DE102016001595A1 - Reciprocating piston engine, in particular two- or multi-stage piston compressor, compressed air supply system, compressed air supply system and vehicle, in particular passenger car with a compressed air supply system - Google Patents

Abstract

The invention relates to a reciprocating piston engine (400), in particular a two-stage or multi-stage piston compressor (400), comprising: - at least one first cylinder (420) and at least one first piston (K1) associated with the first cylinder (420) and at least one second cylinder ( 410) and at least one second piston (K2) assigned to the second cylinder (410), the pistons (K1, K2) being deflected in a respective cylinder stroke space (411, 421) of the respective cylinder (410, 420) during operation, - one operable crankshaft (430) having an eccentric crankshaft journal (432) and a drive shaft coupling (431) adapted to couple a drive shaft (501) of a drive motor (M) for driving the crankshaft (432), - one for deflecting the first piston (K1) formed first connecting rod (P1), - designed to deflect the second piston (K2) second connecting rod (P2), and - a fixedly connected to the first connecting rod (P1) L Agerbolzen (L2B), by which the second connecting rod (P2) is rotatably movable, wherein the first connecting rod (P1) by means of at least one first connecting rod bearing (L1) directly on the crankshaft journal (432) is mounted and by means of the eccentric crank journal (432) is movable and the second connecting rod (P2) is movable by means of the bearing bolt (L2B) and wherein the second connecting rod (P2) has two connecting rod parts (P2a, P2b) with a clearance (ZR) between them (P2a, P2b), at least one connecting rod part (P1a ) of the first connecting rod (P1) in the intermediate space (ZR) is arranged and wherein between the bearing pin (L2B) and each of the two connecting rods (P2a, P2b) of the second connecting rod (P2) at least one second connecting rod bearing (L2) is arranged.

Description

The invention relates to a reciprocating engine, in particular a two- or multi-stage piston compressor, according to the preamble of claim 1. Furthermore, the invention relates to a compressed air supply system and a compressed air supply system and a vehicle, in particular a car, with a reciprocating engine, in particular with a reciprocating compressor.

A compressed air supply system is used in vehicles of all kinds, in particular for supplying an air spring system or air spring systems of a passenger car or a commercial vehicle with compressed air. Air suspension systems may also include level control devices, with which the distance between the vehicle axle and vehicle body can be adjusted. An air spring system of a pneumatic compressed air supply system mentioned at the beginning comprises a number of air bellows pneumatically connected to a common line (gallery) which, with increasing filling, can lift the vehicle body and lower it with decreasing filling. Such a system is used for example in an off-road vehicle and a sports utility vehicle (SUV) or a utility or passenger transport vehicle.

To ensure long-term operation of the compressed air supply system, this has an air dryer with which the compressed air is to be dried. As a result, the accumulation of moisture in the compressed air supply system is avoided, which can otherwise lead to valve-damaging ice crystals and other undesirable effects in the compressed air supply system and in the pneumatic system at relatively low temperatures. An air dryer has a desiccant, usually a granular bed, which can be traversed by the compressed air, so that the granular bed - at relatively high pressure - can absorb moisture contained in the compressed air by adsorption. It has often proven useful to accommodate the dry granules in a dryer cartridge having a dryer bed for guiding a flow of compressed air.

A compressed air supply system for use in a pneumatic compressed air supply system with a pneumatic system, for example with an air spring system described above, is operated with compressed air from a compressed air supply, for example within a pressure level of 5 bar to 20 bar. The compressed air is provided by means of an air compressor (compressor), in this case with a reciprocating engine, preferably with a two-stage or multi-stage piston compressor, the compressed air supply available.

In a compressed air supply system for a compressed air supply system in a vehicle, the compressed air supply supplied by the air compressor is pneumatically connected on the one hand to supply the pneumatic system with a compressed air connection and on the other hand pneumatically connected to a vent connection. Via a vent valve arrangement, the compressed air supply system and / or the pneumatic system can be vented by venting air to the vent port.

The drive of the reciprocating engine in the air compressor (compressor) of the compressed air supply is carried out regularly with a drive motor, the drive power via a crankshaft and one or more connecting rods to one or more pistons of the preferably two- or multi-stage piston compressor passed - a piston runs sealed in operation in a cylinder , The drive of the reciprocating engine in the air compressor (compressor) of the compressed air supply can also be done for example with a belt drive.

In this way, sucked ambient air or compressed air supplied from another source of compressed air is compressed. Basically, so-called TWIN reciprocating compressors have proven themselves; d. H. Two-stage piston-type compressors whose two pistons are driven by two connecting rods assigned to each of these, which in turn are aligned exactly along a cylinder axis which is preferably aligned exactly parallel and center-symmetrical to cylinder running surfaces in the cylinder stroke space for the piston.

Depending on the requested dynamics and pressure load such or other two-stage or multi-stage compressor in operation develop increasing operating noise, which - as it turns out - significantly by a structure-borne sound transmission through the connecting rod u. a. may be caused in the drive motor of the compressor or its housing. It is desirable to realize an improved acoustics and a nevertheless reliable connecting rod drive in a compressor in the form of said reciprocating piston engine. This should be sufficient in particular for a particularly low noise level in the car area.

DE 10 2004 020 104 discloses approximately a TWIN compressor with symmetrically mounted double piston for a compressor, with an elongate piston carrier having a piston at each end, and with a connecting rod extending approximately parallel to the piston carrier, which is rotatably mounted by means of a bearing on a pin of the piston carrier and is mounted at a distance thereof by means of a connecting rod bearing on an eccentric drive means. The piston carrier contains in a middle Area that extends between the two pistons, a dimensioned for freely movable recording of the connecting rod gap in which the connecting rod is received freely movable.

It turns out, as recognized by the invention, that solutions of this kind run the risk of a comparatively high sound level and m. E. To cause structure-borne sound transmissions through the connecting rod drive in the compressor drive motor and thus also to the outside.

At this point, the invention begins, the object of which is to provide a reciprocating engine, in particular a two- or multi-stage piston compressor, preferably TWIN compressor, and a compressed air supply system for operating a pneumatic system with a compressed air flow, by means of improved acoustics and yet reliable Pleueltrieb in a reciprocating compressor is to be realized. This should be particularly suitable for noise level requirements in the car sector. In particular, as part of an acoustic improvement, structure-borne noise emissions of a connecting rod drive into adjacent, radiating components, such as electric motor, crank mechanism or the like components of an air compressor (compressor) are to be reduced. In particular, the compressed air supply system should be relatively compact. The object of the invention is also to provide a corresponding compressed air supply system and a vehicle with the compressed air supply system, in particular for an air spring system.

The object with regard to the reciprocating engine is achieved with a reciprocating engine, in particular with the two- or multi-stage reciprocating compressor, preferably TWIN compressor, of claim 1.

• – wenigstens einen ersten Zylinder sowie wenigstens einen dem ersten Zylinder zugeordneten ersten Kolben und wenigstens einen zweiten Zylinder sowie wenigstens einen dem zweiten Zylinder zugeordneten zweiten Kolben, wobei im Betrieb die Kolben in einem jeweiligen Zylinderhubraum des jeweiligen Zylinders ausgelenkt werden,
• – eine im Betrieb antreibbare Kurbelwelle mit einem exzentrischen Kurbelwellenzapfen und einer Antriebswellen-Kopplung, die zum Ankoppeln einer Antriebswelle eines Antriebsmotors zum Antreiben der Kurbelwelle ausgebildet ist,
• – ein zum Auslenken des ersten Kolbens ausgebildetes erstes Pleuel,
• – ein zum Auslenken des zweiten Kolbens ausgebildetes zweites Pleuel, und
• – einen fest mit dem ersten Pleuel verbundenen Lagerbolzen, um den das zweite Pleuel drehbeweglich ist,

wobei das erste Pleuel mittels wenigstens einem ersten Pleuellager direkt am Kurbelwellenzapfen gelagert ist und mittels dem exzentrischen Kurbelwellenzapfen bewegbar ist und das zweite Pleuel mittels dem Lagerbolzen bewegbar ist.This indicates:

• At least one first cylinder and at least one first piston assigned to the first cylinder and at least one second cylinder and at least one second piston assigned to the second cylinder, the pistons being deflected in a respective cylinder stroke space of the respective cylinder during operation,
• An operationally drivable crankshaft having an eccentric crankshaft journal and a drive shaft coupling adapted for coupling a drive shaft of a drive motor for driving the crankshaft,
• A first connecting rod designed to deflect the first piston,
• - A designed for deflecting the second piston second connecting rod, and
• A bearing bolt fixedly connected to the first connecting rod, about which the second connecting rod is rotatable,

wherein the first connecting rod is mounted by means of at least one first connecting rod bearing directly on the crankshaft journal and by means of the eccentric crankshaft journal is movable and the second connecting rod by means of the bearing pin is movable.

According to the invention, it is provided that
the second connecting rod has two Pleueiteile with a gap between them, wherein at least one Pleuelteil of the first connecting rod is arranged in the intermediate space and
wherein between the bearing pin and each of the two Pleueiteile the second connecting rod at least one second connecting rod bearing is arranged.

A firm connection is possible, for example, by a press connection. Direct bearing means that the connecting rod is moved directly via the connecting rod bearing through the crankshaft journal.

• – eine Lufttrockneranordnung in einer Pneumatikhauptleitung, die eine Druckluftzuführung von einem Luftverdichter und einen Druckluftanschluss zu der Pneumatikanlage pneumatisch verbindet, und
• – eine an die Pneumatikhauptleitung pneumatisch angeschlossene Ventilanordnung zur Steuerung der Druckluftströmung und einen Lufttrockner in der Pneumatikhauptleitung, wobei
• – an die Druckluftzuführung ein Luftverdichter mit einer Hubkolbenmaschine, insbesondere ein zwei- oder mehrstufiger Kolbenkompressor, vorzugsweise TWIN-Kompressor, insbesondere der Ansprüche 1 bis 13 angeschlossen ist.

The task with regard to the compressed air supply system is achieved with a compressed air supply system of claim 14. A compressed air supply system for operating a pneumatic system, in particular an air spring system of a vehicle, preferably a passenger car, with a compressed air flow, has:

• An air dryer arrangement in a pneumatic main line which pneumatically connects a compressed air supply from an air compressor and a compressed air connection to the pneumatic system, and
• - A pneumatically connected to the pneumatic main valve assembly for controlling the flow of compressed air and an air dryer in the pneumatic main, wherein
• - To the compressed air supply an air compressor with a reciprocating engine, in particular a two- or multi-stage piston compressor, preferably TWIN compressor, in particular of claims 1 to 13 is connected.

The task concerning the compressed air supply system is achieved with a compressed air supply system of claim 15. The invention also leads to a vehicle, in particular a passenger vehicle, of claim 16.

A compressed air supply system with a pneumatic system and with a compressed air supply system is used for operating the pneumatic system with a compressed air flow, in particular an air spring system of a vehicle, preferably a passenger car, wherein the pneumatic main line pneumatically connects a compressed air supply from an air compressor with a reciprocating engine, in particular a two- or multi-stage reciprocating compressor, preferably TWIN compressor according to one of claims 1 to 13 and a compressed air connection to the pneumatic system.

A vehicle, in particular a car, is provided with a pneumatic system, in particular an air suspension system, and a compressed air supply system according to claim 14 for operating the pneumatic system with a compressed air flow.

A cylinder axis is aligned substantially symmetrically with respect to cylinder running surfaces for the pistons in the Zylinderhubräumen the at least one cylinder. A cylinder axis with cylinder strokes aligned therewith is to be understood in particular as meaning that the cylinder running surfaces on the cylinder stroke spaces of a cylinder for the piston are exactly parallel and symmetrical to the cylinder axis.

Preferably, the eccentric crankshaft journal - in particular also the drive shaft coupling - is aligned parallel to a shaft axis oriented perpendicular to the cylinder axis; d. H. that the crankshaft journal and / or a connecting rod bearing surrounding it is perpendicular to the cylinder axis.

The invention is based on the consideration that, depending on the requested dynamics and pressure load in an air compressor, a two- or multi-stage compressor, in particular a two-stage TWIN compressor or other reciprocating engine operating noise increasingly developed during operation, which - as it turns out - mainly by a structure-borne sound transmission can be caused by the connecting rod drive in the compressor drive motor. The structure-borne sound excitations lead to higher airborne sound excitations of the entire system, d. H. the reciprocating engine and the components or parts associated with it. It therefore occurs in the current arrangement of plain bearings and needle bearings between the first connecting rod and bearing pin high noise. It turns out, as recognized by the invention, that the operating noise is partly due to constructions requiring a large amount of conrod bearing play in the prior art, which can cause a tilting or entanglement of the connecting rods against each other during operation. The common arrangement offers only a small guide, whereby the parallelism of all bearing axles at different loads can not be ensured. This can lead, among other things, to striking camps, which in particular unfold an unacceptable psychoacoustic effect. Furthermore, the wear is increased by the tilting movements.

The invention has now recognized that by the arrangement of two second connecting rod bearings on two connecting rods of the second connecting rod, an improved acoustics is to be realized in a compressor; also with a low noise development which is acceptable in particular for a passenger car sector. Moreover, the concept of the present invention is likewise preferred for a commercial vehicle (commercial vehicle) or passenger transport vehicle, in particular if the compressed air supply system is designed for comparatively high pressure amplitudes.

As recognized by the invention, see previous solutions - in simplified terms - only a ball bearing or plain bearing for storage between the first connecting rod and the bearing pin before, d. H. a simple storage. The invention has further recognized that a double bearing around the bearing pin leads to improved guidance and resulting lower tilting of the connecting rods. Overall, the bearing clearance can be significantly reduced. This allows a reduction in structure-borne sound excitations and therefore also leads to a reduction in noise in the reciprocating engine and thus in the entire system, for example in the vehicle such as a car during operation.

The structure-borne sound excitation can be reduced in particular by the fact that lower impact velocities occur in the power transition points. The connecting rod bearings are loaded alternately radially to train and pressure. Between the maxima of the load there is a force-free time, in which the conrod bearing clearance is bridged. The larger the conrod clearance, the more speed or momentum is present in the system when reaching the opposite pressure or Zugpunktes.

The invention provides that in each case a ball bearing or sliding bearing are arranged on two connecting elements separated by a gap of the second connecting rod, in order to allow better guidance. Furthermore, the double storage allows to reduce the frictional heat. The frictional heat is distributed in this case on two connecting rod bearings, which can dissipate the heat. By dividing the heat sources at the connecting rod bearings on two separate from each other by a gap connecting rod parts of the second connecting rod, the amount of heat to be dissipated per connecting rod bearing. This makes it possible to use Kunststoffpleuel.

The invention makes it possible in particular to optimize the acoustic behavior, in particular of a two-stage TWIN compressor, since the tilting movement of the towed piston or Pleuels can be reduced. This also leads to a reduction of wear, especially of compressor elements. Furthermore, a bearing load in the engine can be reduced by the tilting movement is reduced and thereby fail the attacks of the connecting rods.

Furthermore, the double bearing allows an increase or extension of the effective lever arm, in particular with respect to the tilting of the connecting rod. For the same radial clearance, therefore, lower tilting games occur and, with the same tilting play, larger radial clearances are permissible. This makes it possible to use simple and inexpensive storage variants, in particular plain bearings.

The invention makes it possible to use two second connecting rod bearings in the form of plain bearings. As a result, the support surface can be increased, whereby less surface load occurs. The use of plain bearings can also be cheaper and quieter than the use of a rolling bearing, since no rolling noise by rolling elements such as rollers, rollers, needles or the like occur.

However, the reciprocating piston engine described here, in particular the reciprocating compressor, for use in a pneumatic compressed air supply system can in principle also be used in other fields of application, especially where - as in the case of the aforementioned compressed air supply systems - comparatively high pressure amplitudes are to be achieved flexibly and dynamically. In particular, the reciprocating engine can be used in a compressor for a car suspension control. Furthermore, the reciprocating engine, in particular the reciprocating compressor in a multi-stage compressor with at least two compressor stages, which operate on the drag piston principle, find use. The invention may further find use in a reciprocating compressor for supplying air spring suspensions and lift axles, especially in passenger car vehicles.

Advantageous developments of the invention can be found in the dependent claims and specify in particular advantageous ways to realize the above-described concept within the scope of the task and with regard to further advantages.

A connecting rod can be rigid without spherical plain bearings or also articulated, in particular with spherical plain bearings. A piston may be held on the connecting rod, held or integrally formed on the connecting rod. The piston is preferably integrally formed on the connecting rod, firmly connected or held by a piston holder.

In a particularly preferred embodiment, the second connecting rod is mounted indirectly by means of the two second connecting rod bearings and the bearing pin on the crankshaft journal. Indirect bearing means that the connecting rod is moved by means of another component (for example, preferably the first connecting rod or the first connecting rod and the bearing pin), that is to say indirectly, through the crankshaft journal, but is not mounted directly on it.

In the context of a particularly preferred development, the first connecting rod can be moved directly by means of the eccentric crankshaft journal and the second connecting rod can be moved indirectly by means of the eccentric crankshaft journal, in particular directly by means of the first connecting rod. Preferably, in this development, the second connecting rod (as Schlepppleuel) from the first connecting rod (as drive connecting rod) movable, wherein the first connecting rod is moved directly from the crankshaft journal. An aforementioned development has proved particularly useful for the realization of a two-stage reciprocating compressor, which may also be referred to as TWIN compressor, namely with two opposite pistons along a cylinder axis.

Within the scope of a particularly preferred development, at least one of the connecting rod bearings has a sliding bearing or a roller bearing. In particular, the connecting rod bearing may have a needle bearing, a ball bearing or a barrel bearing. The first and the second connecting rod bearings may have plain bearings. The first and the second connecting rod bearings may also have rolling bearings. It may have the first connecting rod bearing a sliding bearing and one or both of the second connecting rod bearing a rolling bearing. It may also have the first connecting rod bearing a rolling bearing and one or both of the second connecting rod bearing a plain bearing. The first connecting rod bearing is preferably a roller bearing, in particular a ball bearing. In a development, the second connecting rod bearing plain bearings. The plain bearings can be designed for example in the form of a plain bearing bush or the like.

Within the scope of a further particularly preferred development, at least one of the connecting rod bearings has an outer ring and / or an inner ring of a roller bearing. Preferably, the rolling bearing is a needle bearing. The connecting rod bearing can therefore only have an outer ring, only an inner ring or both an outer ring and an inner ring. Outer ring and inner ring of the rolling bearing can be, for example, a needle sleeve, a needle bushing, a metal ring or the like. The outer ring preferably has rollers or needles, rollers or the like on its inner surface and the inner ring preferably has rollers or needle, rollers or the like on its outer surface. Both the outer ring, as well as the Inner ring can also be rings without rollers. Outer ring and inner ring of the bearing can be, for example, needle rings, in which case both outer ring, and inner ring rollers or needles, rollers or the like, which are adapted to run in operation on a surface. The rollers or needles, rollers or the like of the needle rings pierce both the outer surface and the inner surface of the outer ring and inner ring, so that the rollers, or needles, rollers or the like run in operation on an opposite inner surface and outer surface. When the connecting rod bearing outer ring and inner ring, the outer ring and the inner ring of the rolling bearing are preferably arranged concentric with each other, so that in operation rollers, such as needles of the outer ring on an outer surface of the inner ring run and rollers, such as needles of the inner ring on an inner surface of the Outer ring run. It can also be performed as a ring without rolling one of the rings, so outer ring or inner ring, so that it essentially serves as a running surface for the rollers of the other ring. Preferably, the ring, if it is designed without rollers, made of a metal, in particular steel.

In the context of a further preferred development, the second connecting rod bearings are ball bearings. In the context of a further development, the two second connecting rod bearings can be designed as a needle bearing without cage, d. H. in the form of two nested wreaths. These are then arranged between bearing pin and second connecting rod. The rollers or needles of the needle rings then run on each of the other needle ring and either the bearing pin or a Pleuelinnenoberfläche the second connecting rod. An embodiment of the needle bearing without a cage can thus increase the bearing surface. In the context of a further preferred development, the second connecting rod bearing plain bearings.

In a preferred development, a maximum deflection angle of the deflection of the connecting rods between respective longitudinal axes of the connecting rods is at most 14 °, for example at most 10 ° and preferably approximately 7 °. The maximum deflection angle of the connecting rod can be, for example, a maximum of +/- 7 °. The maximum deflection angle can be limited by various components of the reciprocating engine. For example, the connecting rods can be designed and arranged relative to one another in such a way that the maximum deflection of the connecting rods is constructively limited to one another. This may, for example, be a consequence of at least one connecting rod part of the first connecting rod being arranged in a gap of the second connecting rod.

In the context of a further preferred development, the at least two second connecting rod bearings are arranged and configured such that, during operation, a tilting angle "α" of the first connecting rod perpendicular to the deflection of the connecting rod and parallel to a longitudinal axis of the bearing pin is less than 5 ° and, in particular, below 3 °. The tilt angle refers to a tilt of the connecting rod to each other, while the deflection angle of the connecting rod refers to a deflection of the connecting rod to each other. The limitation of the maximum deflection angle deflection of the connecting rod to each other is necessary in the context of the operation of the reciprocating engine and takes place in a direction oriented perpendicular to the longitudinal axis of the bearing pin direction. The occurring tilting of the connecting rod, however, leads to increased wear and increases the operating noise and should therefore be reduced. The tilting takes place in a direction oriented parallel to the longitudinal axis of the bearing pin. The fact that in each case a second connecting rod bearing is arranged on a respective connecting rod part of the second connecting rod, the tilting of the connecting rod can be reduced in comparison to a simple storage at the first connecting rod. On the one hand, this allows lower operating noise, since the lower connecting rod bearing play results in a lower velocity of attack in the force transfer points. On the other hand, this allows an increased life due to the lower wear.

In the context of a further development, it has proved to be advantageous that the first connecting rod is mounted directly on the crankshaft journal by means of the first connecting rod bearing and the first piston is held on the first connecting rod by means of a piston holder. At the second connecting rod of the second piston is formed and the second connecting rod is connected by means of the second connecting rod bearings and the bearing pin with the first connecting rod. In this case, the development of a Schleugg connecting rod with a molded piston and a drive connecting rod is realized with a piston held thereon. Basically, independently of this development, a piston formed on the connecting rod or a piston held on the connecting rod can be realized as required. For a Schlepppleuel formed with the (low-pressure) compressor stage of a TWIN compressor above all a molded piston has proven. For a (high-pressure) compressor stage of a TWIN compressor explained below, above all a drive connecting rod with a piston held thereon has proven itself.

In the context of a preferred constructive realization, the first connecting rod bearing can be realized as a ring-ball bearing, which is preferably formed in the form of a ring-ball bearing on the crankshaft journal, that is directly on the crankshaft journal. The first connecting rod bearing may also be a ring ball bearing and / or a spherical plain bearing.

As already mentioned above, a reciprocating piston engine has proven particularly useful as a reciprocating compressor with a two-stage compressor having first and second compressor stages for providing compressed air to a compressed air supply system. In particular, the two-stage compressor may be formed as a TWIN compressor. In particular, it is provided that the first connecting rod of the second, in particular (high-pressure) compressor stage is formed and the first connecting rod is mounted directly on the crankshaft journal by means of the first connecting rod bearing. Additionally or alternatively, it has proved to be advantageous that the second connecting rod of the first, in particular (low-pressure) compressor stage is formed and the second connecting rod is mounted by means of the second connecting rod bearings and the bearing pin on the first connecting rod.

One aspect of the invention relates to the use of the reciprocating piston engine, in particular of the reciprocating compressor in a compressor or air compressor for a car chassis control. Furthermore, one aspect of the invention relates to the use of the reciprocating engine in other compressors such as an air compressor in vehicles such as cars and commercial vehicles (NFZ), in electro-hydraulic power steering, as well as in a compressor for ABS / EBS hydraulic pumps. One aspect of the invention also relates to the use of the invention in electrical drives for vacuum pumps. The invention can also be used generally in piston connections application.

Embodiments of the invention will now be described below with reference to the drawing. This is not necessarily to scale the embodiments, but the drawing, where appropriate for explanation, executed in a schematized and / or slightly distorted form. With regard to additions to the teachings directly recognizable from the drawing reference is made to the relevant prior art. It should be noted that various modifications and changes may be made in the form and detail of an embodiment without departing from the general idea of the invention. The disclosed in the description, in the drawings and in the claims features of the invention may be essential both individually and in any combination for the development of the invention. In addition, all combinations of at least two of the features disclosed in the description, the drawings and / or the claims fall within the scope of the invention. The general idea of the invention is not limited to the exact form or detail of the preferred embodiments shown and described below or limited to an article which would be limited in comparison to the subject matter claimed in the claims. For the given design ranges, values within the stated limits should also be disclosed as limit values and be arbitrarily usable and claimable. Further advantages, features and details of the invention will become apparent from the following description of the preferred embodiments and from the drawing.

In detail, the drawings show in:

1 A pneumatic circuit for an embodiment of a compressed air supply system with connected pneumatic system in the form of an air spring system for a vehicle, wherein a shown in detail D two-stage piston compressor in an air compressor, the air spring system supplied with compressed air via an air dryer assembly and designed as a pilot-operated check valve assembly, which is switchable via a controllable solenoid valve;

2 for an air compressor, a reciprocating engine in the form of a two-stage reciprocating compressor with a first connecting rod for a first piston of a second (high pressure) stage and a second connecting rod of a first (low pressure) stage and with a first connecting rod bearing and two second connecting rod bearings;

3 a further embodiment of a reciprocating piston engine in the form of a two-stage reciprocating compressor with a first connecting rod for a first piston of a second (high pressure) stage and a second connecting rod of a first (low pressure) stage and with a first connecting rod bearing and two second connecting rod bearings in the form of ball bearings ;

4 : Another embodiment of a reciprocating piston engine in the form of a two-stage reciprocating compressor with a first connecting rod for a first piston of a second (high pressure) stage and a second connecting rod of a first (low pressure) stage and with a first connecting rod bearing and two second connecting rod bearings in the form of plain bearings ,

1 shows in detail D an air compressor with a reciprocating engine in the form of a two-stage reciprocating compressor 400 with a first compressor stage 401 and a second compressor stage 402 that has an engine 500 is driven as drive motor M.

Such a piston compressor 400 is preferred for pneumatic compressed air supply systems 1000 used like one in 1 is shown.

1 shows a pneumatic circuit diagram of a pneumatic compressed air supply system 1000 with a compressed air supply system 1001 With an air dryer arrangement 100 and a pneumatic system 1002 in the form of an air spring system. The compressed air supply system 1001 is used to operate the pneumatic system 1002 , The compressed air supply system 1001 has a previously mentioned compressed air supply 1 and a compressed air connection 2 to the pneumatic system 1002 on.

The compressed air supply 1 is present with an air supply 0 , one of the air supply 0 upstream air filter 0.1 and one of the air supply 0 via the air supply line 270 downstream of the engine 500 driven air compressor formed. The air compressor is here as an example of a reciprocating engine in the form of a double air compressor, namely a two-stage reciprocating compressor 400 with a first compressor stage 401 and a second compressor stage 402 and an unspecified connection of the compressed air supply 1 educated.

To the connection of the compressed air supply 1 closes in the pneumatic main 200 to the first part 201 the main pneumatic line, the connection of the drying tank 101 the air dryer arrangement 100 at. The air dryer of the air dryer arrangement 100 is still using the second part 202 the main pneumatic line for guiding a compressed air flow DL to the pneumatic system 1002 pneumatically connected.

In the in 1 shown main view is provided that a branch line 230 at the compressed air supply 1 from the pneumatic main 200 branches off and to a vent line 240 for venting to a vent port 3 Downstream venting filter 03.01 joined; the vent is by means of another branch connection 241 and a connection section 242 to the vent line 240 connected as well as to another vent line 260 over the branch connection 261 ,

The pneumatic main 200 thus pneumatically connects the compressed air supply 1 and the compressed air connection 2 , where in the main pneumatic line 200 the air dryer arrangement 100 and continue in the direction of the compressed air connection 2 a pilot operated check valve 311 and a first throttle 331 is arranged.

The pneumatically operated check valve 311 is present part of the directional control valve arrangement 310 , in addition to the unlockable check valve 311 a controllable vent valve 312 in series with a second throttle 332 in the vent line 230 having. The pneumatically operated check valve 311 is present also in a series connection with the first throttle 331 in the pneumatic main 200 arranged, the main pneumatic line 200 The only pneumatic line of the first pneumatic connection is that extending to the pneumatic system 1002 with another pneumatic line 600 continues. The series arrangement of first throttle 331 and pneumatically operated check valve 311 So is between the air dryer arrangement 100 and the compressed air connection 2 to the pneumatic system 1002 in the pneumatic main 200 arranged.

Next points the compressed air supply system 1001 one with the pneumatic main 200 and the vent port 3 and more filters 03.01 and / or muffler pneumatically connected second pneumatic connection; namely the aforementioned vent line 230 , The nominal diameter of the second throttle 332 is present above the nominal diameter of the first throttle 331 ,

The arranged in the second pneumatic connection vent valve 312 is present as a pneumatically operated check valve 311 separate 2/2 valve in the vent line 230 educated.

The controllable vent valve 312 is thus part of a valve arrangement as an indirectly switched relay valve 300 with a control valve 320 in the form of a 3/2-way solenoid valve. The control valve 320 can with one over an electrical control line 321 transmittable electrical control signal, in the form of a voltage and / or current signal to the coil 322 of the control valve 320 be controlled electrically. In this electrical control, the control valve 320 from the in 1 shown de-energized the pneumatic control line 250 interrupting position are transferred to a pneumatically open position in the on the pneumatic control line 250 from the pneumatic main line 200 derived pressure for pneumatic control of the controllable vent valve 312 as a relay valve is passed.

The controllable vent valve 312 is present additionally with a pressure relief 313 Mistake. The pressure limit 313 engages via a pneumatic control line in front of the vent valve 312 - specifically between second throttle 332 and bleed valve 312 - From a pressure which, when exceeding a threshold pressure, the piston 314 of the vent valve 312 against the force of an adjustable spring 315 lifts off the valve seat - so the controllable vent valve 312 even without control via the control valve 320 into the open position. In this way it avoids an unintentionally too high pressure in the pneumatic system 1000 arises.

The control valve 320 separates the control line in the presently closed state 250 and is over another vent line 260 with the vent line 240 for venting via the venting connection 3 pneumatically connected. In other words, a between vent valve 312 and control valve 320 lying line section 251 the control line 250 at the in 1 shown closed position of the control valve 320 with the further vent line 260 between control valve 320 and the vent port 3 connected. The further vent line 260 closes in the further branch connection 261 to the vent line 230 and the further vent line 240 at. Thus, these are in one between the other branch connection 261 and the vent port 3 lying portion of a vent line 240 merged.

About the control valve 320 So it can be at pending one of the main pneumatic line 200 or from the other pneumatic line 600 via the pneumatic control line 250 from the control terminal 252 derived control pressure the vent valve 312 under pressure of the piston 314 be opened.

The piston 314 is presently designed as a double piston, so that provided with particular advantage, the transfer of the control valve 320 in the - in the sense above - opened state not only to open the vent valve 312 leads, but also to unlock the pilot operated check valve 311 , In other words, the control valve is used 320 the solenoid valve assembly 300 for controlling the separately from the check valve 311 provided vent valve 312 as well as the check valve 311 , This leads to a two-sided pneumatic opening of the air dryer assembly 100 at the transfer of the control valve 320 in the open position. This further through the compressed air supply system 1001 Inmaceable operating position can be used during operation for bleeding the pneumatic system 1002 and at the same time for regenerating the air dryer assembly 100 be used.

In the 1 shown operating position of the compressed air supply system 1001 serves under flow of the check valve 311 in the forward direction, especially for filling the pneumatic system 1002 via the pneumatic main line 200 as well as the further pneumatic line 600 ,

The pneumatic system 1002 of the 1 in the form of an air spring system has in this case a number of four so-called bellows 1011 . 1012 . 1013 . 1014 on, which are each associated with a wheel of a passenger vehicle, not shown, and form an air spring of the vehicle.

Furthermore, the air suspension system has a memory 1015 for storing quickly available compressed air for the bellows 1011 . 1012 . 1013 . 1014 on. Those bellows 1011 to 1014 are each in one of a gallery 610 outgoing spring branch line 601 . 602 . 603 . 604 each a solenoid valve 1111 . 1112 . 1113 . 1114 upstream, which each as a level control valve to open or close one with a bellows 1011 to 1014 formed air spring serves. The solenoid valves 1111 to 1114 in the spring branch lines 601 to 604 are as 2/2-way valves in a valve block 1110 educated. A store 1015 is in a memory branch line 605 a solenoid valve 1115 in the form of a further 2/2-way valve upstream as a storage valve. The solenoid valves 1011 to 1015 are by means of the spring and storage branch lines 601 to 604 respectively. 605 to a common bus, namely the aforementioned gallery 610 and then to the other pneumatic line 600 connected. The gallery 610 is so over the pneumatic line 600 to the compressed air connection 2 the compressed air supply system 1001 pneumatically connected. In the present case are the solenoid valves 1111 to 1115 in a valve block 1010 arranged with the five valves. The solenoid valves are in 1 shown in a de-energized state - there are the solenoid valves 1111 to 1115 formed as normally closed solenoid valves. Other, not shown here modified embodiments can realize a different arrangement of the solenoid valves - it can also be less solenoid valves in the context of the valve block 1010 be used.

For filling the pneumatic system 1002 become the bellows 1011 to 1014 upstream solenoid valves 1111 to 1114 and / or the memory 1015 upstream solenoid valve 1115 brought into an open position.

Nevertheless, with the position closed, the solenoid valves 1111 to 1114 respectively. 1115 in the pneumatic system 1001 - Due to the present not unlocked check valve 311 - An operating position of the pneumatic system 1002 decoupled from the compressed air supply system 1001 possible. In other words, a cross-over of bellows 1011 to 1015 (eg in off-road operation of a vehicle) filling the bellows 1011 to 1015 from the store 1015 or a pressure measurement in the pneumatic system 1002 over the gallery 610 be made without the compressed air supply system 1001 is pressurized.

In particular, the air dryer assembly 100 due to the compressed air connection 2 for compressed air supply 1 locked check valve 311 and the closed control valve 320 Protected against unnecessary pressurization with compressed air. Advantageously, therefore, an admission of the Air dryer assembly 100 with compressed air not at every operating position of the pneumatic system 1002 advantageous. Rather, it is for an effective and fast regeneration of the air dryer plant 100 advantageous if this only in the case of a venting of the pneumatic system 1002 from the compressed air connection 2 for compressed air supply 1 is made with unlocked check valve 311 ,

For this purpose - as explained above - the control valve 320 brought into an open switch position, so that both the vent valve 312 opens as well as the check valve 311 is unlocked. A venting of the pneumatic system 1002 can over the first throttle 331 , the unlocked check valve 311 with regeneration of the air dryer assembly 100 and then on the second throttle 332 and the opened vent valve 312 for venting via the venting connection 3 respectively.

In other words, for simultaneous unlocking operation of the check valve 311 and for opening the venting valve 312 one from the control valve 320 pneumatically controllable control piston 314 as a double relay piston provided with a relay vent body 314.1 the bleeder valve and a Relaisentsperrkörper 314.2 for the pilot operated check valve 311 , The double relay piston clarifies the present principle for unlocking the check valve 311 and simultaneous actuation of the vent valve 312 over the two coupled actuators - namely on the Relaisentsperrkörper 314.2 and the relay vent body 314.1 - Which can be formed as a one-piece double relay body or in a modification as a separate body. In the context of a particularly preferred modification of a structural realization, the aforementioned actuating elements of the double relay piston can be formed as one-piece regions of a double relay piston.

2 now explains the details of the concept of the invention using the example of a reciprocating engine especially in the form of the two-stage reciprocating compressor 400 of the 1 ,

Referring to 2 shows this a reciprocating engine in the form of a double compressor according to the detail D of 1 namely, a two-stage reciprocating compressor 400 executed TWIN compressor with a first compressor stage 401 and a second compressor stage 402 as well as with a motor 500 , which is a drive motor M with a drive shaft 501 to a crankshaft 430 of the reciprocating compressor 400 is coupled.

This is indicated by the crankshaft 430 a drive shaft coupling 431 on that as a receptacle for the drive shaft 501 of the drive motor M is used. The crankshaft 430 is outside the drive shaft coupling 431 in a warehouse 502 rotatably mounted, which in the present case is designed as a ring ball bearing. The warehouse 502 Again, with a corresponding holding mechanism on the motor housing 503 held. In this way, in operation by means of the drive motor M driven crankshaft 430 via said drive shaft coupling 431 for coupling the drive shaft 501 of the drive motor 500 for driving the crankshaft 430 educated.

The crankshaft 430 also has an eccentric to the axis A on the crankshaft 430 trained eccentric crankshaft journal 432 on, which extends along an eccentric axis, which is referred to here as the shaft axis E.

Under rotating drive of the crankshaft 430 is the eccentric crankshaft journal 432 designed to indirectly drive a first connecting rod P1 directly and a second connecting rod P2. This is the eccentric crankshaft journal 432 formed by means of a first connecting rod bearing L1 for direct storage and direct drive of the first connecting rod P1. The second connecting rod P2, in turn, is movably supported on the first connecting rod P1 functioning as drive connecting rod P1, ie as a connecting rod, via two second connecting rod bearings L2 in the form of the ball bearings L2K1 and L2K2 which enclose a bearing bolt L2B. The ball bearing L2K1 is arranged on a first connecting rod part P2a of the second connecting rod P2 and the ball bearing L2K2 is arranged on a second connecting rod part P2b of the second connecting rod P2. The first connecting rod bearing L1 is designed as a ring ball bearing. With the first connecting rod P1 of the bearing pin L2B is firmly connected. For this purpose, the bearing pin L2B is pressed in the central region of its longitudinal axis with the connecting rod P1 via press-fit elements PV by means of a press fit.

The first piston K1 is inserted by means of a piston holder K11 as a separate part in the head end of the first connecting rod P1 and held there. The second piston K2 is integral and integrally formed on the head end K22 of the second connecting rod P2 - that is, along a cylinder axis Z distally opposite the first piston K1. The second connecting rod P2 is as a one-piece, in this case in a ring-like component - as in 2 visible - hung on the second connecting rod bearings L2 drehbweglich. Alternatively, the first piston may also be integrally formed on the first connecting rod P1 or the second piston may be held on the second connecting rod P2 (not shown).

At the in 2 shown construction is under rotating drive of the crankshaft 430 an eccentric rotational movement of the crankshaft journal 432 during operation of the compressor 400 achievable, so that the first and second piston K1, K2 with a reciprocating motion for the compression of Compressed air in the corresponding second and first compressor stage 402 . 401 each to be moved.

The second piston K2 of the first compressor stage 401 moves in a Zylinderhubraum 411 of the first cylinder 410 in the first (low pressure) compressor stage 401 , The first piston K1 moves in a Zylinderhubraum 421 a second cylinder 420 the second (high pressure) compressor stage 402 , The first and second cylinders 410 . 420 are part of a housing 440 of the entire air compressor with reciprocating compressor 400 , Drive motor M and crankshaft 430 , The housing 440 the air compressor is through other components 441 on the housing of a compressed air supply system 1001 as they are in 1 shown is held.

2 shows the TWIN compressor 400 , in this case in an operating position, according to which the second piston K2 of the (low-pressure) compressor stage 401 is in a stroke position HS, that is, the compression of the displacement 411 Air is imminent. By contrast, the first piston K1 of the second compressor stage is located as 402 in a compression position VS, that is from the second high-pressure stage 402 Compressed air is compressed to be discharged to the compressed air supply system 1001 ,

The movement of the first and second pistons K1, K2 during operation of the reciprocating compressor 400 is basically along the cylinder axis Z. This is center-symmetrical to cylinder surfaces Z1 and Z2 of the first and second Zylinderhubraums 411 . 421 for the second or first piston K2, K1 of the first and second cylinder 410 . 420 , In 2 For this purpose, the connecting rod length of the first connecting rod P1 with 52.00 mm is given as an example of the magnitude of the high-pressure stage 420 of the reciprocating compressor 400 ,

The first connecting rod P1 can, for example, also have a connecting rod length between 50 and 70 mm, in particular a connecting rod length of 66 mm. The second connecting rod may for example have a connecting rod length between 40 and 60 mm, in particular a connecting rod length of 53 mm. In the case of a connecting rod length of the second connecting rod of 53 mm, the distance between a piston head of the piston K2 and the eccentric crankshaft journal 432 for example, be between 15 and 25 mm, in particular 21 mm. The aforementioned dimensions can allow a deflection angle of the connecting rods to each other of up to 20 °, for example 14 °, and +/- 7 ° and in particular 7 °.

The bearing pin L2B has a diameter of 8 mm in this embodiment and may have diameters between 5 mm and 12 mm. The diameter of the bearing pin L2B is constant in this embodiment. The diameter of the bearing pin L2B can also change along its longitudinal axis. The maximum speed for this embodiment is up to 2700 revolutions per minute, resulting in a maximum sliding speed of about 0.14 m / s, in particular 0.137 m / s results. The maximum speed is preferably between 1500 and 3500 revolutions per minute.

The cylinder axis Z is oriented such that it runs along a radius about the shaft axis E (eccentric axis E). The shaft axis E is exactly perpendicular to the cylinder axis Z. That is, the eccentric crankshaft journal 432 the crankshaft 430 is also exactly perpendicular to the cylinder axis Z in the piston compressor 400 arranged. A sufficiently reliable and tight running of the second and first pistons K2, K1 in the first (low-pressure) compressor stage or (high-pressure) compressor stage 401 . 402 is thus also ensured along the cylinder axis Z due to the running direction of the piston K2, K1.

For this purpose, the arrangement of the first connecting rod P1 with piston K1 and the second connecting rod P2 with piston K2 under storage thereof by means of the first connecting rod bearing L1 and the second Bearing L2 is made exactly along the cylinder axis Z; for example, with a mounting dimension of X = 15.00 mm.

The result is a reciprocating engine in the form of a TWIN compressor 400 with first and second compressor stage 401 . 402 provided in which the first connecting rod P1 of the second, namely (high-pressure) compressor stage 402 is formed, wherein the first connecting rod P1 by means of the first connecting rod bearing L1 directly on the crankshaft journal 432 is stored - that is, as a drive connecting rod - and the second connecting rod P2 of the first, here (low-pressure) compressor stage 401 is formed, wherein the second connecting rod P2 by means of the second connecting rod bearings L2 in the form of two ball bearings L2K1 and L2K2 indirectly on the crankshaft journal 432 , that is directly on the first connecting rod P1 - so as Schlepppleuel the drive connecting rod - is stored.

The first connecting rod P1 is arranged with a first connecting rod part P1a within the intermediate space ZR between the two connecting rods P2a and P2b of the second connecting rod P2. The second connecting rod part P1b of the first connecting rod P1 forms the piston holder K11 in this case. A third connecting rod part P2c of the second connecting rod extends to the head end K22 of the second piston K2.

The above-described embodiments with drive connecting rod and Schlepppleuel prove to be particularly advantageous for a TWIN Compressor. However, the concept of the invention is not limited thereto.

3 shows a further embodiment of a reciprocating engine in the form of a two-stage reciprocating compressor 400 with a first connecting rod P1 for a first piston K1 of a second (high pressure) stage 402 and a second connecting rod P2 of a first (low pressure) stage 401 and with a first connecting rod bearing L1 and two second connecting rod bearings L2 in the form of ball bearings L2K1 and L2K2.

The construction of in 3 shown embodiment of the reciprocating compressor 400 is similar to the one in 2 shown piston compressor 400 , In the in 3 and 4 shown embodiments of the reciprocating compressor 400 Some details are not shown to improve the clarity of the drawings. The not described and not shown details of the reciprocating compressor 400 of the embodiment of 3 are made 2 for the expert.

The piston compressor 400 has a motor 500 , which is designed as a drive motor M and serves to drive the first connecting rod P1. This is an eccentric crankshaft journal 432 connected by a first connecting rod bearing L1 for direct storage and direct drive of the first connecting rod P1 with a first connecting rod P1a of the first connecting rod P1. The first connecting rod part P1a is arranged in a gap ZR between a first connecting rod part P2a and a second connecting rod part P2b of the second connecting rod P2. The first connecting rod bearing L1 is designed as a ring ball bearing. Under rotating drive is the eccentric crankshaft journal 432 designed to drive the first connecting rod P1 directly and the second connecting rod P2 indirectly.

The second connecting rod P2 is connected to the first connecting rod P1, d acting as drive connecting rod P1. H. Schlepppleuel, about two second connecting rod L2 in the form of ball bearings L2K1 and L2K2 enclose a bearing pin L2B, movably mounted. The ball bearing L2K1 is arranged on the first connecting rod part P2a of the second connecting rod P2 and the ball bearing L2K2 is arranged on the second connecting rod part P2b of the second connecting rod P2. The ball bearings L2K1 and L2K2 have ball bearing collars L2KB which are pressed between the ball bearings L2K1 and L2K2 and the second connecting rod P2 and improve the attachment of the ball bearings L2K1 and L2K2 between bearing pin L2B and second connecting rod P2.

The first connecting rod P1 is fixedly connected to the bearing bolt L2B. For this purpose, the bearing pin L2B is pressed in the central region of its longitudinal axis with the connecting rod P1 via press-fit elements PV by means of a press fit. A second connecting rod part P1b of the first connecting rod P1 extends up to the piston K1 formed on the first connecting rod P1.

The connecting rod parts P2a and P2b of the second connecting rod P2 open into a third connecting rod part P2c of the second connecting rod P2, which extends up to the second piston K2 formed on the second connecting rod P2.

Under rotating drive by the drive motor M is an eccentric rotational movement of the crankshaft journal 432 during operation of the compressor 400 achievable, so that the first and second pistons K1, K2 with a reciprocating motion for compressing compressed air in the respective second and first compressor stage 402 . 401 each to be moved. The second piston K2 of the first compressor stage 401 moves in a Zylinderhubraum 411 of the first cylinder 410 in the first (low pressure) compressor stage 401 , The first piston K1 moves in a Zylinderhubraum 421 a second cylinder 420 the second (high pressure) compressor stage 402 ,

The two ball bearings L2K1 and L2K2 make it possible, during operation, for a tilting angle α of the first connecting rod P1 to the second connecting rod P2, which is aligned perpendicular to the deflection of the connecting rods P1 and P2 and parallel to a longitudinal axis of the bearing bolt L2B, to be less than 5 ° and in particular less than 3 °. The tilt angle α refers to a tilting of the connecting rods P1 and P2 to each other. The occurring tilting of the connecting rods P1 and P2 leads to increased wear and increased operating noise. Therefore, it is advantageous if the tilting and in particular the tilt angle α is low.

A deflection angle, not shown, refers to a deflection of the connecting rods P1 and P2 relative to one another, which is necessary in the course of the operation of the reciprocating engine and takes place in a direction oriented perpendicular to the longitudinal axis of the bearing bolt L2B (not shown, deflection out of the image plane or into the plane) Image plane into it).

4 shows a further embodiment of a reciprocating engine in the form of a two-stage reciprocating compressor 400 with a first connecting rod P1 for a first piston K1 of a second (high pressure) stage 402 and a second connecting rod P2 of a first (low pressure) stage 401 and with a first connecting rod bearing L1 and two second connecting rod bearings L2 in the form of plain bearings L2G1 and L2G2. The embodiment of 4 is essentially identical to the one in 3 shown embodiment of the reciprocating compressor 400 with the only difference that in the embodiment of 4 two second connecting rod bearings L2 are used in the form of plain bearings L2G1 and L2G2, which have a sliding bearing collar L2GB. The sliding bearing collar L2GB on the one hand serves to fasten the respective plain bearings L2G1 and L2G2 to the first connecting rod part P2a of the second connecting rod P2 and the second connecting rod part P2b of the second connecting rod P2. On the other hand, the sliding bearing collar L2GB also prevents leakage of lubricant such as grease, lubricating oil or the like.

LIST OF REFERENCE NUMBERS

0

Air supply, intake

0.1

Filter element, air filter

1

Compressed air supply

2

Compressed air connection

3

exhaust port

3.1

Vent filter, filter element, silencer

100

Air dryer assembly

101

dry container

200

Pneumatic main line

201

first part of the pneumatic main

202

second part of the pneumatic main

230

Branch line, vent line

240

further vent line

241

another branch connection

242

connecting section

250

pneumatic control line

251

line section

252

control connection

260

further vent line

261

branch port

270

Air supply line

300

Valve arrangement, solenoid valve arrangement

310

Way valve arrangement

311

check valve

312

vent valve

313

pressure relief

314

piston

314.1

Relay vent body

314.2

Relaisentsperrkörper

315

adjustable spring

320

control valve

321

electrical control line

322

Kitchen sink

331

first throttle

332

second throttle

400

Air compressor in the form of a two-stage reciprocating compressor

401

first (low pressure) compressor stage

402

second (high pressure) compressor stage

410

first cylinder

411.421

Cubic capacity

420

second cylinder

430

crankshaft

431

Drive shaft coupling

432

crankshaft journal

440

casing

441

additional housing components

500

engine

501

drive shaft

M

drive motor

502

camp

600

additional pneumatic line

601, 602, 603, 604

Spring branch line

605

Storage branch line

610

gallery

1000

Compressed air supply system

1001

Compressed air supply system

1002

pneumatic system

1011, 1012, 1013, 1014

bellows

1110

manifold

1015

Storage

1111 to 1114

Magnetic storage-way valve

1115

Solenoid directional valve

A

axis

α

tilt

D

detail

DL

Compressed air flow

e

Eccentric axis, shaft axis

HS

stroke position

K1, K2

piston

K11

piston holder

K22

head

L1

first connecting rod bearing, ring ball bearing, joint plain bearing

L2

second connecting rod bearing

L2B

bearing bolt

L2G1, L2G2

bearings

L2GB

bearings Bund

L2K1, L2K2

ball-bearing

L2KB

Ball bearing collar

P1, P2

first, second connecting rod

P1a, P1b

first, second connecting rod of the first connecting rod

P2a, P2b, P2c

first, second, third connecting rod part of the second connecting rod

PV

Metal press fastener

VS

compression position

Z

cylinder axis

Z1, Z2

Cylinder surface

ZR

gap

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102004020104 [0009]

Claims (16)

Reciprocating engine ( 400 ), in particular two-stage or multi-stage piston compressor ( 400 ), comprising: - at least one first cylinder ( 420 ) and at least one of the first cylinder ( 420 ) associated first piston (K1) and at least one second cylinder ( 410 ) and at least one second cylinder ( 410 ) associated with the second piston (K2), wherein in operation the pistons (K1, K2) in a respective Zylinderhubraum ( 411 . 421 ) of the respective cylinder ( 410 . 420 ), - a crankshaft which can be driven during operation ( 430 ) with an eccentric crankshaft journal ( 432 ) and a drive shaft coupling ( 431 ), for coupling a drive shaft ( 501 ) of a drive motor (M) for driving the crankshaft ( 432 ), - a first connecting rod (P1) designed to deflect the first piston (K1), - a second connecting rod (P2) designed to deflect the second piston (K2), and - one fixed to the first connecting rod (P1) Bearing pin (L2B) about which the second connecting rod (P2) is rotatably movable, wherein the first connecting rod (P1) by means of at least one first connecting rod bearing (L1) directly on the crankshaft journal ( 432 ) is mounted and by means of the eccentric crankshaft journal ( 432 ) is movable and the second connecting rod (P2) by means of the bearing pin (L2B) is movable and wherein the second connecting rod (P2) has two connecting rods (P2a, P2b) with a gap (ZR) between these (P2a, P2b), wherein at least a connecting rod part (P1a) of the first connecting rod (P1) is arranged in the intermediate space (ZR) and at least one second connecting rod bearing (L2) is arranged between the bearing bolt (L2B) and each of the two connecting rod parts (P2a, P2b) of the second connecting rod (P2) is arranged. Reciprocating engine ( 400 ) According to claim 1, characterized in that the eccentric crank pin ( 432 ) and / or the drive shaft coupling ( 431 ) is aligned parallel to a shaft axis (E) perpendicular to a cylinder axis (Z). Reciprocating engine ( 400 ) according to claim 1 or 2, characterized in that - the second connecting rod (P2) by means of the two second connecting rod bearings (L2) and the bearing pin (L2B) indirectly on the crankshaft journal ( 432 ) is stored. Reciprocating engine ( 400 ) according to one of claims 1 to 3, characterized in that integrally formed on the first (P1) and / or second connecting rod (P2) of the piston (K1, K2), or by means of a piston holder (K11) of the piston (K1) is held. Reciprocating engine ( 400 ) according to one of claims 1 to 4, characterized in that the first connecting rod (P1) directly by means of the eccentric crankshaft journal ( 432 ) is movable and the second connecting rod (P2) indirectly by means of the eccentric crankshaft journal ( 432 ), in particular by means of the first connecting rod (P1), is movable, preferably at least the second connecting rod (P2) as a Schleue connecting rod from the first connecting rod (P1) is movable as a drive connecting rod. Reciprocating engine ( 400 ) according to one of claims 1 to 5, characterized in that at least one of the connecting rod bearings (L1, L2) a sliding bearing (L2G1, L2G2) or a roller bearing (L2K1, L2K2), in particular a needle bearing (L2N), a ball bearing or a roller bearing having. Reciprocating engine ( 400 ) according to one of claims 1 to 6, characterized in that at least one of the connecting rod bearings (L1, L2) has an outer ring and / or an inner ring of a rolling bearing, in particular needle bearing. Reciprocating engine ( 400 ) according to one of claims 1 to 7, characterized in that the second connecting rod bearings (L2) are ball bearings (L2K1, L2K2). Reciprocating engine ( 400 ) according to one of claims 1 to 7, characterized in that the second connecting rod bearings (L2) slide bearing (L2G1, L2G2). Reciprocating engine ( 400 ) according to one of claims 1 to 9, characterized in that a maximum deflection angle of the deflection of the connecting rods (P1, P2) between respective longitudinal axes of the connecting rods (P1, P2) is at most 14 °, for example at most 10 °, preferably about 7 ° is. Reciprocating engine ( 400 ) according to one of claims 1 to 10, characterized in that the at least two second connecting rod bearings (L2) are arranged and designed such that in operation a perpendicular to the deflection of the connecting rod and parallel to a longitudinal axis of the bearing pin (L2B) aligned tilt angle (a ) of the first connecting rod (P1) to the second connecting rod (P2) is less than 5 °, in particular less than 3 °. Reciprocating engine ( 400 ) according to one of claims 1 to 11, characterized in that - the first connecting rod (P1) by means of the first connecting rod bearing (L1) directly on the crankshaft journal ( 432 ) is mounted and at the first connecting rod (P1) by means of a Piston holder (K11), the first piston (K1) is held, and - the second connecting rod (P2) by means of the two second connecting rod bearings (L2) and the bearing pin (L2B) is connected to the first connecting rod (P1) and at the second connecting rod ( P2) of the second piston (K2) is formed. Reciprocating engine ( 400 ) according to one of claims 1 to 12, characterized in that the reciprocating compressor ( 400 ) as a two-stage compressor ( 400 ) with a first and second compressor stage ( 401 . 402 ), in particular as a TWIN compressor, wherein: - the first connecting rod (P1) of the second, in particular (high-pressure) compressor stage ( 402 ), wherein the first connecting rod (P1) by means of the first connecting rod bearing (L1) directly on the crankshaft journal ( 432 ), and / or - the second connecting rod (P2) of the first, in particular (low-pressure) compressor stage ( 401 ), wherein the second connecting rod (P2) by means of the two second connecting rod bearings (L2) and the bearing pin (L2B) on the first connecting rod (P1) is mounted. Compressed air supply system ( 1001 ) for operating a pneumatic system ( 1002 ), in particular an air suspension system of a vehicle, preferably a passenger car, with a compressed air flow (DL), comprising: - an air dryer arrangement ( 100 ) in a pneumatic main line ( 200 ), which is a compressed air supply ( 1 ) from an air compressor ( 400 ) and a compressed air connection ( 2 ) to the pneumatic system ( 1002 ) pneumatically connects, and - one to the pneumatic main ( 200 ) pneumatically connected valve arrangement ( 300 ) for controlling the compressed air flow (DL) and an air dryer ( 101 ) in the pneumatic main line ( 200 ), whereby - to the compressed air supply ( 1 ) an air compressor ( 400 ) with a reciprocating piston engine ( 400 ), in particular a two-stage or multi-stage piston compressor ( 400 ), is connected according to one of claims 1 to 13. Compressed air supply system ( 1000 ) with a pneumatic system ( 1002 ) and with a compressed air supply system ( 1001 ) according to claim 14 for operating the pneumatic system ( 1002 ) with a compressed air flow (DL), in particular an air suspension system of a vehicle, preferably a passenger car, wherein the pneumatic main ( 1002 ) a compressed air supply ( 1 ) from an air compressor ( 400 ) with a reciprocating piston engine ( 400 ), in particular a two-stage or multi-stage piston compressor ( 400 ), according to one of claims 1 to 13 and a compressed air connection ( 2 ) to the pneumatic system ( 1002 ) pneumatically connects. Vehicle, in particular a car, with a pneumatic system ( 1002 ), in particular an air spring system, and a compressed air supply system ( 1001 ) according to claim 14 for operating the pneumatic system ( 1002 ) with a compressed air flow (DL).

Images