EP1589224A1 - Double piston for compressor - Google Patents

Abstract

A compressor has a double-piston consisting of an elongated core (11) with a piston (12, 13) at each end and linked by a connecting rod (11) that is parallel to the core. The connecting rod has a bearing (19) with a gudgeon pin (18) that is free to move on a cam (15) bearing (17) during the power stroke. The piston core has a centre section (31) extending between the two pistons that incorporates a gap (32) in which the connecting rod moves freely.

Description

The invention relates to a double piston for a compressor with the Features in the preamble of claim 1.

There is a double piston of this type for a compressor known (EP 12 33 183 A1), the connecting rod of a compressor between the output of a Drive means and the piston carrier is arranged to connect via the connecting rod rotating, eccentric output movement of the drive device in a back and forth implement reciprocal movement of the double piston. It has shown, that during the movement process of the piston in this and in the Valves of the compressor generate vibrations, which are transmitted through the connecting rod and the Pleuellager be transferred. Furthermore, arise from the drive device and from its eccentric vibrations. These vibrations Due to the mechanical stresses, premature bearing damage can occur cause and also have the disadvantage that thereby disturbing noises are generated, which are particularly uncomfortable, if such Compressor z. B. be installed in vehicles.

The invention is based on the object, a double piston of the above so-called type in such a way that when installed in a compressor any resulting vibrations dampened and thus generated noises at least reduced with concomitant increase in efficiency and the life of the bearings.

The task is in a double piston of the type mentioned in accordance with the Invention solved by the features in claim 1. Because of this in relation on the piston carrier and its piston symmetrical arrangement of the connecting rod act in the area of the bearings of the connecting rod no transverse forces but only forces within the plane of symmetry. This will reduce the load on the bearings reduced and the life of the connecting rod increased. Further, due Reduced bearing stress and increased efficiency. In Advantageously, this also results in a vibration damping with the result that otherwise reduces noises alone become. This makes one equipped with such a double piston Compressors with particular preference for installation wherever it is on Low noise particularly important, z. B. in vehicles. The design is simple, inexpensive and reliable.

Other particular features of the invention and embodiments thereof will be apparent from the other claims. Due to the at least one vibration damping device, in the connecting rod between the connecting rod bearing and the Coupling point is arranged, the vibration damping is still further improved, so that otherwise resulting noise many times over be reduced.

Further details and advantages of the invention will become apparent from the following description.

The full text of the claims is above solely to avoid unnecessary repetitions are not reproduced, but instead only by referring to the claims to it, however, by which all these claim features as at this point express and essential to the invention disclosed to have to apply. Here are all in the above and following description mentioned features as well as the only from the Drawing removable features further components of the invention, too if not highlighted and especially not in the Claims are mentioned.

Fig. 1

einen schematischen Schnitt eines Doppelkolbens mit daran angreifendem Pleuel eines ansonsten nicht weiter gezeigten Verdichters,

Fig. 2

die Halbseite eines schematischen Schnitts entlang der Linie II - II in Fig. 1.

The invention is explained in more detail with reference to an embodiment shown in the drawing. Show it:

Fig. 1

a schematic section of a double piston with it attacking connecting rod of a compressor not otherwise shown,

Fig. 2

the half-side of a schematic section along the line II - II in Fig. 1st

In the drawings, a piston 10 is one not otherwise shown Compressor, z. B. high-performance compressor, shown with a not shown electric drive motor analog z. B. EP 12 33 183 A1 to a Function unit can be assembled. The piston 10 is as Double piston formed having an elongated piston carrier 11, the one end a first piston 12 with a large diameter for a first Compression and at the opposite end a second piston 13 with smaller diameter for a second pressure stage. Based on these Design of the piston 10 as a double piston is not shown Compressor in two stages. The piston carrier 11 forms together with one or two pistons 12, 13 a one-piece component, the z. B. as a molded part Plastic or die-cast aluminum is formed.

The piston 10, in particular the piston carrier 11, is by means of a connecting rod 14 driven on an eccentric 15 at the end of a shaft 16 by means of a Warehouse 17, z. B. a ball bearing, hereinafter referred to as a rod bearing 17th is designated, is rotatably mounted. The shaft 16 is part of the drive device in the form of the electric drive motor, not shown, for. B. High-performance engine.

The connecting rod 14 extends approximately parallel to the piston carrier 11 and approximately at right angles to the longitudinal center axis of the shaft 16. At a radial distance from the eccentric 15 is on Piston carrier 11 a transverse bolt 18 firmly attached, thus integral part of the piston carrier 11 and is approximately parallel to Longitudinal axis of the shaft 16 extends. On the bolt 18 is the connecting rod 14th by means of a bearing 19, z. B. a ball bearing, pivoting, in particular rotatable, couplable. The bearing 19 is firmly seated with its inner ring on the bolt 18, while the outer ring rotatably in the connecting rod 14th is included.

The piston carrier 11 contains in a central region 31, which is between two pistons 12, 13 extends, a freely movable recording of the connecting rod 14 sized gap 32 in which the connecting rod 14 is free to move is included. Here, the piston carrier 11 has two approximately longitudinal and to each other approximately parallel webs 33 and 34, which in the region of Pistons 12 and 13 are integrally united with these. Between the bridges 33 and 34, the gap 32 is formed and the connecting rod 14 is received. As Fig. 1 reveals, the gap 32 extends approximately within a plane 35, with a diametrical plane 36 of a piston 12 and one with this Diametral plane 36 of the other piston 13 aligned diametral plane 37 Aligns such that these levels 35 to 37 run in alignment. The level 35 essentially represents the longitudinal plane of symmetry of the piston carrier 11 That connecting rod 40 is placed in the space 32 so that it is in the substantially within this level 35 extends.

The connecting rod 14 is formed as a straight-line component, the connecting rod bearing 17 and Bearings 19 lie within a common longitudinal median plane, approximately with the Symmetrieebene of the piston carrier 11 coincides. The bolt 18 of Piston carrier 11 passes through the gap 32 transversely to the plane of symmetry 35th extending and is both ends in the transversely spaced ridges 33 and Received 34 of the piston carrier 11, in particular fixed. The Webs 33, 34 of the piston carrier 11 together with the pin 18 a Storage fork for the local end of the connecting rod 14, which was added in between and is held with the bearing 19 on the bolt 18, while the rest Part of the connecting rod 14 extends freely into the gap 32 inside. Through this special arrangement of the center-placed connecting rod 14, the bearings 17 and 19 burdened only with forces acting within the level 35 forces and not with any transverse forces. Because of that, the life is the bearings 17, 19 increases and also improves the efficiency. Advantageous is also that thereby also in the area of the bearings 17, 19 a noise reduction is reached.

The connecting rod bearing 17 is seated with its inner ring firmly on the eccentric 15. Im Course of the connecting rod 14 between the connecting rod bearing 17 and the coupling point with the bearing 19 is at least one vibration damping device 20th arranged in the region of the coupling point, z. B. of the local warehouse 19, and / or - as shown in Fig. 1 - in the region of the connecting rod bearing 17th is provided. This vibration damping device 20 has a vibration-damping bearing seat 21, which is a vibration-damping Layer 22 which is elastic, in particular rubber, Art rubber od. Like. Is formed. The vibration damping layer 22 has z. B. a hardness of about 80 ° Shore A.

In the embodiment shown in FIG. 1 and 2, the vibration damping bearing seat 21 a rubber spring on, while at another, not shown embodiment, the bearing holder 21 alone may be formed from the vibration damping layer 22. In this case is the connecting rod bearing 17 with its outer ring directly into the vibration damping Embedded layer 22, which in turn in a receptacle 23, in particular bore, is arranged in the connecting rod 14. In the training of Bearing seat 21 as shown rubber spring has these two concentric Rings 24 and 25, in particular of metal, and between the rings 24, 25 the annular extending layer 22, the z. B. as vulcanized rubber layer is trained. By means of the vibration-damping bearing seat 21 is the Pleuellager 17 embedded in the receptacle 23 of the connecting rod 14. The order the vibration damping device 20 at this point has as proved particularly advantageous. The vibration damping layer 22 may with Advantage be designed so that these in the circumferential direction a greater elasticity as in the radial direction.

In another embodiment, not shown, and the bearing 19 the coupling point by means of a vibration-damping bearing mount analog the bearing seat 21 in the connecting rod 14 and / or in a part of the piston 10, z. B. of the piston carrier 11, be embedded.

Due to the arrangement of the at least one vibration damping device 20 a very good damping of vibrations is achieved, the arise during the movement process of the piston 10 and over the Connecting rod 14 and the bearings 17 and 19 are transmitted and the other by the drive device not shown further and the eccentric 15 arise. Such vibrations not only burden the bearings but lead to disturbing noises, which are especially unpleasant make noticeable if so trained compressors z. B. in vehicles are installed. Due to the vibration damping device 20 are so Such vibrations in the region of the bearing seat 21 of the layer 22nd recorded and muted, creating a further noise reduction, and Although many times, is achieved.

Claims (17)

A double piston for a compressor, comprising an elongate piston carrier (11) having a piston (12, 13) at each end, and a connecting rod (14) extending approximately parallel to the piston carrier (11) and engaging with the piston carrier (11) a bearing (19) is rotatably coupled and at a distance from the coupling point by means of a connecting rod bearing (17) on an eccentric (15) of a drive device is storable,
characterized in that the piston carrier (11) in a central region (31) extending between the two pistons (12, 13) includes a freely movable receptacle of the connecting rod (14) sized intermediate space (32) in which the connecting rod (14) is recorded freely movable. Double piston according to claim 1,
characterized in that the piston carrier (11) has two approximately longitudinally and mutually approximately parallel webs (33, 34), between which the intermediate space (32) formed and the connecting rod (14) is accommodated. Double piston according to claim 1 or 2,
characterized in that the intermediate space (32) extends approximately within a plane (35) which is aligned with a diametral plane (36) of one piston (12) and a diametral plane (37) of the other piston (13) which is in alignment with the latter represents the longitudinal plane of symmetry of the piston carrier (11), and that the connecting rod (14) extends substantially within this plane (35). Double piston according to one of claims 1 to 3,
characterized in that the connecting rod (14) is designed as a rectilinear component whose connecting rod bearing (17) and bearing (19) lie within a common longitudinal center plane which coincides approximately with the plane of symmetry (35) of the piston carrier (11). Double piston according to one of claims 1 to 4,
characterized in that the connecting rod (14) with the bearing (19) on a bolt (18) of the piston carrier (11) is held and the bolt (18) passes through the intermediate space (32) transversely to the plane of symmetry (35) and with both Ends in the transversely spaced webs (33, 34) of the piston carrier (11) is received, in particular fixedly arranged. Double piston according to claim 5,
characterized in that the spaced lands (33, 34) of the piston support (11) together with the bolt (18) form a bearing fork for one end of the connecting rod (14) received therebetween and connected to the bearing (19) on the bolt (14). 18) is held while the remaining part of the connecting rod (14) extends freely into the intermediate space (32). Double piston according to one of claims 1 to 6,
characterized in that a vibration damping device (20) is arranged in the connecting rod between the connecting rod bearing (17) and the coupling point (bearing 19). Double piston according to claim 7,
characterized in that the vibration damping device (20) in the region of the connecting rod bearing (17) is provided. Double piston according to claim 7 or 8,
characterized in that the vibration damping device (20) has a vibration-damping bearing mount (21). Double piston according to claim 9,
characterized in that the vibration-damping bearing mount (21) has a vibration-damping layer (22). Double piston according to claim 10,
characterized in that the vibration-damping layer (22) of the bearing receptacle (21) is elastic, in particular of rubber, synthetic rubber od. Like. Is formed. Double piston according to one of claims 1 to 11,
characterized in that the vibration-damping layer (22) has a hardness of 80 ° Shore A. Double piston according to one of claims 1 to 12,
characterized in that the bearing receptacle is formed solely from the vibration-damping layer (22). Double piston according to one of claims 1 to 13,
characterized in that the vibration-damping bearing mount (21) has a rubber spring. Double piston according to claim 14,
characterized in that the rubber spring comprises two concentric rings (24, 25), in particular of metal, and between the rings (24, 25) an annular, z. B. vulcanized, rubber layer (22). Double piston according to one of claims 1 to 15,
characterized in that the connecting rod bearing (17) by means of the vibration-damping bearing mount (21) in the connecting rod (14) is embedded. Double piston according to one of claims 1 to 16,
characterized in that the bearing (19) of the coupling point by means of the vibration-damping bearing mount (21) in the connecting rod (14) and / or in a part of the piston carrier (11) is embedded.

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