KR20010111239A - The multi-scroll pump - Google Patents

Abstract

The present invention relates to a multiple scroll fluid machine which can obtain a high output by operating a plurality of scroll units are synchronized, the configuration thereof is as follows.

In the center, there is a housing in which the fluid collection part and three or more scroll chambers are formed at equal intervals in the center, and a plurality of swinging scroll parts mounted inside the housing and assembled with the scroll chambers. It is characterized in that it consists of a rocking member is mounted to three or more interlocking camshaft.

Description

Electric rotating fluid machine {The multi-scroll pump}

The present invention relates to a multi-scroll fluid machine applied to the compression, expansion and pumping of fluid, and more particularly to a multi-scroll fluid machine that can obtain a high output by allowing a plurality of scroll units to operate in synchronization.

In general, the electric field rotating fluid machine applies the basic principle of the well-known scroll, and is produced as a product such as a compressor, an expander, a vacuum pump or a conveyer as it is applied to pumping as well as compression and expansion of a fluid. Accordingly, the prior art of a representative scroll fluid machine among multiple scroll fluid machines is as follows.

Conventional scroll fluid machine, using a compression method by the synchronous rotational movement of the fixed scroll member and the swinging scroll member, the fixed scroll member is fixed to the main body, the pivoting scroll member is connected to a separate drive unit, The pivoting scroll member is rotated by applying power to make a linear contact with the fixed scroll member to compress or expand the fluid.

Therefore, in recent years, an electric field rotating scroll fluid machine, which is a technology capable of increasing efficiency by rotating the fixed scroll member with a rotating scroll member, is known and in use.

Therefore, FIG. 9 is a configuration diagram schematically illustrating a fluid machine in which the fixed scroll member and the swing scroll member are interlocked and rotated.

The main shaft 100 is mounted on one side of the main body 100 and the driving shaft 102 is mounted on the other side, and the support shaft 103 is mounted at an eccentric position with the driving shaft 102. ) Is mounted at the end of the drive unit 101 to receive the rotational force of the driving means 101 and to the inside of which the scroll 201 protrudes, and to the end of the support shaft 103 and to the inside of the scroll 301. ) Is characterized by consisting of a driven scroll member 300 is protruding.

In particular, the inlet port (HH) is formed in the center of the drive shaft 102, the discharge port (OH) for discharging the compressed fluid is formed on the outside of the main body (100).

As shown in FIG. 10, the plurality of parts are in close contact with each other on sidewalls of the scrolls 201 and 301 formed in the driving scroll member 200 and the driven scroll member 300, and thus, the driving scroll member 200. When the drive shaft 102 is connected to the rotating, the driving scroll member 200, as well as the driven scroll member 300 is interlocked due to the adhesion of the scroll (201,301) formed inside the driven, driven scroll member (200,300) To rotate.

Hereinafter, the operation of the electric field rotating fluid machine configured as described above.

9 and 10, when power is applied to the driving means mounted on one side of the main body 100, the driving shaft 102 is rotated so that the driving scroll member 200 is also interlocked.

At the same time, as described above, the driven scroll member 200 which is eccentrically assembled to the driving scroll member 200 is also rotated in association with the support shaft 103 due to the frictional force of the scroll units 201 and 301.

Therefore, after the fluid flows through the suction port IH formed at the center of the drive shaft 102, the flow fluid is compressed and formed by the scrolls 201 and 301 of the driven and driven scroll members 200 and 300 repeatedly formed. After passing through, the compressed fluid is supplied to an air conditioning line (not shown) through an outlet OH formed on the outside of the main body 100.

However, in moving the fluid through the electric field rotating fluid machine configured as described above, the driving, driven scroll member is made of only a pair, there was a problem that can not be applied to a large-capacity fluid machine.

In addition, since the rotational force of the driving scroll member is transmitted to the driven scroll member through friction, the performance of the fluid machine is deteriorated due to the loss of power due to the continuous rotation of the driving and driven scroll members and friction, which also leads to a problem that high power cannot be obtained. there was.

In addition, the side walls of the scrolls formed on the inner side of the driving and driven scroll members are easily worn out due to friction, thereby degrading the performance of the apparatus.

In addition, the wear phenomenon caused by the vibration and loud noise during operation of the device also had a problem.

In addition, in the prior art, a lubricant is generally used to prevent the above-described wear of the scroll, but the lubricant is difficult to apply a precision fluid machine as it causes a sliding phenomenon of each scroll and prevents rotation of the driven scroll member. I had.

Accordingly, the present invention has been invented to solve the above-described problems, and has an object to provide a multi-scroll fluid fluid machine in which three or more scroll units are synchronized to obtain high output.

It also has the purpose of enabling high speed output by operating the swinging member on which a plurality of scroll portions are formed without rotating completely.

In addition, it has the purpose of maximizing the output by connecting the drive cam shaft and the interlock cam shaft.

In addition, the swinging scrolls have the purpose of preventing the occurrence of vibration and noise during operation by maintaining only the state in which the swinging scrolls repeatedly contact each other without sliding with respect to the fixed scrolls.

In addition, a plurality of scroll units are synchronized through a single drive camshaft, which has the purpose of simplifying the configuration of the device.

It also has the purpose of preventing the mixing of the lubricant in the fluid by eliminating the need for the lubricant on the contact surfaces of the scrolls.

In order to achieve the above object, the present invention provides a housing having three or more scroll chambers at equal intervals in a fluid collection portion and a periphery thereof, and a plurality of mounted in the housing and assembled with the scroll chambers. It is characterized in that the swinging scroll portion is provided with a rocking member having a drive cam shaft in the center and three or more interlocking cam shafts in the peripheral portion thereof.

1 is a perspective view showing an electric field rotating fluid machine of the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a cross-sectional view taken along the line B-B in FIG.

Figure 4 is a schematic diagram showing a connection state of the drive camshaft according to the present invention.

Figure 5 is a schematic diagram showing a connection state of the interlocking camshaft according to the present invention.

6 is a schematic view showing an assembled state of gears according to the present invention.

Figure 7 is a cross-sectional view showing another embodiment of the electric field rotating fluid machine according to the present invention.

Figure 8 is a cross-sectional view showing another embodiment of the electric field rotating fluid machine according to the present invention.

9 is a schematic cross-sectional view showing a conventional scroll pump.

10 is a cross-sectional view taken along the line C-C in FIG.

Explanation of symbols for main parts of drawings

1: housing

11: collection part

111 outlet

12: scroll room

121: inlet hole, S2: fixed scroll

13: space part

2: rocking member

21: rocking scroll member

S1: rocking scroll

22: drive camshaft

221: eccentric cam, 222; Axis of rotation, 223: middle eccentric shaft,

W: balance weight

23: linked camshaft

231; Eccentric cam, 232: rotation axis, 233: intermediate eccentric shaft

24: fluid through hole

25: soft disk

G1: drive gear, G2: driven gear, G3: idle gear

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

1 is a perspective view showing a multiple scroll fluid machine of the present invention, Figure 2 is a cross-sectional view taken along the line A-A of Figure 1, Figure 3 is a cross-sectional view taken along the line B-B of Figure 2, the configuration thereof is as follows.

A fluid collecting part 11 having a discharge port 111 is formed in the center, and three or more scroll chambers 12 having inlet holes 121 are formed at equal intervals, and a vertical space is formed in the middle. A housing 1 in which the portion 13 is formed,

It is mounted to the space portion 13, the peripheral portion is provided with three or more swinging scroll portion 21 to be assembled with the scroll chamber 12, the drive cam shaft 22 and three or more interlocking portions in the peripheral portion in the center Camshaft 23 is mounted in a horizontal state, the central peripheral portion is characterized in that composed of a rocking member (2) formed with one or more fluid passage holes (24).

In addition, the swinging scroll unit 21 is composed of swinging scrolls S1 formed in pairs on both sides of the swinging member 2, and a pair of fixed scrolls symmetrical to each other on the inner wall of the scroll chamber 12. S2) are formed and assembled with the pair of swinging scrolls S1.

In addition, two or more contact portions A1 and a space A2 are formed between the sidewalls on which the fixed scroll S2 and the swinging scroll S1 are assembled, so that the swinging cam shaft 22 is rotated when the driving cam shaft 22 is rotated. As the member 2 pivots and the contact portion A1 and the space A2 are alternately changed, the fluid flowing into the inlet hole 121 is moved toward the outlet 111.

In particular, even when the interlocking camshaft 23 is mounted at three or more places, the swinging member 2 can pivotally swing inside the housing 1.

Hereinafter, the above configuration will be described in more detail.

Figure 4 shows the assembled state of the drive cam shaft according to the present invention, the drive cam shaft 22 is formed in the middle, the eccentric cam 221 penetrating the center of the rocking member 2, and the eccentric cam ( 221 formed on both sides of the rotating shaft 222 penetrating the housing 1, the rotation axis 222 formed on both ends of the drive cam shaft 22 deviation of the center of gravity generated in the drive cam shaft 22 The balance weight (W) having the shape of the eccentric plate to be offset is to be mounted.

Therefore, the drive cam shaft 22 is mounted at the center of the swinging member 2 to serve as a power source for swinging the swinging member 2.

5 shows an assembled state of the interlocking camshaft according to the present invention, wherein the interlocking camshaft 23 is formed in the middle and penetrates the center of the rocking scroll unit 21 formed at equal intervals in the rocking member 2. It is composed of an eccentric cam 231 and a rotating shaft 232 formed on both sides of the eccentric cam 231 and inserted into the housing 1.

On the other hand, as shown in Figures 4 and 5, the diameter and the eccentric interval of the eccentric cams (221,231) constituting the drive cam shaft 22 and the interlocking cam shaft 23 is formed to be the same, installed at a plurality of equal intervals It is possible to constantly swing the rocking of the swinging scroll portion 21 is made.

In addition, intermediate eccentric shafts 223 and 233 are formed between the eccentric cams 221 and 231 constituting the drive cam shaft 22 and the interlocking cam shaft 23 and the rotation shafts 222 and 232. 25) is to be mounted.

Accordingly, the soft disk 25 minimizes friction with the housing 1 and prevents damage to the inner surface of the housing 1 and both sides of the moving member 2. In addition, when using the machine for a long time by replacing only the soft disk 25 is to prevent the performance of the machine is reduced.

6 is a schematic view showing the assembly state of the gears according to the present invention, the drive shaft (G1) is mounted on the rotary shaft 222 of the drive cam shaft 22, the rotary shaft 232 of the interlocking cam shaft (23) is The driven gears G2 having the same tooth shape and pitch circle as the drive gears G1 are mounted, and the driven gear G3 is mounted between the outer side of the drive gear G1 and the driven gears G2, thereby driving the driven gears. It is possible to match the rotation direction of the (G2) and the drive gear (G1).

That is, the rotation speed of the drive cam shaft 22 in which the drive gear G1 is mounted and the interlocking cam shaft 23 in which the driven gear G2 is mounted can be maintained the same.

Hereinafter will be described the operational relationship of the present invention configured as described above.

As shown in FIGS. 1 to 3, first, when the driving cam shaft 22 penetrating the center of the housing 1 is rotated through a driving unit (not shown), the driving cam shaft 22 is mounted in the middle of the driving cam shaft 22. Since the eccentric cam 221 is also rotated at the same time, the swinging member 2 on which the eccentric cam 221 is mounted starts turning swing.

At the same time, the interlocking camshaft 23 mounted at equal intervals is also interlocked through the entire intrinsic swinging swing of the swinging member 2, thereby limiting the swinging swing range of the swinging member 2.

That is, when the swinging member 2 swings as described above, the swinging scroll portion 21 mounted at the same intervals on the swinging member 2 swings in the scroll chamber 12 formed in the housing 1. By oscillating, the close contact portion A1 and the space portion A2 formed by the oscillating scroll S1 of the oscillating scroll portion 21 and the fixed scrolls S2 of the scroll chamber 12 are repeated one after another. Is changed.

Therefore, the fluid flowing into the inflow hole 121 is collected through the space portion A2 repeated in the intervals and collected by the collecting portion 11 formed in the center of the housing, and then the discharge port 111 formed in the collecting portion 11. It is supplied to the air conditioning line (not shown) through.

7 is a view showing another embodiment of the present invention, the configuration of which is as follows.

The housing 1, the rocking member 2 and the drive camshaft 22 is the same as described above, the interlocking camshaft 23 is formed in the middle, formed on the rocking member (2) An eccentric cam (231 ') mounted between the swinging scroll portions (21), and a rotating shaft (232') formed on both sides of the eccentric cam (231 ') and inserted into the housing (1). will be.

Therefore, the drive cam shaft 22 is rotated and the interlocking cam shaft 23 is also rotated through the swinging swing of the rocking member 2.

That is, when the swinging member 2 is pivotally rotated as described above, the swinging swing portion 21 mounted on the swinging member 2 at equal intervals is pivoted in the scroll chamber 12 in which the housing 1 is formed. The contact portion A1 and the space portion A2 formed by the swinging scrolls S1 of the swinging scroll portion 21 and the fixed scrolls S2 of the scroll chamber 12 are repeatedly changed at different times. The fluid flowing into the inflow hole 121 passes through the space portion A2 repeated at the same time, is collected by the collecting portion 11 formed at the center of the housing, and then discharge port 111 formed in the collecting portion 11. It is supplied to the air conditioning line (not shown) through.

8 shows another embodiment according to the present invention, wherein the configuration of the housing 1, the swinging member 2, and the drive camshaft 22 is the same as described above, and the drive camshaft 22 ) Is mounted through the center of the swinging member (2) and the center of the housing (1), it is characterized in that no interlocking camshaft is mounted.

That is, as only the driving cam shaft 22 is rotated, the swinging member 2 pivots along the swinging scroll portion 21 mounted at the same time as the driving cam shaft 22 is rotated. Will be.

Therefore, when the swinging scroll portions 21 make the swinging swing as described above, the contacting portions (S1) of the swinging scroll portion 21 and the fixed scroll (S2) of the scroll chamber 12 are formed ( As A1) and the space A2 are repeatedly changed at different times, the fluid flowing into the inflow hole 121 passes through the space A2 repeated at the same time and is collected into the collecting part 11 formed at the center of the housing. Then, it is supplied to the air conditioning line (not shown) through the outlet 111 formed in the collecting portion (11).

The present invention as described above has an effect of increasing the output efficiency, which is a weak point of the scroll pump, by providing a multi-scroll fluid machine that can obtain a high output.

In addition, it is possible to operate the swinging member in which the plurality of scroll portions are formed without rotating completely, thereby enabling high-speed output, thereby having the effect of extending the application range of the apparatus.

In addition, it has the effect of maximizing the output by connecting the drive cam shaft and the interlock cam shaft.

In addition, by preventing the wear of each scroll by the contact operation, it also has the effect of preventing the generation of vibration and noise during operation to increase the reliability of the device.

In addition, by simplifying the configuration of the device through a single camshaft, it is possible to reduce the unit cost of the device.

In addition, by preventing the mixing of the lubricant with the fluid, it also has the effect of preventing the transfer fluid deterioration.

Claims (11)

A fluid collecting portion 11 having a discharge port 111 formed at the center thereof and three or more scroll chambers 12 having an inlet hole 121 formed at the periphery thereof are formed at equal intervals, and a vertical space portion 13 is formed in the middle thereof. The housing 1 is formed, Three or more swinging scroll portions 21 mounted on the space portion 13 and assembled with the scroll chambers 12 are provided, and a driving cam shaft 22 in the center and three or more interlocking cam shafts 23 in the peripheral portion thereof are provided. ) Is horizontally mounted, the central periphery is composed of a rocking member (2) formed with at least one fluid passage hole (24). According to claim 1, The swinging scroll portion 21 is composed of a swinging scroll (S1) formed in pairs on both sides of the swinging member (2), a pair of symmetrical to the inner wall of the scroll chamber 12 The fixed scroll (S2) of the multiple scroll fluid machine, characterized in that assembled with the pair of swinging scroll (S1). 3. The multi-scroll fluid machine according to claim 2, wherein at least two contact portions (A1) and spaces (A2) are formed between the side walls on which the fixed scroll (S2) and the swinging scroll (S1) are assembled. The eccentric cam (221) according to claim 1, wherein the drive cam shaft (22) is formed in the middle and penetrates the center of the rocking member (2), and is formed on both sides of the eccentric cam (221) to form the housing ( 1) A multiple scroll fluid machine comprising a rotating shaft 222 penetrating therethrough. The method of claim 4, wherein both ends of the drive cam shaft 22 is equipped with a balance weight (W) having a shape of the eccentric plate is mounted so as to offset the deviation of the center of gravity generated in the drive cam shaft (22) Scroll fluid machine. The eccentric cam (231) according to claim 1, wherein the interlocking cam shaft (23) is formed in the middle and passes through the center of the swinging scroll portion (21) formed at regular intervals in the swinging member (2). And a rotating shaft (232) formed on both sides of the (231) and inserted into the housing (1). The multi-scroll fluid machine according to claim 1, wherein the diameter and the eccentric distance of the core cams (221, 231) constituting the drive cam shaft (22) and the interlocking cam shaft (23) are the same. The driving gear G1 is mounted on the rotation shaft 222 of the driving cam shaft 22, and the driving gear G1 is mounted on the rotation shaft 232 of the interlocking cam shaft 23. Follower gears G2 having the same tooth shape and pitch circle as () are mounted, and a plurality of driven gears G2 can be made to match the rotational direction of the driven gears G2 between the outer side of the drive gear G1 and the driven gears G2. Multi-idle fluid machine characterized in that the idle gear (G3) of the. The intermediate eccentric shafts 223 and 233 are formed between the eccentric cams 221 and 231 constituting the drive cam shaft 22 and the interlocking cam shaft 23 and the rotation shafts 222 and 232. The outer diameter of the eccentric shaft (223, 233) is a multiple scroll fluid machine, characterized in that the soft disk 25 is mounted to minimize the friction with the housing (1). The eccentric cam (231 ') according to claim 1, wherein the interlocking cam shaft (23) is formed between the swinging scroll portions (21) formed in the middle and formed on the swinging member (2). And a rotating shaft (232 ') formed on both sides of the') and inserted into the housing (1). The multiple scroll fluid machine according to claim 1, wherein only the drive cam shaft (22) is mounted through the center of the swinging member (2) and the center of the housing (1), and no interlocking cam shaft is mounted. .