 15. With this configuration, there is an effect that the orbiting scroll end plate can be effectively cooled.

FIG. 4 shows another embodiment of the invention. Both the oil supply passage I4 and the oil drain passage 15 are opened directly into the oil pool chamber 21, and the oil in the oil pool chamber 21 is sealed with an oil seal 11', and the bearing 10' is not supplied with oil.

The bearing 10' is made of a self-lubricating material (carbon.

made of Teflon, etc.). With this configuration, the amount of oil to be supplied can be reduced, and the oil cooler 24 and pump 28 can be made smaller.

FIG. 5 shows an embodiment of another invention. Fins 29 are provided on the back surface of the orbiting scroll end plate facing the oil pool chamber 21. By configuring in this way, the heat transfer area increases,
This has the effect of improving the cooling effect of the orbiting scroll.

〔Effect of the invention〕

As described above, according to the present invention, it is possible to cool the central high-temperature part of the orbiting scroll and make the thermal expansion of the wrap uniform, and there is an effect that a scroll fluid machine with less fluid source loss can be obtained.

[Brief explanation of the drawing]

Figure 1 is a sectional view of the first embodiment of the present invention, Figure 2 is a sectional view taken along line A-A in Figure 1, Figure 3 is a sectional view of the second embodiment, and Figure 4 is a sectional view of the second embodiment.
The figure is a sectional view of the third embodiment, and FIG. 5 is a sectional view of another embodiment of the present invention. 1... Orbiting scroll, 2... Fixed scroll, I
a. 2a... End plate, lb, 2b... Wrap, 3... Port, 4... Port, 5... Frame, 6... Crankshaft, 7... Main bearing, 8... Auxiliary bearing, 9...
・Balance weight. 10...Swivel bearing, 11...Oil seal, 12.
...Oil seal, work 3...Oil seal, 14...
・Oil supply passage, 15...Oil drain passage, 16...Thrust bearing, 18...Oil filler port, 19...Oil drain port, 20...
- Oil drain port, 21... Oil pool, 22... Auxiliary crank bearing, 23... Auxiliary crank bearing, 24... Oil cooler, 27... Radial passage, 28... Pump.

Claims (1)

[Claims] (1) A pair of scroll members each having an end plate and a wrap are engaged with each other with their wraps facing each other, and the orbiting scroll member makes an orbital movement relative to the stationary scroll member so as not to apparently rotate on its own axis. In the invention, there is a room in which the coolant remains for one hour at the back of the center of the orbiting scroll, a crankshaft inserted into this room, a coolant supply passage and a discharge passage provided in the crankshaft, and the above-mentioned room. A scroll fluid machine consisting of a shaft seal member provided between crankshafts. 2. The scroll fluid machine according to claim 1, wherein a bearing is provided on the crankshaft between the shaft seal member and the chamber. 3. The scroll fluid machine according to claim 2, wherein the supply passage opens between the bearing and the shaft seal. 4. The supply passage # is opened between the back surface of the orbiting scroll end plate in the room and the bearing, and the discharge passage is opened between the bearing and the shaft seal. A scroll fluid machine according to claim 2. 5. The scroll fluid machine according to claim 1, wherein the bearing is provided on the crankshaft outside a space surrounded by the room and the shaft seal. 6. In a pair of scroll members having a plate and a wrap, which are engaged with each other with their wraps facing each other, and the orbiting scroll member orbits with respect to the stationary scroll member so as not to apparently rotate, the center of the orbiting scroll is A room in which the coolant remains for one hour on the back of the unit, a crankshaft inserted into this room, a coolant supply passage and a discharge passage provided within the crankshaft, and a space provided between the room and the crankshaft. A scroll fluid machine comprising: a shaft seal member provided with a rotary shaft seal member; and a fin provided on an orbiting scroll end plate within the chamber.