EP1206640B1 - Axial-piston drive system with a continuously adjustable piston stroke - Google Patents

Description

The invention is based on an axial piston engine with a Infinitely adjustable piston stroke according to the generic term of claim 1. Such an axial piston engine is e.g. from the US-A-4,236,875.

It is known to use a continuously variable axial piston engine adjustable piston stroke, especially for automotive air conditioning systems to be used as a refrigerant compressor.

An air conditioning system of a motor vehicle essentially has a refrigerant compressor, a first heat exchanger, the so-called evaporator, a second heat exchanger, an expansion device and piping that connect the components together connect. The refrigerant compressor has the task to draw a refrigerant from the evaporator, in which the Refrigerant evaporates under heat, and to a higher one To compress pressure. In the second heat exchanger the refrigerant then heat at a higher temperature level give up and experiences one in the expansion organ Throttling to an evaporator pressure level.

The performance of the refrigerant compressor can be controlled via a drive speed and particularly energetically favorable for axial piston engines Infinitely adjustable via the piston stroke be carried out. Known axial piston engines or axial piston compressors for automotive air conditioners have one drive shaft driven by a pulley. In one The crankcase has a swashplate that is non-rotatable and tiltable mounted on the drive shaft via a joint. The swashplate drives at least one movable in a cylinder Piston on. Everyone is capable of absorbing tensile and compressive loads Piston connected to the swash plate via two articulated stones, each with a joint stone on the Piston facing and on the tread facing away from the piston the swashplate. The articulated stones run with their Flat surfaces on the tread of the swash plate with full Peripheral speed with superimposed radial movement, which results in an elliptical career. The articulated stones lie with their curved surfaces in molded spherical bearings of the pistons, in which during operation there is a comparatively small relative movement.

Furthermore, instead of using swivel blocks, the swash plate be connected to the pistons via a swash plate. The Swashplate is either on a housing or on piston rods secured against rotation against the drive shaft. A Bearing between the swash plate and the swash plate takes up the entire relative movement. The swashplate only wobbles due to the rotating swashplate out.

The piston stroke and thus the performance of the axial piston compressor is about the degree of tilt angle of the swash plate set. A large tilt angle creates a large one Piston stroke and high performance, with a small tilt angle there is a small piston stroke and a low output. The tilt angle of the swashplate is usually by two stops at a minimum and a maximum Value limited. Usually there are one or two guide pins necessary to guide the tilting movement and a Avoid jamming. The tilt limits or the stops can be integrated in the guide pins.

Is when adjusting the tilt angle from a maximum Set a lower dead center of the piston moved towards the swash plate in the cylinder, can already compressed gas cannot be pushed out completely. The compression energy introduced into the gas can not be used for the cooling process. A so-called arises Clearance between the piston and a valve plate on the cylinder, which leads to energy loss. To the Avoid harmful space and the top dead center of the pistons maintain, the swash plate is also against one preloaded compression spring mounted axially. The Swashplate is usually over stops in axial Direction limited.

Advantages of the invention

The axial piston engine according to the invention has a drive shaft with one on it tiltable in a crankcase and swash plate mounted slidably in the axial direction. A tilting angle and a axial position of the swash plate adjustable. The swashplate is driving with at least one, in a cylinder movable piston connected.

It is proposed that the control device be a piston Has separate actuating unit, and that the actuating unit from one of the pumped medium of the piston independent hydraulic unit is supplied with pressure oil. With one of the pistons separate actuator can be independent of the operating points large control range can be created. A positioning force can only in the direction of the possible adjustment movement the swashplate be initiated, creating a Pinching and increased wear can be avoided.

Flow losses between the top of the piston and the Crankcase can be avoided and the total compressor capacity, for example as a cooling capacity for an air conditioning system be used. Furthermore, the axial piston engine be operated with a low pressure in the crankcase. On Leakage flow of refrigerant from the crankcase through shaft seals outward is roughly proportional to the crankcase pressure. With a low pressure can be an expensive seal of the crankcase avoided and a low leakage achieved become. This is especially true with high-volume refrigerants absolute pressures beneficial, in general for a control over a gas pressure difference at the piston high Pressures in the crankcase are required. At a low Pressure is also the solubility of the refrigerant in an air conditioning system low in a piston lubricant, thereby a high viscosity can be maintained.

Furthermore, the viscosity has a positive effect that with a separate control unit heating the lubricant by a gas heated from the high pressure side of the piston can be avoided. With a high viscosity, a low friction between highly loaded sliding pairs on the Swashplate and reached between the pistons and the cylinders become, resulting in a long life and a high Reliability helps.

With an actuating unit separate from the piston, there is no particular one Pressure in the crankcase required for regulation, whereby from an evaporator coolant through the crankcase the cylinder can be guided. The crankcase can cooled, an additional suction chamber on top of the Pistons can be avoided and installation space can be saved. Furthermore, a mostly large volume of the crankcase can Damping of gas pulsations can be used.

The actuating unit can be electrical, pneumatic or advantageous be hydraulically driven. With hydraulic fluid can achieve an advantageous vibration damping and a especially vibration-resistant axial piston mechanism created become. The hydraulic control unit is operated by a hydraulic unit independent of the pumped medium of the piston supplied with pressure oil, for example advantageous from a hydraulic unit already present in a motor vehicle. Additional components can be saved and one more independent of the operating points of the axial piston engine large control range can be achieved. Furthermore, there is no Pressure build-up when starting the axial piston engine for the Regulation required, for example by a minimal Tilt angle of 2 °. A load-free start-up of the axial piston engine is made possible and for example starting one the internal combustion engine driving the axial piston engine will be relieved.

The swash plate can be suitable with various ones to those skilled in the art appearing constructions tiltable and axially displaceable be carried out. For example, the swash plate on a Z-shaft with a tilted bearing bore stored and a rotational movement of the bearing disc with a Stroke movement be superimposed, etc. In one embodiment of the Invention is proposed that the swash plate on a axially displaceable via an actuating piston of the actuating unit Rod end mounted and the swash plate via a decentralized Joint with a component fixed in the axial direction connected is. It can be a structurally simple and inexpensive Adjustment mechanism can be achieved at the tilt angle and axial position of the swash plate a desired To have context. The top dead center of the piston in the cylinder barrel can get and a damaged space and Energy losses can be avoided, making the axial piston engine particularly advantageous as a compressor in one Air conditioning can be used. The compressor can be used as pure swash plate compressor or as swash plate compressor be executed. Furthermore, the solution according to the invention be used for gears etc.

The adjusting piston and the joint head are advantageously in one piece executed, whereby additional components, assembly costs and Costs can be saved. The actuator can partially or rotating completely with the drive shaft or be arranged rotatably in a housing. Furthermore, the actuator from the side facing away from the piston to the Swashplate or from the side facing the piston the swashplate act.

drawing

Further advantages result from the following description of the drawing. In the drawing, embodiments of the Invention shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also use the features individually consider and combine them into meaningful further combinations.

Fig. 1

ein Axialkolbentriebwerk bei maximalem Kolbenhub im Schnitt,

Fig. 2

ein Axialkolbentriebwerk bei minimalem Kolbenhub im Schnitt,

Fig. 3

einen Ausschnitt einer Variante nach Fig. 1 und

Fig. 4

eine Prinzipskizze einer hydraulischen Regelung.

Show it:

Fig. 1

an axial piston engine with maximum piston stroke on average,

Fig. 2

an axial piston engine with minimal piston stroke on average,

Fig. 3

a section of a variant of FIGS. 1 and

Fig. 4

a schematic diagram of a hydraulic control.

Description of the embodiments

Fig. 1 shows an axial piston engine for an air conditioning system of a motor vehicle that works as a compressor. The axial piston engine has a drive shaft 10 on which in a Crank chamber 14 a swash plate 16 is mounted. The Swash plate 16 is driven via hemispherical joint stones 56 with pistons 26, 28 guided in cylinders 22, 24 connected. Everyone is capable of absorbing tensile and compressive loads Pistons 26, 28 via two joint blocks 56 with the swash plate 16 connected, each via an articulated stone 56 with one facing the pistons 26, 28 and with one piston 26, 28 facing away from tread 58, 60. The articulated stones 56 run with their flat surfaces on the running surfaces 58, 60 the swash plate 16 at full peripheral speed superimposed radial movement, creating an elliptical Path results. The articulated stones 56 lie with their arched Surfaces in molded spherical bearings 62 of the pistons 26, 28, in which a comparative during operation there is a small relative movement.

The swash plate is via a joint head 48 of a joint sleeve 64 rotatably connected to the drive shaft 10. To the Piston stroke and thus the performance of the axial piston engine To be able to adjust the swashplate 16 continuously a control device 18 tiltable on the joint head 48 and displaceable in the axial direction with the joint sleeve 64. With a large tilt angle, a large piston stroke and high performance, with a small tilt angle becomes a small piston stroke and low power achieved (Fig. 1 u. 2).

According to the invention, the control device 18 has one of the Pistons 26, 28 separate hydraulic actuator 30 Adjustment unit 30 has one piece with joint sleeve 64 and the articulated head 48 formed adjusting piston 44. The Actuating piston 44 is formed in an actuating housing 54 Cylinder guided. The control housing 54 is radially above a positive engagement, not shown, and axially over a Tension ring 76 positively attached to the drive shaft 10. The drive shaft 10 is axially in the of the cylinders 22, 24 facing away from the control housing 54, a Axial bearing 80 and via a running disk 82 on a cover 78 and in the direction of the cylinders 22, 24 via an axial slide bearing 84 supported on a housing 86 of the axial piston engine. Furthermore, the drive shaft 10 via two radial bearings 88, 90 stored in the cover 78 and in the housing 86.

The actuating piston 44 includes the cylinder over three Seals 68, 70, 72 sealed pressure chamber 74. The Swash plate 16 is integral with the swash plate 16 molded connecting element 66 and a decentralized joint 52 connected to the steep housing 54.

If the pressure chamber 74 is pressurized with oil, shifts the actuating piston 44 together with the joint sleeve 64, the Rod 48 and swash plate 16 in the direction of the cylinder 22, 24 against a prestressed compression spring 92 (Fig. 2). The compression spring 92 is rotationally fixed to the drive shaft 10 connected and is supported on a clamping ring 94 in the from Adjusting piston 44 facing away from. By the decentralized Hinge 52, which is attached to the connecting element 66 by a formed in an elongated hole 96 bolts 98 is created by the lifting movement of the swash plate 16 Tipping moment on the swash plate 16. The lifting movement of the Swash plate 16 is by one through the bolt 98 in the slot 96 guided tilting movement superimposed, so that one top dead center 100 of the pistons 26, 28 in the cylinders 22, 24 preserved. To make do with a small amount of oil, the volume of the pressure chamber 74 is preferably small.

The actuating unit 30 or the actuating piston 44 is one the cylinders 22, 24 downstream oil separator 34 an axial bore 102, 104, 106 in the housing 86, in the slide bearing 84 and in the drive shaft 10 and via a radial bore 108 in the drive shaft 10 supplied with pressure oil (Fig. 1, 2nd u. 4). The pressure oil is advantageously in the drive shaft 10 fed axially in the middle. In this area is the relative movement between the drive shaft 10 and the slide bearing 84 advantageously low. Furthermore, the slide bearing 84 can additionally can be used as a seal. Located in the oil separator when starting 34 no oil pressure before, the compression spring 92 a maximum tilt angle, which ensures a pressure build-up is.

The actuating unit 30 is connected to the oil separator via an inflow 38 34 and via an outlet 36 with the crank chamber 14 connected. The inlet 38 and the outlet 36 are each over a valve 110, 112 controllable. If a higher actuating force is required, opens valve 110. The oil flows at a high pressure level into the actuating unit 30 and acts on the actuating piston 44. The valve 112 remains closed. Will be a lesser Actuating force required, valve 112 opens, which Oil drains from the actuator 30 and at the actuator 30 a lesser force is available. The swash plate 16 is via the compression spring 92 in the direction of the maximum tilt angle postponed. The valve 110 is closed.

If one of the valves 110, 112 is replaced by a throttle and only the inflow 38 or the outflow 36 can be regulated advantageously with an oil level control unit indicated in FIG. 4 40 and with a channel 42 from the oil separator 34 to Crank chamber 14 ensure that there is always sufficient Amount of lubricant available in crankcase 14 stands.

Fig. 3 shows a section of a variant of an axial piston engine with a control device 20. Essentially constant components are basically the same Numbered reference numerals. Regarding the function and not illustrated components can on the embodiment in 1 and 2 are referred. The control device 20 has an actuating unit 32 with an actuating piston 46, which in an annular recess 122 of a housing 114 of the axial piston engine is rotatably arranged, which means an additional Adjustment housing can be saved. The actuating piston 46 is in the direction of swash plate 16 by a first compression spring 136 loaded, is opposite via two seals 116, 118 sealed the housing 114 and acts via a joint sleeve 120 and one made in one piece with the joint sleeve 120 Articulated head 50 on the swash plate 16 in the axial Direction against a second biased, stronger Compression spring 124. The compression spring 124 is in the from the actuating piston 46 opposite direction on a shoulder 126 of a drive shaft 12 supported. The swash plate 16 is not closer to a shown decentralized joint supported in the axial direction, so that by the lifting movement of the swash plate 16 a tilting moment arises on the swash plate 16. The actuating piston 46 and the joint sleeve 120 are on both sides acting axial bearing 128, the actuating piston 46 inner treads, hinge sleeve 120 and a fastener Form 130 outer treads. With the fastener 130, which has a thread 132 with the joint sleeve 120 is connected, a defined axial play in Thrust bearing 128 can be set. Actuator 32 or the actuating piston 46 is driven by an axial bore 134 Oil separator 34 is supplied with pressure oil, as is the actuating unit 30 (cf. corresponding to Fig. 4).

reference numeral

10

drive shaft

12

drive shaft

14

crankcase

16

swash plate

18

control device

20

control device

22

cylinder

24

cylinder

26

piston

28

piston

30

actuator

32

actuator

34

oil separator

36

outflow

38

Inflow

40

Oil level control unit

42

channel

44

actuating piston

46

actuating piston

48

joint head

50

joint head

52

joint

54

component

56

joint Stein

58

tread

60

tread

62

camp

64

joint sleeve

66

connecting element

68

poetry

70

poetry

72

poetry

74

pressure chamber

76

clamping ring

78

cover

80

thrust

82

sheave

84

bearings

86

casing

88

camp

90

camp

92

compression spring

94

clamping ring

96

Long hole

98

bolt

100

dead

102

drilling

104

drilling

106

drilling

108

drilling

110

Valve

112

Valve

114

casing

116

poetry

118

poetry

120

joint sleeve

122

puncture

124

compression spring

126

paragraph

128

camp

130

fastener

132

thread

134

drilling

136

compression spring

Claims (4)

1. Axial piston drive unit with a continuously adjustable piston stroke, comprising a drive shaft (10, 12) on which a swash plate (16) is mounted in a crank chamber (14) in such a way as to be tiltable and displaceable in the axial direction, and with a regulator (18, 20) by means of which an angle of tilt and an axial position of the swash plate (16) can be adjusted, and with at least one piston (26, 28) connected to the swash plate (16) so that it can be actuated to move within a cylinder (22, 24), wherein the regulator (18, 20) incorporates an adjustment unit (30, 32) that is separated from the piston (26, 28) and hydraulically driven,
   characterized in that the adjustment unit (30, 32) is supplied with pressurized oil by a hydraulic unit that is independent of the medium being propelled by the piston (26, 28).
2. Axial piston drive unit according to Claim 1,
   characterized in that the adjustment unit (30, 32) is driven hydraulically.
3. Axial piston drive unit according to Claim 1 or 2, characterized in that the swash plate (16) is mounted on a joint head (48, 50) that can be axially displaced by means of a positioning piston (44, 46) of the adjustment unit (30, 32) and the swash plate (16) is connected by an off-centre joint (52) to a component (54) that is fixed in the axial direction.
4. Axial piston drive unit according to Claim 3, characterized in that in the positioning piston (44) and the joint head (48) are constructed in one piece.

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