DE102013202543A1 - Hydraulic radial piston machine - Google Patents

Abstract

Disclosed is a digitally adjustable hydraulic radial piston machine which has a central part. In this case, a low-pressure valve and at least one high-pressure valve are assigned to a respective cylinder-piston unit of the radial piston engine. Furthermore, a valve block is provided for each cylinder-piston unit, in which the low and / or high pressure valve is received. The valve blocks are mounted on the central part.

Description

The invention relates to a hydraulic radial piston machine according to the preamble of patent claim 1.

In conventional hydraulic displacement machines, which may be embodied, for example, as radial piston or as axial piston machines, the control of the inlet and the outlet or the connections to the high and low pressure of the individual cylinder-piston units takes place mechanically. In the case of an axial piston pump, for example, two pressure kidneys are used, via which the connections to the high-pressure side and to the low-pressure side open during a certain region of the circular path and thus during a certain stroke section of the cylinder-piston units. In the case of radial piston pumps, one mechanical high-pressure valve and one mechanical low-pressure valve are provided per cylinder-piston unit. The high-pressure valve of each unit, for example, always opens when a certain pressure built up in the respective cylinder is exceeded, so that the pressure-increased pressure medium can flow to the high-pressure side of the pump.

The publication WO 2008/012558 A2 discloses valve controlled positive displacement machines that are digitally adjustable. In this case, each cylinder-piston unit is associated with an electrically operated low-pressure valve and an electrically operated high-pressure valve.

Thus, the units can be controlled separately in pump mode, motor mode and in a so-called idle mode. Through the idle mode, individual units can be deactivated or powerless by permanently opening the low-pressure valve and by permanently closing the high-pressure valve. Thus, the volume flow or the rotational speed of the positive displacement machine can be reduced.

The publication EP 2 187 104 B1 shows a digitally adjustable radial piston machine with six cylinder-piston units, which are arranged in a radial plane, with pistons of the cylinder-piston units are supported on an eccentric shaft. Each cylinder-piston unit is associated with an actively controllable low-pressure valve and a passively controllable high-pressure valve. The valves are used in a common one-piece housing.

In the document Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment by the authors SH Salter, JRM Taylor and NJ Caldwell discloses a digitally adjustable radial piston machine with several radial planes, in each of which five cylinder-piston units are arranged. In this case, an actively controllable low-pressure valve and an actively controllable high-pressure valve designed as a check valve are associated with a respective cylinder-piston unit, wherein the valves are arranged in a common housing.

The DE 10 2010 004 808 A1 also discloses a digitally adjustable radial piston machine. A respective cylinder-piston unit is hereby assigned, in addition to an actively controllable low-pressure valve and an actively controllable high-pressure valve, a passive high-pressure valve which is arranged parallel to the actively controllable high-pressure valve. This results in that the radial piston machine can be used independently of the actively controllable high-pressure valve in a pump operation.

A disadvantage of the above radial piston machines is that they have a high manufacturing risk, since the housing in which the valves are arranged has a plurality of holes and recesses for the low and high pressure valves and for high and low pressure channels for supplying the valves. For example, if a manufacturing error occurs in a valve hole for a high or low pressure valve, the entire housing can not be used. Furthermore, it is disadvantageous that the high and low pressure valves can be tested consuming only in a mounted state in the housing on their functionality. In addition, such a radial piston machine has a high assembly cost during final assembly. Furthermore, a maintenance of the radial piston machine is relatively high, since during maintenance, for example, the individual valves are checked and this is only possible in the assembled state of the valves.

In contrast, the present invention seeks to provide a radial piston machine which has a low manufacturing risk, which is easy to maintain, in which an assembly effort is reduced and in the specific assemblies separately, so independent of the radial piston machine, mounted and testable.

The object is achieved by a radial piston machine according to the features of patent claim 1.

Other advantageous developments of the invention are the subject of further subclaims.

According to the invention, a radial piston machine, in particular a digitally adjustable hydraulic radial piston machine, cylinder-piston units. These each have a piston which is supported on a drive shaft, in particular on an eccentric shaft. The radial piston machine advantageously has a central part with a high pressure passage to which individual valve blocks are mounted. Here, a valve block is provided for each cylinder-piston unit. In the valve block, a low and / or high pressure valve is arranged, which serves for connecting a valve block associated cylinder-piston unit with a low and / or high pressure region of the radial piston machine.

This solution has the advantage that the radial piston machine has a low manufacturing risk, since not the central part, but only a valve block for receiving a low-pressure and / or a high-pressure valve must be formed. If, for example, a production shortage occurs during the production of the valve mount, then only the defective valve block has to be replaced. By contrast, it is necessary in the prior art explained at the outset to replace a complete housing having all valves in case of manufacturing errors. A further advantage is that a low-pressure and / or high-pressure valve arranged in a valve block can be tested independently of the radial piston machine or the central part of the radial piston machine. Thus, a valve block can be preassembled with the low-pressure and / or high-pressure valve and checked independently of the remaining radial piston machine. Furthermore, easy maintenance is possible by the radial piston machine according to the invention, since the low-pressure and / or high-pressure valves do not need to be tested in the radial piston engine or in a common housing, as in the prior art described above, but can only be tested in their valve block , In addition, an assembly effort is reduced in the radial piston engine according to the invention, since the valve blocks can be pre-assembled with their low-pressure and / or high-pressure valves and also pre-tested. Another advantage is that with the same ausgestaltetem central part of the valve block or an arrangement of the valves in the valve block can be configured differently and only a Schnittstellte between the valve block and the central part must remain the same. Thus, it is not necessary to change the central part in a change of the valve block and it is conceivable, for example, to use a different central part at different radial piston machines with differently shaped and arranged valves cost. Preferably, both the low-pressure valve and the high-pressure valve are arranged together in a respective valve block. However, it is also conceivable to provide a single valve block for each valve.

In a further embodiment of the invention, the valve block has a high-pressure branch channel. This extends over a contact surface of the valve block in the central part, continues therein and opens in, in particular in an axial direction of the radial piston engine extending, high-pressure channel. Thus, the high-pressure passage of the central part can be easily connected via the valve block with the cylinder-piston unit.

Advantageously, in the central part for each cylinder-piston unit, which are arranged in a common radial plane, a high-pressure channel is provided. This is preferably introduced adjacent to the associated cylinder-piston unit in the central part.

In order to use the radial piston engine, for example in an engine operation, the high-pressure valve of at least one valve block is an actively controllable high-pressure valve. Thus, the valve block associated with the actively controllable high-pressure valve cylinder-piston unit can be connected to the high-pressure passage of the central part in a stroke movement of its piston in the direction of enlargement of a piston bounded working space. Vorzugsswiese all valve blocks have an actively controllable high pressure valve.

The low-pressure valve of at least one valve block is preferably an actively controllable low-pressure valve. This can be a cylinder-piston unit, which is associated with a valve block with an actively controllable low-pressure valve, activated and deactivated. To deactivate the cylinder-piston unit, the low-pressure valve simply remains in its open position, whereby the limited by the cylinder and the piston of the cylinder-piston unit working space is continuously connected to a low pressure. Preferably, all the valve blocks have an actively controllable low-pressure valve.

In addition or as an alternative to the actively controllable high-pressure valve, a respective high-pressure valve can be assigned to a respective cylinder-piston unit, which is preferably arranged in the central part. The passive high pressure valve is preferably arranged fluidically parallel to the high pressure valve of the valve block. The passive high-pressure valve can serve to control a pressure medium connection between the high-pressure branch channel of the cylinder-piston unit associated valve block and connectable to this high-pressure passage, whereby the radial piston machine can be used in a simple manner in a pump operation. Moves a piston of a cylinder-piston unit, which is associated with a passive high-pressure valve, in the direction of a reduction of his limited working space, so can pressure medium From this working space simply be displaced over the opening passive high pressure valve to the high pressure channel.

A cylinder of a cylinder-piston unit can preferably be supported outwardly on the central part, whereby the support can be formed independently of the valve block and the high and low pressure valves.

In a further embodiment, the support of the cylinder can be made pivotable on a socket inserted in the central part, which can be easily replaced when worn.

The central part may be formed as a disk with a plurality of cylinder-piston units in a single radial plane. Alternatively, the central part may also be designed as a monoblock having a plurality of cylinder-piston units in a plurality of radial planes.

Preferably, an electrical contacting of the high and low pressure valves takes place on the respective valve block.

In the following, a preferred embodiment of the invention is explained in more detail with reference to schematic drawings.

Show it:

1 in a schematic front view with an outbreak a radial piston machine according to an embodiment,

2 in a simplified perspective view of the radial piston engine according to the embodiment,

3 an enlarged section of the eruption area of the radial piston machine 1 .

4 in a schematic cross-sectional view of a valve block of the radial piston machine according to the embodiment,

5 an enlarged section of the valve block 4 in the area of a low-pressure valve,

6 an enlarged section of the valve block 4 in the area of a high pressure valve and

7 a in a schematic plan view of the valve block 4 ,

According to 1 is shown a radial piston machine whose displacement volume is digitally adjustable. The radial piston machine 1 has an annular central part 2 , this in 1 by the outbreak of the front view of the radial piston machine 1 is apparent. The central part 2 surrounds an eccentric shaft 4 which is substantially coaxial with the central part 2 extends. The eccentric shaft 4 has four eccentrics 6 to 12 on, in the axial direction of the eccentric shaft 4 arranged one behind the other. At the eccentric shaft 4 are supported by the eccentrics 6 to 12 Thus, in four radial planes from cylinder-piston units from where in the 1 for simplicity, only a single cylinder-piston unit 14 the first radial plane - in the outbreak - is shown, the piston 16 to be in the 1 foremost eccentric 6 supported. The eccentric shaft 4 has at its end a toothing 17 for a splined shaft connection.

A respective cylinder-piston unit 14 are an actively controllable high pressure valve 18 , an actively controllable low-pressure valve 20 and a passive high pressure valve 22 assigned. The actively controllable high and low pressure valves 18 and 20 are each in a common valve block 24 arranged at the central part 2 is attached.

In a radial plane of the radial piston machine 1 are each six cylinder-piston units 14 provided, thus a total of six valve blocks 24 at the central part 2 are arranged per radial plane. In the 1 are in the outbreak that to the valve block 24 adjacent valve blocks 26 and 28 recognizable in sections. The cylinder-piston units are via the high and low pressure valves 18 and 20 for adjusting a volume flow of the radial piston machine 1 activatable or deactivatable.

Furthermore, each cylinder-piston unit 14 a radial plane of the radial piston machine 1 an axially extending high pressure passage 30 to 40 assigned in the central part 2 seen in a radial plane are each introduced between two cylinder-piston units. Thus, according to the number of cylinder-piston units in a radial plane, a corresponding number of evenly distributed on a bolt circle high-pressure channels provided. The axially-successively arranged cylinder-piston units of the radial planes of the radial piston engine 1 are connected to the same high-pressure channel.

In the 2 is the radial piston machine 1 out 1 in a perspective view without a substantially circular cylindrical low pressure area limiting sheath 42 , please refer 1 represented. According to 2 are four radial planes 44 to 50 the radial piston machine 1 Recognizable with cylinder-piston units. The central part 2 is designed here as a monoblock. It is conceivable that the central part has cylinder-piston units in only a single radial plane, wherein the central part is then designed as a disk. Together with the valve blocks it would then form a total disc.

The central part 2 is cylindrical and has a cross section substantially as an equilateral hexagon formed outer surface 52 , By this configuration, the central part 2 six side surfaces, on each of which four valve blocks 24 are arranged in series one behind the other, with the better representability half only a valve block in the 2 is provided with a reference numeral. If the radial piston engine per radial plane more or less cylinder-piston units, so it would have more or less side surfaces accordingly.

Furthermore, in the 2 an electrical contacting of the electromagnetically actuated actively controllable high and low pressure valves 18 and 20 recognizable. These are the high and low pressure valves arranged in series one behind the other 18 and 20 each at a common Kontaktierungsstrang 54 connected, each extending between the rows.

According to 3 is a section of the radial piston machine 1 in the area of the outbreak 1 shown enlarged. The following is the configuration of the central part 2 with the valve block 24 described, wherein the central part 2 in the region of the valve blocks, not shown, and the valve blocks, not shown, are designed accordingly.

It can be seen that the cylinder-piston unit 14 out to one in a radial bore 55 of the central part 2 screwed socket 56 supported. The piston 16 in turn, it is supported on the eccentric shaft in a conventional manner 4 from. For the support of the cylinder-piston unit 14 For example, a spring, not shown, is provided which the piston 16 against the eccentric shaft 4 and the cylinder 58 against the socket 56 stressed. The cylinder 58 is pivotable in the socket 56 stored by the cylinder 58 an annular cross-sectionally convex annular face 60 and the socket 56 a concave cross-section annular face 62 have, wherein the annular end faces 60 and 62 slidably abut each other. The socket 56 extends in the radial direction of the radial piston machine 1 from the outside of the central part 2 Approximately half of the radial bore 55 , The cylinder 58 in turn, for the most part is in the radial bore 55 ,

The socket 56 dives with a radial from the central part 2 cantilevered sleeve 64 in one in the valve block 24 screwed connection socket 66 one. In the outer circumference of the Buchsenbundes 64 the socket 56 is introduced an annular groove for receiving sealant. The socket 56 serves in addition to the support of the cylinder-piston unit 14 as a connecting channel between the valve block 24 and one of the cylinder 58 and the piston 16 limited work space 68 ,

The radial bore 55 is about in the cutting plane of the 3 seen in the middle of the side surface 70 forth in the central part 2 brought in. Approximately in parallel distance to the radial bore 55 to the right in the 3 offset is a blind hole 72 also from the side surface 70 forth in the central part 2 introduced the the high pressure channel 30 cuts. The blind hole 72 serves to connect the high pressure channel 30 with one in the valve block 24 trained high pressure branch channel 74 , In the blind hole 72 is a check valve 76 used. Its valve body 78 is via a spring against a valve seat of the check valve 76 curious; excited. In a pressure medium flow direction from the high pressure branch passage 74 in the direction of the high-pressure channel 30 can the valve body 78 lift off the valve seat. The high pressure branch channel 74 is with the workspace 68 the cylinder-piston unit 14 in pressure medium connection, which in the pump operation of the radial piston machine 1 upon reaching a predetermined pressure in the working space 68 the check valve 76 can be opened automatically.

Based 4 is the valve block below 24 together with the low pressure valve 20 and the high pressure valve 18 explained in more detail. For connecting the valve block 24 to the side surface 70 of the central part 2 out 3 this one has a connection surface 80 , From this forth is seen in cross section approximately in the middle of a valve body 24 penetrating stepped bore 82 brought in. Starting from the connection surface 80 is a first bore section 84 the stepped bore 82 provided with an internal thread into which the socket 66 is screwed. A screwed-in section of the connection socket 66 is radially stepped back, which then one to the valve block 24 facing ring end face 86 which, in the screwed-in state on a sinking base in the valve block 24 introduced lowering 88 is essentially present. The connection socket 66 has a substantially cylindrical inner circumferential surface 90 that has rounded edges. In the of the inner circumferential surface 90 spanned space dives the socket 56 out 3 with her bush collar 64 sealing and extends approximately to a low pressure valve 20 pointing rounded edge 92 the connection socket 66 , In the connection socket 66 is in the of the low pressure valve 20 pointing away a side down 94 introduced, creating an annular end face 96 is formed at the Rifle 56 from the 3 can rest in the assembled state.

The stepped bore 82 will after the threaded section 84 from the high pressure branch channel 74 interspersed. This is the workspace 68 out 3 over the socket 56 and the connection socket 66 with the high pressure branch channel 74 connected.

The stepped bore 82 has after the high pressure branch channel 74 one, a smaller diameter than the threaded portion 84 having a recording stage 100 for receiving a valve housing 102 of the low pressure valve 20 , After the recording stage 100 is then a smaller diameter than the recording level 100 having a drilling step 104 provided, which then in the from the terminal surface 80 pointing away top 106 of the valve body 24 empties.

The valve housing 102 of the low pressure valve 20 is in the recording stage 100 from the connection surface 80 used and has an axial length, which is about the axial length of the receiving stage 100 equivalent. Thus, the valve housing is adjacent 102 about at the the stepped bore 82 penetrating high-pressure branch channel 74 at. From an outer circumferential surface of the valve 102 here is an annular groove 108 in the valve body 102 introduced for the arrangement of an O-ring seal. The valve housing 102 has one further in the direction of the bore stage 104 of the valve body 24 extending axial projection 110 who is in the drilling stage 104 cantilevers. In the middle is the valve housing 102 approximately coaxial to the stepped bore 82 from a pilot hole 112 interspersed, in which a guide pin 114 is guided in a sliding manner. This protrudes with its two end portions of the valve housing 102 out. At its in the direction of the pad 80 pointing end section 116 is a plate-shaped valve body 118 attached, which is approximately coaxial with the guide pin 114 is arranged. The valve body 118 has an annular to the valve body 102 facing sealing surface 120 that seal against one of the top 106 of the valve block 24 pointing away base 122 of the valve housing 102 can be present. In the in 4 shown position is the sealing surface 120 from the bottom 122 spaced, causing the low pressure valve 20 in its open position. As a result, three in the valve housing 102 introduced kidney-shaped low-pressure channels 124 with the high pressure branch channel 74 connected. The low pressure channels 124 are arranged on a pitch circle, pass through the valve body 102 in the longitudinal direction completely and include the guide bore 112 of the valve housing 102 , Lies the sealing surface 120 on the bottom 122 on, so is a pressure medium connection between the low-pressure channels 124 and the high-pressure branch channel 74 interrupted and the low pressure valve 20 closed. The low pressure channels 124 each lead into a respective one in the valve block 24 introduced kidney-shaped low-pressure channel 126 , Thus, there are also three low-pressure channels 126 in the valve block 24 provided, wherein in the 4 only one of them is visible. The low pressure channels 126 are, in the radial direction of the low pressure valve 24 seen, towards the Bohrungsstufe 104 open and have the same axial length as the bore stage 104 on, making them in the top 106 of the valve block 24 lead. The low pressure channels 126 are thus with the of the casing 42 out 1 limited low pressure space of the radial piston machine 1 connected.

For actuating and moving the guide pin 114 together with the valve body 118 is an electrical actuator 128 intended. This is in a cup-shaped actuator housing 130 arranged on the opening side of the axial projection 110 of the valve housing 102 dips in and determines this. The actuator housing 130 extends through the bore stage 104 through and cantilevers out of the valve block 24 out. In the actuator housing 130 is a magnetic coil 132 arranged, which has an axially displaceable armature 134 embraces. The magnet armature 134 is with the guide pin 114 connected. For the sake of clarity, a more detailed explanation of the configuration of the actuator is provided 128 of the low pressure valve 20 based on 5 that a section of the valve body 24 out 4 in the area of the low pressure valve shows.

According to 5 cant the guide pin 114 with its end section 136 from the valve body 102 in the direction of the actuator 128 out. The end section 136 is radial with a radial collar 138 extended, that of one in a through hole 140 of the magnet armature 134 trained inner waistband 139 is behind.

An approximately coaxial with the guide pin arranged valve spring 142 rests against one of the magnetic coil 132 gripped and in the actuator housing 130 fixed pole piece 144 Dive into the through hole 140 of the magnet armature 134 and urges one towards the top 106 of the valve block 24 pointing face 146 of the guide pin 114 with a spring force.

The magnet armature 134 is between the valve body 102 and the pole piece 144 arranged axially displaceable. The valve spring 142 rests on the pole piece 144 over a step of a continuous stepped bore 150 of the pole piece 144 from. The pole piece 144 passes through the actuator housing 130 axially in its bottom surface, whereby the stepped bore 150 of the pole piece 144 with that of the sheath 42 out 1 limited low pressure range of the radial piston engine 1 connected is. One between the pole piece 144 and the armature 134 trained space 152 is over the stepped bore 150 of the pole piece 144 thus also connected to the low pressure area. For pressure equalization of axial surfaces of the magnet armature 134 this is from a plurality of axial bores 154 interspersed with the gap 152 are connected. For electrical contacting of the actuator 128 has this outwardly projecting tabs 156 on.

In the in the 5 shown position is the low pressure valve 20 in its open position. Here is the magnetic coil 132 of the actuator 128 de-energized, causing the guide pin 114 together with the magnet armature 134 away from the pole piece 144 by a spring force of the valve spring 142 is moved. To limit a displacement of the guide pin 114 is the magnet armature 134 at the axial projection 110 of the valve housing 102 at. To close the low pressure valve 20 becomes the magnetic coil 132 of the actuator 128 energized, causing the armature 134 via a magnetic force of the magnetic coil 132 against the spring force of the valve spring 142 away from the valve body 102 in the direction of the pole piece 144 is moved. The magnet armature 134 takes over his inner waistband 139 the guide pin 114 via its radial collar 138 With. The valve body 118 of the low pressure valve 20 , see also 4 , passes here with its sealing surface 120 to the bottom 122 of the valve housing 102 and seals the low pressure channel 124 to the high pressure branch channel 74 from.

The high pressure valve 18 out 4 is in parallel distance to the low pressure valve 20 in the valve block 24 added. The high pressure valve 18 has a valve spool 158 that in a slide hole 160 slidably guided. This passes through the valve block 24 approximately in parallel distance to the stepped bore 82 of the low pressure valve 20 completely, with the valve block 24 in the area of the slide bore 160 about half as thick as in the area of the stepped bore 82 is. The slide bore 160 thus extends from the pad 80 seen from approximately in the longitudinal direction approximately to the central region of the recording stage 100 the stepped bore 82 , In the slide bore 160 two pressure chambers open 162 and 164 in the longitudinal direction of the slide bore 160 seen offset from each other are arranged. With the valve slide 158 is doing a pressure medium connection between the pressure chambers 162 and 164 opened and closed. The pressure room 162 is between the pad 80 of the valve block 24 and the pressure room 164 arranged. The radially into the slide bore 160 introduced pressure chambers 162 and 164 embrace them completely. The Indian 4 upper pressure chamber 164 is with the high pressure branch channel 74 connected. The lower pressure chamber 162 is against it in the 4 not shown approximately coaxial with the slide bore 160 in the direction of the connection surface 80 of the valve block 24 connected extending channels. These sit over the connection surface 80 in the central part 2 out 1 and 3 and are adjacent to the valve block 24 arranged high-pressure channel 40 connected. Thus, the work space 68 the cylinder-piston unit 14 in 3 over the check valve 76 with the high pressure channel 30 and over the high pressure valve 18 out 1 with the high pressure channel 40 be connected fluidly.

A closer explanation of the high pressure valve 18 is based on 6 that made a cut out 4 in the area of the high pressure valve 18 shows. According to 6 is the valve spool 158 designed as a hollow slide, where it towards the connection surface 80 of the valve block 24 is designed open and towards the top 106 a floor 166 Has. The valve spool 158 has an annular groove formed by its outer circumferential surface 168 on, creating a control edge 170 is formed. With this a pressure fluid connection between the pressure chambers 162 and 164 opened and closed. In the in the 6 shown position is the valve spool 158 in a closed position, in which the pressure medium connection between the pressure chambers 162 and 164 closed is. The valve spool 158 is moved in the direction of its closed position by a valve spring 172 acted upon by a spring force. This is supported by a spring plate 174 in the mounted state of the valve block 24 on the side surface 70 of the central part 2 out 3 is applied. The valve spring 172 extends from the spring plate 174 out through the hollow valve spool 158 and impose this on his soil 166 with a spring force. The spring plate 174 has a centering projection in the middle 176 for centering the valve spring 172 , In the in 6 shown closed position of the high pressure valve 18 the valve slide is supported 158 with his bottom 166 on a pole piece 178 an electromagnetic actuator 180 from. The pole piece 178 has an end section 182 , seen in the longitudinal direction sections in the slide bore 160 , please refer 4 , dips. Following the end section 182 is the pole piece 178 with a radial collar 184 extended and supported on this on a cup-shaped actuator housing 186 in radial and axial direction. The actuator housing 186 is about a fastener 188 on the valve block 24 screwed. Furthermore, the actuator housing 186 to the valve spool 158 designed open and has a introduced from this side lowering 190 at the pole piece 178 with his Radialbund 184 supported. The pole piece has the radial collar 184 seen in the longitudinal direction another end portion 192 that of a magnetic coil 194 is encompassed. One from the valve spool 158 pointing away face 196 of the pole piece 178 serves as a stop surface for one in the actuator housing 186 longitudinally displaceable armature 198 , About this is the valve spool 158 moved to its open position by the armature 198 over a pestle 200 on the ground 166 of the valve spool 158 attacks. According to 4 is the pestle 200 in a guide hole 202 of the pole piece 178 led the pole piece 178 completely interspersed. The plunger also has a magnet armature 198 passing end section 204 , which is radially stepped back, whereby one of the valve spool 158 pointing away ring end face 206 on the pestle 200 is formed, over which the armature 198 for moving the plunger 200 is applied.

In the closed position of the high pressure valve 18 according to 4 is between the armature 198 and the pole piece 178 a gap 208 who has one in the actuator 180 out 6 trained channel and over in the actuator housing 186 introduced through holes 210 with the low-pressure region of the radial piston engine 1 connected is.

For frontal pressure relief of the valve spool 158 this valve spring side is one in the connection surface 80 introduced groove 212 connected to the low pressure area. The pole piece 178 facing side of the valve spool 158 is about one from the top 106 introduced groove 214 and one with the groove 214 connected and in the pole piece 178 introduced transverse groove 216 also connected to the low pressure area. The spring side and the pole piece side of the valve spool 158 in turn are over in the ground 166 introduced axial bores 218 together in pressure medium connection.

To 6 becomes the actuator 180 of the low pressure valve 18 over contact flags 220 electrically contacted.

According to 4 extends the high-pressure branch channel 74 from the pressure room 164 out over the stepped bore 82 of the low pressure valve 20 and then along a curve to the pad 80 , A mouth opening 222 of the high pressure branch channel 74 is from one in the valve block 24 from the connection surface 80 ago introduced annular groove 224 encompassed for receiving an O-ring.

In the 7 is a plan view of the valve block 24 of the 4 shown. Here is the fastener 188 from the 6 recognizable. This is designed plate-shaped and has a recess 226 on, over which the fastener 188 the actuator housing 186 embraces. The fastener 188 lies on an outer collar 228 of the actuator housing 186 on and is about two screws 230 on the valve block 24 attached. Furthermore, in the 7 the groove 214 recognizable, extending approximately in the longitudinal direction of the valve block 24 to the slide bore 160 in 4 extends. In a top of the actuator housing 186 of the high pressure valve 20 are three kidney-shaped recesses 232 brought in. These serve according to the 6 for connecting a gap 234 with the low-pressure region of the radial piston engine 1 where the gap 234 from the actuator housing 186 and one of the valve spool 158 groundbreaking side of the magnet armature 198 is limited.

In the area of the low pressure valve 20 has the valve block 24 a cylindrical section 236 , see also 4 , In this are the kidney-shaped low pressure channels 126 educated. Furthermore, in the cylindrical section 236 three threaded holes 238 for example between the low-pressure channels 126 introduced in the axial direction, for fixing an electrical contact for the contact lugs 156 and 220 serve.

The valve block 24 will have four through holes 240 that from the top 106 are introduced in this, at the central part 2 , please refer 3 , for example, fastened by screws.

For centering the valve block 24 at the central part 2 are according to 4 centering 242 one of which is in the 4 is apparent. These are from the bottom 80 of the valve block 24 used in these and dive when mounting the valve block 24 in corresponding center holes of the central part 2 one.

The following is the operation of the radial piston machine 1 explained. In pump operation of the radial piston machine 1 is in the suction stroke, ie in the direction of the increasing work space 68 , the cylinder-piston unit 14 out 3 Pressure medium via the opened low pressure valve 20 aspirated from the low pressure area. Here, pressure medium flows through the low-pressure channels 126 , please refer 4 , via the low pressure channels 124 , via the connection socket 66 and the socket 56 , please refer 3 , in the workroom 68 , The high pressure valves 18 and 22 are closed here. In the displacement stroke of the piston 16 the cylinder-piston unit 14 becomes the pressure medium when the high pressure valve is closed 18 , please refer 4 , and closed low pressure valve 20 over the high-pressure branch channel 74 , please refer 3 , via the check valve 76 in the high-pressure channel 30 promoted.

In engine operation, the piston 16 in a lifting movement in the direction of the increasing work space 68 out 3 acted upon by the high pressure. This is the low pressure valve 20 out 4 closed, and the high pressure valve 18 opened, whereby pressure medium from the high-pressure channel 40 out 1 over the pressure room 162 and 164 in the high pressure branch channel 74 flows and from there continue to work space 68 , During a movement of the piston 16 in the direction of the decreasing workspace 68 out 3 becomes the pressure medium when the high pressure valve is closed 18 and opened low pressure valve 20 out 4 over the low pressure channels 124 and 126 in the low-pressure region of the radial piston engine 1 ejected.

By the valve block according to the invention 24 can use the high and low pressure valves 18 and 20 out 4 be pre-assembled and independent of the radial piston machine 1 out 2 being checked. During maintenance of the radial piston machine 1 can the valve block 24 simply unscrewed, and the high and low pressure valve 18 and 20 Here too, independent of the rest of the radial piston engine 1 be checked and maintained.

For example, if the arrangement or design of the high and / or low pressure valve 18 and 20 out 4 be changed, it is in the radial piston engine according to the invention 1 only necessary, the valve block 24 adjust accordingly. An adaptation of the central part 2 is not necessary, as long as the interfaces between valve block 24 and the central part 2 stay the same.

Disclosed is a digitally adjustable radial piston machine which has a central part. In this case, a low-pressure valve and at least one high-pressure valve are assigned to a respective cylinder-piston unit of the radial piston engine. Furthermore, a valve block is provided for each cylinder-piston unit, in which the low and / or high pressure valve is received. The valve blocks are mounted on the central part.

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

• WO 2008/012558 A2 [0003]
• EP 2187104 B1 [0005]
• DE 102010004808 A1 [0007]

Cited non-patent literature

• Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment by the authors SH Salter, JRM Taylor and NJ Caldwell [0006]

Claims (11)

Hydraulic radial piston machine with cylinder-piston units ( 14 ), whose pistons ( 16 ) on a drive shaft ( 4 ), characterized in that the radial piston engine ( 1 ) a central part ( 2 ), to the individual valve blocks ( 24 . 26 . 28 ) corresponding to a number of cylinder-piston units ( 14 ) are mounted, wherein a respective valve block ( 24 . 26 . 28 ) a low pressure and / or high pressure valve ( 18 . 20 ). Radial piston machine according to claim 1, wherein the valve block ( 24 . 26 . 28 ) a high pressure branch channel ( 74 ), which extends over a connection surface ( 80 ) in the central part ( 2 ) and into a high-pressure channel ( 30 ) of the central part ( 2 ) opens. Radial piston machine according to claim 2, wherein the central part ( 2 ) so much high-pressure channels ( 30 - 40 ) as arranged in a radial plane cylinder-piston units. Radial piston machine according to one of the preceding claims, wherein the high-pressure valve ( 18 ) at least one valve block ( 24 ) an actively controllable high pressure valve ( 18 ). Radial piston machine according to one of the preceding claims, wherein the low-pressure valve ( 20 ) at least one valve block ( 24 ) an actively controllable low-pressure valve ( 20 ). Radial piston machine according to one of the preceding claims, wherein a cylinder-piston unit ( 14 ) associated passive high pressure valve ( 76 ) in the central part ( 2 ) is arranged. Radial piston machine according to claim 6, wherein the passive high pressure valve ( 76 ) a pressure medium connection between the high pressure channel ( 30 ), in which the high-pressure branch channel ( 74 ) the cylinder-piston unit ( 14 ), and the high-pressure branch channel ( 74 ) controls. Radial piston machine according to one of the preceding claims, wherein a cylinder ( 58 ) a cylinder-piston unit ( 14 ) to the outside at the central part ( 2 ) is supported. A radial piston machine according to claim 8, wherein the support is pivotally mounted on a central part ( 2 ) inserted socket ( 56 ) he follows. Radial piston machine according to one of the preceding claims, wherein the central part ( 2 ) a disk with a plurality of cylinder-piston units ( 14 ) is in a single radial plane or wherein the central part ( 2 ) is a monoblock that is in several radial planes ( 44 . 46 . 48 . 50 ) a plurality of cylinder-piston units ( 14 ) having. Radial piston machine according to one of the preceding claims, wherein an electrical contacting of the high and low pressure valves ( 18 . 20 ) on the respective valve block ( 24 ) he follows.

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