DE2812594A1 - SNAIL FLOW MACHINE - Google Patents

Description

HITACHI, LTD., Tokyo, Japan

Scroll turbomachine

The invention relates to a scroll-type fluid flow machine which is used as a compressor for increasing the pressure of Air or other gases, as a coolant compressor for freezers, showcases or refrigerators, as Coolant compressor for air conditioning or room cooling devices or as an expansion device for implementation of the Rankine process or for expanding a high pressure gas to a predetermined pressure level can be used to generate power.

U.S. Patent 3,884,599 and U.S. Patent 3,924,977 are agents for producing an axial seal on two screw assemblies, with the front end of the overlap the one screw is kept in contact with the end plate of the other screw to allow gas to escape to prevent between the two snails.

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File pressurizes the gas coming out of the through the "two." The back side (i.e. the area from which the overlap occurs) is taken from the outlet area defined by the screw runs out, opposite surface) of one screw, so that one screw is pressed tightly against the other. The gas acting on the back of the screw is directed to a part of the back, which is only one has a very small area. In the known structure, an axial thrust force acts, the magnitude of which is that exerted by the gas corresponds to axial displacement force on a bearing 47 (Tgl. Figs. 8 and 34 of US-PS 3,884,599) and on main drive shaft bearings 122, 293 and 343 (cf. 8, 34 and 38 of the same U.S. Patent) so that each this bearing is subjected to a strong axial thrust.

In US-PS 3,994,633 and US-PS 3,994,636 screws are indicated which are surrounded by a housing, which has a chamber into which a fluid is provided from an outside of the scroll turbomachine Pressure supply is introduced so that the fluid reaches the back (i.e. that of the area from which the overlap going out, opposite surface) act on one screw and thereby the screw tightly against the other snail can push. With this arrangement, the axial thrust applied to each bearing can be eliminated will. However, this type of scroll-type turbomachine has some disadvantages. On the one hand, a separate pressure supply must be arranged outside the turbomachine. Furthermore, if the scroll-type fluid-flow machine is used as a refrigerant compressor, great care must be taken

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to use is that no non-condensing gas enters the coolant, means may be provided to ensure that the two screws are hermetically sealed are tight so that the gas introduced into the housing chamber does not enter the gas to be compressed by the screws Gas can enter.

The object of the invention is to create a screw flow machine, in which a good axial sealing of the screws is achieved by means of a simple structure is, no pressure supply located outside of the turbo machine is required for the axial sealing of the screws and it is unnecessary to provide means using mixing one for axial sealing Prevent gas with a gas to be compressed by the screws.

According to the invention, to achieve this object, a part of a gas of an intermediate pressure stage is provided of the scroll-type flow machine in a housing chamber formed in a housing, so that the gas acts on the rotating screw and presses it tightly against the stationary screw. The intermediate pressure gas is through at least one small hole formed in the end plate of one of the two screws into the housing chamber insertable.

The invention thus specifies a screw flow machine in which an intermediate pressure gas of is withdrawn from the working chambers during the compression or expansion of a fluid and the entire the rear area of one of two screws

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impacts, so that one screw is pressed tightly against the other and thereby an axial seal of the both snails is reached.

An embodiment of the invention is explained in more detail below with reference to the drawing. Show it:

1a views showing the working principle to 1d of a screw or scroll compressor explain;

Pig. 2 shows a vertical section through the scroll turbomachine the invention; and

3 is a sectional view according to III-III Fig. 2.

Before the detailed explanation of a preferred embodiment, the working principle of a screw or Scroll fluid machine will be briefly explained with reference to a compressor as a typical example; reference is made to FIGS. 1a-1d. In these figures the end plates are omitted and only the overlaps shown. Fig. 1a shows the relative positions of the overlap 1b of a revolving screw 1 and the Overlap 2b of a stationary screw 2 when the compressor begins to compress the fluid after the suction of the fluid has ended. Figures 1b, 1c

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and 1d show the relative positions of the overlaps 1b and 2b after the revolving screw 1 has moved in Has rotated counterclockwise by 90 ° from the positions according to Fig. 1a or 1b or 1c.

When the screw compressor changes from the state according to FIG. 1a to the states according to FIGS. 1b and 1c moved, fluid-tight gaps created by the overlaps 1b and 2b of the two screws 1 and 2 are formed, gradually reduced in size, and the fluid therein is compressed. That condensed Fluid is conveyed from the tight spaces through an outlet opening when a connection is established between the said spaces; this results when the two screws 1 and 2 have a certain angular relationship to one another which extends between the positions according to Pig. 1c and Fig. 1d results. If the revolving screw 1 rotates counterclockwise by 90 ° from the position according to FIG. 1d, the two screws 1 and 2 are returned to their relative starting positions according to FIG. 1a. In the 1a-d, the fluid-tight spaces are formed by radial lines of contact 4 of the two screws 1 and 2. The formation of the fluid-tight spaces will hereinafter be referred to as being effected by radial sealing.

The above explanation relates to a compressor. However, it can be seen that when a high pressure gas is supplied the revolving screw 1 is opposite to the tight spaces through the outlet opening 3 revolves in the aforementioned direction, so that the flow machine works as an expansion device.

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Reference is now made to FIGS. 2 and 3. The stationary screw 2 has an end plate 2a from which an overlap 2b extends and is arranged upright. The revolving screw 1, which is similar is constructed, has an end plate 1a and an overlap 1b extending therefrom, which are arranged upright is. The two overlaps 1b and 2b are essentially equal to one another in terms of thickness and height are arranged in the form of an involute or another similar curve.

The stationary screw 2 is at its center point with an outlet opening 3 and at its edge with a suction opening 5 trained.

The fixed screw 2 and the revolving screw 1 are arranged next to one another in such a way that the overlaps 2b and 1b point inwards and end points 2b ¹ and 1b ^{1 of} the overlaps 2b and 1b are offset by 180 ° or are diametrically opposite one another.

A housing 6 is connected to the fixed screw 2 by means of several bolts 7, which are at equal angular intervals are arranged to each other.

The housing 6 comprises a cylindrical housing part 6a in which two bearings 8 and 9 are arranged spaced apart in the tertiary direction and receive a drive shaft 10, the end section 10a of which is connected to the rotating worm 1 via a needle bearing 11. The drive shaft 10 and the revolving worm 1 are arranged in relation to one another in such a way that the center of rotation 0 ^ _{0 of} the drive shaft 10 and the center O ₁

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· the screw 1 from each other a distance S stick "Ben distance £ i; referred to as the radius of rotation.

Between a Miekselte Ta the revolving snail-1 and a "wood" surface 6b of the housing 6 is a Gldham washer; 1s2 arranged that a turning of the revolving Auger 1 / - around its own axis or around yours MiirfeenpunSrii Q ^ prevent.

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edaai -wei.1i; eiEex- Qr-EäiiDg 20 ": isrfe zwüseäBeam 6a. undl So the case & "was-rgeseljen» unt due kammear- TT iDcfffeüelcfe äfezi ^ eftüeJäem ,, lüe

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17 and the working chamber 21 and 22 are through that End plates 1a and 2a of the screws 1 and 2, which are kept in contact with each other, are sealed.

The operation of the turbomachine will now be explained. A drive unit, e.g. B. an electric motor (not shown ) _r drives the drive shaft 10, the rotational movement of which is transmitted via the needle bearing 11 to the revolving worm 1, which executes a rotary motion with the radius of rotation S around the center point O ₁₀ Oldham washer 12 a rotation of the worm 1 about its own axis "Thus the worm 1 rotates around the center point Q .. _{Q of} the drive shaft 10 without changing its position relative to the stationary worm 2"

While the revolving worm 1. revolves around the center point Q.JQ of the drive shaft 10, the lines of contact 4 between the revolving and the stationary worm T or «2 move from the end points 1b ^f or 2b ^{f of} the overlaps 1b or« 2b to: the starting points 1b ^tt or ZK? *, so the talumen of the working chambers 21 and 22 _r through, the end plates 1a and 2a and the overlaps, tb and 2b of the two screws 1 and. 2 are defined _r decreases and. the denomination agent is compressed "

A compressed gas with the aforementioned intermediate pressure flows through the small ones. Lacher 13 _r 14 * 15 and 16 in the housing chamber 1.7 from the. Working chambers 21 and 22, while the gas is compressed in these chambers, and the pressure in the housing chamber 17 is at the intermediate level.

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keep. The intermediate pressure gas in the housing chamber 17 presses the rotating screw 1 tightly against the stationary screw 2, so that the two Screws 1 and 2 are tight in the axial direction.

The advantages achieved by the invention are as follows: Since the intermediate pressure gas acts on the rotating screw 1, if the gas does not exert an excessively high pre-tensioning force on the rotating screw, when the gas pressure acts on the entire area of the rear side of the revolving screw 1. This gets a good axial seal between the two screws 1 and 2.

With coolant compressors or expansion devices It is important that the housing is constructed in such a way that gas can escape from the scroll-type turbomachine to the outside or the penetration of a gas from the outside into the screw flow machine is avoided. These This requirement is met by the invention, since a good axial seal between the two screws is simply a result of this it can be achieved that at least one small hole is formed in the end plate 1a. That is, the goal of a axial seal can be realized by a very simple structure.

The gas compressed or expanded by the scroll-type turbomachine itself is used for the axial seal of the two screws are used, so that no separate pressure source outside the device is required. Furthermore, there is no risk that a dissimilar gas will mix with the gas in the device

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and it is only necessary to prevent gas from leaking outside the facility. this is achieved in a simple manner, since that is in the housing chamber introduced gas has the said intermediate pressure.

H U 9 8 4 0/0 8 6 7

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Claims (4)

Expectations Screw flow machine, with a rotating and a stationary screw, each of which has an end plate and an overlap extending therefrom, which is arranged upright, has; with a drive shaft that is rotatable about its central axis, which is with respect to the center of the revolving screw is eccentric, so that the revolving worm is around the drive shaft circulates; with a housing having a housing chamber; with an Oldham washer that allows the rotating one to turn Prevents the worm around its center and causes the worm to move around the drive shaft without changing its position circulates; with a suction port; and
with an outlet opening,
marked by a mechanical seal (18) which is arranged in a part of the housing (6) through which the drive shaft (10) runs is, so that the housing chamber (17) is tight, and at least one small hole (13) formed in the end plate of one of the two screws (1, 2), which the housing chamber (17) while compressing or relaxing a 81- (A 2857-02) -schö 8U9840 / 0 867 Fluids with working chambers (21, 22) of the turbomachine connects, so that the internal pressure of the housing chamber (17) at a level between the pressure level at which the fluid is sucked into the working chambers (21, 22) and the pressure level at which it is released therefrom, so that the intermediate ^{pressure I 1} IuId presses one screw (1) firmly against the other screw (2) and creates an axial seal. 2. Screw flow machine according to claim 1, characterized in that that at least one small hole (13) that the housing chamber (17) during the sealing or relaxation of a fluid connects to the working chambers (21, 22), formed in the end plate (1a) of the revolving screw (1) is. 3. Screw flow machine according to claim 1, characterized in that that at least one small hole (13) that the housing chamber (17) with the working chambers (21, 22) during the Compressing or relieving a fluid, is formed along the overlap (1b). 4. Screw flow machine according to claim 2, characterized in that that at least two small holes (13, H) are provided and each working chamber (21, 22) with the housing chamber (17) connected by a small hole (13, H). 809840/0867