DE102006042021A1 - Compressor with gas-bearing piston - Google Patents

Abstract

A compressor has an inlet port (12) and an outlet port (13) for a gas to be compressed and a working chamber (1) in which a piston (2) is movable for compressing the gas, swept in one of the pistons (2) Wall (10) of the working chamber (1) with the outlet port (13) communicating openings (11) are formed. A particulate filter (7) is disposed in a flow path of the gas between the inlet port (12) and the outlet port (13).

Description

The The present invention relates to a gas pressure bearing compressor Piston, in particular for use as a refrigerant compressor in a domestic refrigerator.

In household appliances become conventional Compressors with rotary driven piston and oil lubrication used. Due to the rotary drive, the piston is a such compressor in the course of its stroke movement in a working chamber also forces Exposed transverse to the stroke direction, the piston against the wall of the Press working chamber. In order to protect the compressor from fretting, it is necessary to switch between pistons and chamber wall, a continuous oil film may be present. The tenacity of the oil must be big enough be to exclude that under the action of a lateral force the oil between wall and piston repressed becomes. The bigger the transverse forces are the more viscous must the oil be, and the stronger you are Frictional losses due to the viscosity of the oil.

Around To improve the efficiency of the compressor, are lately reinforced Efforts made been developed to develop compressors with linear motor drive. Such a Linear motor exercises lower lateral forces on the flask so that thinner Lubricants can be used up to a storage of the piston through the to be compacted Gas itself. In such a compressor with gas pressure bearing are in a swept by the piston Wall of the working chamber openings formed communicating with an outlet port of the compressor, allowing a small portion of the compressed medium from the outlet port through the openings back pour into the working chamber can and creates a gas cushion between the piston and wall, which ideally a movement of the piston completely without contact with the wall and thus also without any fretting wear possible.

These However, ideal conditions prove difficult to realize. In practice it became common After a relatively short period of operation, a failure of the linear compressor due to fretting between Piston and chamber wall detected.

task The invention is therefore to a compressor with compressed gas storage create, which allows to reliably prevent such friction wear.

The Task is solved by a compressor having an inlet port and an outlet port for a gas to be compressed and a working chamber in which a piston for compressing the gas is movable, wherein in a swept by the piston Wall of the working chamber with the outlet port communicating openings are formed, and which is characterized by a particulate filter, that in a flow path of the gas through the compressor between the inlet port and the outlet port is arranged.

at more precise investigations of the failed compressors have been found that found therein impurities not only on abrasion of the Piston and the chamber wall went back, but also partially from other areas of the refrigerant circuit were registered, and it is believed that these were non-Compressors Contaminants, even if their amount and particle size in itself is insufficient to control the mobility of the piston in the compressor to impair when with the refrigerant flow circulate, first single wall openings clogging, causing the piston cushion protecting gaskets becomes. In the area of these gaps can no longer reliably prevent contact between the piston and the wall so that the abrasion created by contacts the compressor quickly destroyed.

remedy creates here the particle filter according to the invention, by preventing these foreign impurities from the wall openings to reach.

One such particle filter can be provided at various points in the compressor be. According to a first embodiment, the particulate filter disposed between the inlet port and the working chamber. Such a particle filter has the advantage that foreign contaminants be prevented from the outset to reach the working chamber. This is more coarse in particular in the case Foreign impurities desirable, which cause damage even by their presence in the working chamber can.

adversely however, at such a placement of the particulate filter is that the resulting filtering of the complete passing through the compressor Gas flow requires a considerable drive power and therefore affects the efficiency of the compressor. In addition, the pressure drop can Such a particle filter will never become larger than the pressure at Inlet connection itself, allowing to reach a sufficient Throughput a high conductance and accordingly a large cross section of the filter may be required. Especially when used of the compressor in a chiller It is important that the particle filter is not too high back pressure builds up, since this upstream of the evaporation of the refrigerant in the filter Impact evaporator would.

one According to a second embodiment, the particulate filter is in one Output of the working chamber connecting to the output port Conduit disposed between the output and a branch leading to the openings. This arrangement of the filter leads not to an undesirable Pressure increase at the inlet connection of the compressor. In addition, can arranged on such on the pressure side of the compressor Filter a higher one Pressure drop can be constructed as on the inlet side described above Filter, allowing adequate throughput even on a compact Filter is accessible, but affects such a high pressure drop turn the efficiency of the compressor.

one third, particularly preferred embodiment branches of one connecting an output of the working chamber with the outlet port Pressure line one to the openings premier Branch line off, and the particulate filter is in the branch line arranged. Because such a particle filter only on that fraction the gas flow needed to produce the gas cushion acts is the drive power required for The filtering must be done low, even if the pressure drop at the particulate filter is the same as that according to the second Design.

The Although arranged in the branch line filter does not prevent from at the outset that foreign contaminants pass through the compressor, she starts but still all in the course of the operation of the compressor, as soon as they get into the branch line.

one According to preferred development, the branch line comprises a Distribution chamber and a distribution chamber connecting the pressure line Bore, wherein the swept by the piston wall wall a partition forms between the working chamber and the distribution chamber. At a such branch pipe, the particulate filter can be small and compact in the bore can be arranged, or it can in the distribution chamber covering the partition be arranged.

at a working chamber with reciprocating piston, the distribution chamber is preferably a hollow cylinder extending around the cylindrical working chamber.

Further Features and advantages of the invention will become apparent from the following Description of exemplary embodiments with reference to the attached Characters.

It demonstrate:

1 a schematic sections through a compressor according to the invention with suction-side particulate filter;

2 one too 1 analog section through a compressor according to the invention with pressure-side particle filter;

3 one too 1 analogous section through a compressor according to the invention with arranged in a branch line particulate filter; and

4 a section through a modification of the compressor with arranged in a branch line particulate filter.

1 shows a schematic section through a compressor according to a first embodiment of the invention. The compressor is part of a refrigerator of a household refrigerator, which, since its other components are known, is not shown. In a cylindrical working chamber 1 the compressor is a piston 2 by a not shown, also known per se drive unit back and forth. The drive unit may, for example, a linear motor such as in DE 10 2004 010 849 A1 However, in general, any drive unit is considered, which is able to generate a driving force whose transverse components are small enough so that a frictional contact between the walls of the working chamber 1 and the piston 2 can be safely avoided.

At one end of the working chamber are a suction valve 3 and a pressure valve 4 that the working chamber 1 with a suction line 5 or a pressure line 6 and over this with an inlet port 12 or an outlet port 13 connect. In the suction line 5 is a particle filter 7 appropriate. From the pressure line 6 leads a hole 8th to a distribution chamber 9 of hollow cylindrical shape, which is the working chamber 1 surrounds, so that of the piston 2 Wall swept over in its movement 10 the working chamber 1 a partition between the working chamber 1 and the distribution chamber 9 is. In this wall 10 is a variety of narrow openings 11 distributed.

During operation, the piston sucks 2 when moving to the right refrigerant from the inlet port 12 over the suction line 5 , the particle filter 7 and the suction valve 3 in the working chamber 1 one. During a movement of the piston 2 to the left is the contents of the working chamber 1 first on the in the pressure line 6 prevailing pressure compressed before the pressure valve 4 opens and the compressed gas in the pressure line 6 flows. A small part of the pressure line 6 flowing gas passes through the hole 8th into the distribution chamber 9 and from there over the openings 11 the Wall 10 back to the working chamber 1 where he got a gas cushion between the col ben 2 and the wall 10 forms.

Foreign particles that were present in the various other components of the chiller before their assembly or incurred by the assembly are from the particulate filter 7 intercepted before entering the working chamber with the refrigerant flow 1 can reach. Such are the openings 11 protected from constipation by the foreign particles. Because the gas cushion between pistons 2 and wall 10 Thus, there is no gap between the piston and the wall, which in turn over the bore 8th and the distribution chamber 9 to the openings 11 could get in and clog them.

In the 2 The embodiment shown differs from that of 1 in that the particulate filter 7 not in the suction line 5 but in the pressure line 6 between the pressure valve 4 and the hole 8th is arranged. As in the case of the embodiment of 1 the entire refrigerant passing through the compressor passes through the particulate filter 7 , Due to the arrangement of the particulate filter 7 in the pressure line 6 can be attached to the particulate filter 7 a higher pressure drop can be established than in the embodiment of 1 , so that even with a compact filter sufficient throughput can be achieved.

The design of the 3 differs from the two explained above by the placement of the particulate filter 7 in the distribution chamber 9 , It is there on the wall 10 on, making it by the pressure difference between its outer and inner side against the wall 10 is pressed. Since only a fraction of the refrigerant flow rate of the compressor passes through the filter and the drive power consumed during filtering corresponds to the product of filter throughput and pressure drop, the power overhead due to filtering in this design is only a fraction of the additional demand of the first two embodiments.

The attachment of the particulate filter 7 in the distribution chamber 9 has the advantage that the particle filter 7 can be traversed by the refrigerant on a very large cross-sectional area, so that even when using a very tight-pored filter sufficient to maintain the gas cushion throughput can be achieved.

For a uniform distribution of the gas on the openings 11 to ensure the particle filter has 7 here preferably a layer structure with a fine-pored outer layer 7a and a coarse-pored, well-drained inner layer whose function is substantially a distance between the fine-pored layer 7a and the wall 10 to maintain, in which the gas evenly on the openings 11 can distribute.

The presently preferred embodiment of the invention is in 4 shown. This embodiment differs from the previously described in that the bore 8th that the distribution chamber 9 with the pressure line 6 connects, long and wide enough to the particle filter 7 in the form of a filter cartridge 14 take. The filter cartridge is in the hole 8th of which the pressure line 6 introduced facing end ago. A pressure-side flange 15 the filter cartridge is located at one at the entrance of the hole 8th formed shoulder 16 on, leaving the filter cartridge 14 by the pressure drop that it produces on the refrigerant flowing through it to the shoulder 16 is pressed.

According to a development not shown in a figure, the suction side particulate filter 7 the embodiment of 1 also with the on the way of the refrigerant from the pressure line 6 to the openings 11 arranged particulate filter according to 3 or 4 be combined. In this case, the suction side particulate filter may be a coarse-pored filter with low flow resistance, which merely serves to remove coarse contaminants from the working chamber 1 keep away while finer impurities are intercepted by the pressure-side particle filter.

Claims (10)

Compressor with an inlet connection ( 12 ) and an outlet port ( 13 ) for a gas to be compressed and a working chamber ( 1 ), in which a piston ( 2 ) is movable to compress the gas, wherein in one of the piston ( 2 ) swept wall ( 10 ) of the working chamber ( 1 ) with the outlet port ( 13 ) communicating openings ( 11 ), characterized by a particle filter ( 7 ), which in a flow path of the gas between the inlet port ( 12 ) and the outlet port ( 13 ) is arranged. Compressor according to claim 1, characterized in that the particulate filter ( 7 ) between the inlet port ( 12 ) and the working chamber ( 1 ) is arranged. Compressor according to claim 1, characterized in that the particulate filter ( 7 ) in one output ( 4 ) of the working chamber ( 1 ) with the output terminal ( 13 ) connecting line ( 6 ) between the output ( 4 ) and one to the openings ( 11 ) leading branch ( 8th . 9 ) is arranged. Compressor according to claim 1, characterized in that from an an output ( 4 ) of the working chamber ( 1 ) with the output terminal ( 13 ) connecting pressure line ( 6 ) one to the Öffnun gene ( 11 ) leading branch line ( 8th . 9 ) and that the particle filter ( 7 in the branch line ( 8th . 9 ) is arranged. Compressor according to claim 4, characterized in that the branch line ( 8th . 9 ) a distribution chamber ( 9 ) and a distribution chamber ( 9 ) with the pressure line ( 6 ) connecting bore ( 8th ), whereby that of the piston ( 2 ) swept wall ( 10 ) a partition wall between the working chamber ( 1 ) and the distribution chamber ( 9 ). Compressor according to claim 5, characterized in that the particle filter ( 7 ) in the hole ( 8th ) is arranged. Compressor according to claim 5, characterized in that the particle filter ( 7 ) in the distribution chamber ( 9 ) the partition ( 10 ) is arranged overlapping. Compressor according to one of claims 5 to 7, characterized in that the distribution chamber ( 9 ) around the cylindrical working chamber ( 1 =) is extending hollow cylinder. Compressor according to one of the preceding claims, characterized in that the piston ( 2 ) is driven by a linear motor. Refrigeration device, thereby in that it comprises a compressor according to one of the preceding claims Refrigerant compressor having.