The present invention relates to a device for coupling a piston to an annular disk, in particular to a swash/wobble plate or to a swash ring of the power unit of a reciprocating piston machine, preferably of a compressor of the air-conditioning system of a motor vehicle, having a piston bridge assigned to the piston and sliding shoes acting between the annular disk and the piston bridge, the piston bridge at least partially embracing, respectively overlapping the annular disk and engaging slidingly via the sliding shoes with the annular disk.
The device of the species is typically used in reciprocating piston machines which have been known for many years in a wide variety of designs and for a wide variety of intended applications. A reciprocating piston machine of this kind may be a compressor, thus, for example, a compressor for the air conditioning system of a motor vehicle. Compressors of this kind are also usually referred to as air-conditioner compressors, and include a housing, which contains an externally driven compressor unit or pump unit. The compressor unit designed, for example, as an axial piston machine, includes, in turn, a plurality of pistons which are able to reciprocate within a cylinder block. In response to the rotation of a wobble plate mostly designed as an annular disk, or in response to the slewing motion of a corresponding swash plate, the pistons are reciprocated. The housing is typically closed.
Swash-plate compressors or swash-ring compressors are well known in a wide variety of designs. In this connection, reference is made merely exemplarily to the German Patent Application DE 44 41 721 A1, as well as to the German Patent DE 100 10 142 C2.
With respect to other design details, reference is made to the German Patent DE 197 49 727 C2.
In the case of the reciprocating piston machine known from the German Patent DE 197 49 727 C2, a circular, annular swash plate, also referred to as swash ring, is provided, whose inclination relative to the machine shaft is adjustable. The swash plate is driven to rotate by the machine shaft. This is accomplished via a sliding member that is axially guided on the machine shaft as well as via a driving pin that is configured at a distance from the machine shaft. The pistons have articulated connections with which the swash plate engages slidingly.
Specifically, the known reciprocating piston machine includes a power unit having a plurality of correspondingly driven pistons, the pistons being guided in cylinder bores and following the slewing/wobble motion of the annular disk via special coupling elements and executing their stroke in this manner.
The device of the species used in the known reciprocating piston machine is typically fabricated from relatively thick sheet metal which results directly in a considerable unit size in order to allow a large enough clearance space for the shoes and swash ring. Moreover, to enlarge the clearance space for the shoes and swash ring, it is not unusual for stamped formations to be required which outwardly displace the piston bridge material, thereby again enlarging the installation space, namely by radially enlarging the same. This is all completely diametrically counter to miniaturization, i.e., a reduction in installation space, that is always to be aspired to today.
It is, therefore, an object of the present invention to design and refine a device for coupling a piston to an annular disk, in particular to a swash/wobble plate or to a swash ring of the power unit of a reciprocating piston machine, preferably of a compressor of the air-conditioning system of a motor vehicle, in a way that will make it possible to realize a smallest possible installation space, while ensuring adequate strength and providing a large enough clearance space for the shoes and the swash ring. A further object is to provide a reciprocating piston machine equipped with such a device.
In accordance with the present invention, the device includes a piston bridge is designed to have two layers at least on the side facing the piston.
The present invention has recognized that thick sheet metals are not the only way to achieve a sufficient flexural strength. Rather, an adequate flexural strength is also attainable for the piston bridge by designing it to have two layers, at least on the side facing the piston, for example, on the pressure side, namely by using substantially thinner sheet-metal panels which, together, provide an adequate flexural strength.
By using at least two sheet-metal panels to realize a two-layer sliding shoe design, the further advantage may be derived that each of the sheet-metal panels is able to achieve substantially narrower bending radii, thereby providing a clearance space for the shoes and the swash ring that extends further within the interior of the sliding shoe. Moreover, outward formations, respectively stamped-out formations are able to be realized in the inner sheet-metal layer, thereby making it possible to routinely avoid a stamping process involving the outward displacement of material. An enlargement of the installation space may likewise be thereby avoided.
The piston bridge material may be advantageously realized as two-layer sheet metal, it also being perfectly conceivable to design the piston bridge using three- or multi-layer sheet metals, and, in fact, in accordance with the specific requirements.
Specifically, the piston bridge may include an inner shell and an outer shell, it being possible for one or more intermediate shells to be provided between the inner shell and the outer shell. The intermediate shells, in turn, may be designed as partial shells or as complete shells. By employing suitable structural design measures, the individual regions of the piston bridge may be formed with different thicknesses, and with different outward formations, recesses, stamped-out formations, etc.
The outer shell extends in an especially advantageous manner from the side facing the piston, i.e., from the piston, by way of a side surface up to or over the side of the piston bridge facing away from the piston. Such a design has the significant advantage that the piston bridge on the pressure side, for example, on the side facing the piston, is designed to have at least two layers. On the suction side, for example, on the side facing oppositely to, respectively away from the piston, a single-layer design of the piston bridge suffices, thereby making it possible to reduce the weight of the piston bridge.
Moreover, it is possible that the inner shell and, as the case may be, the outer shell be provided on opposite sides with outwardly stamped or bent regions of a pressure cup (on the side facing the piston) and of a suction cup (on the side facing away from the piston), which are used for accommodating the sliding shoes. The interaction of the pressure and suction cups with the sliding shoes renders possible an ideal articulated connection, the pistons engaging with the swash plate via the articulated connections.
It was already previously indicated that the region of the suction cup, for example, the suction side of the sliding shoe, may have a single-layer design, the suction cup preferably being formed by the inner shell.
Moreover, it is conceivable for the inner shell to be provided, preferably in one side surface, with a recess, preferably a stamped-out formation, which enlarges the space within the piston bridge and thus the clearance space for the annular disk and/or the sliding shoes by the wall thickness of the inner shell. A significant advantage of this measure is that the need for stamping the entire piston bridge, which entails an outward material displacement, is eliminated, thereby substantially avoiding an unwanted enlargement of the installation space in the radial direction.
The two or more shells may be configured to virtually engage positively with one another. It is also conceivable in this context for a type of non-positive force-locked connection to be realized between the two shells, so that the shells are mechanically interconnected due to a material-specific prestressing. It is alternatively or additionally conceivable for the shells to be joined to one another using bonding techniques or by rivets.
In an especially advantageous manner, the shells are joined to one another by welding. To facilitate a welded connection of this kind, in particular to facilitate the connection produced by resistance welding, at least one of the shells to be joined, preferably the inner shell, has punctiform or linear raised parts, preferably produced using stamping techniques, which facilitate the resistance welding relative to the opposite shell. The space formed in the process between the shells allows a stamping of the inner shell to extend further, thereby enlarging the space within the piston bridge and thus enlarging the clearance space for the shoes and/or the swash ring.
It is also noted that the piston bridge may be welded via its outer shell to the piston, any other conceivable joining technique being possible. The piston may be designed as a hollow body in the sense of a sleeve that is closed at the extremity, the outer shell of the piston bridge being suited for sealing the sleeve that forms the piston.
The teaching of the present invention may be advantageously embodied and refined in various ways. The following description of two preferred exemplary embodiments of the present invention are provided in the drawing. In conjunction with the explanation of the preferred exemplary embodiments of the present invention which make reference to the drawing, generally preferred embodiments and refinements of the teaching are also elucidated. In the drawing,
In accordance with the present invention, piston bridge 3 is designed to have two layers, at least on the side facing piston 1, for example, on pressure side 5.
Specifically, in the exemplary embodiment shown in
Also discernible in
Also discernible in
As already previously explained, the region of suction cup 10 has a single-layer design, namely due to only inner shell 6 being provided there. On the opposite side, for example, on pressure side 5, pressure cup 9 is formed by two layers, namely both by inner shell 6, as well as by outer shell 7, in order, namely, to be able to absorb forces in this way.
In addition,
In addition,
In a schematic view,
Specifically, inner shell 6 has punctiform or linear raised parts 13 which extend in the direction of outer shell 7. These raised parts 13, which, for example, may be pre-stamped, form what are generally referred to as flow sites for the resistance welding, thereby facilitating this joining technique.
Moreover, the present invention encompasses a reciprocating piston machine, as is known, for example, from the German Patent DE 197 49 727 C2. However, in this case, it is equipped with a device in accordance with the above explanations.
Finally, it is noted that the exemplary embodiments discussed above are merely intended to illustrate the claimed teaching, but not to limit it to such embodiments.
Number | Date | Country | Kind |
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10 2006 035 149 | Jul 2006 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2007/001078 | 6/19/2007 | WO | 00 | 8/17/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/014737 | 2/7/2008 | WO | A |
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