The disclosure relates to a valve arrangement.
In valve arrangements according to the prior art, housings of cartridge design are known which can be inserted into an opening of a hydraulic apparatus.
DE 10 2007 044 451 A1 discloses a pressure control valve of this type with a housing of cartridge design which is screwed into a connection plate of a hydrostatic piston engine.
GB 2 367 095 A likewise discloses a pressure control valve and DE 296 20 927 U1 discloses a nonreturn valve of cartridge design.
It is a disadvantage of valves of this type that only one valve is accommodated in a cartridge.
Furthermore, it is known from the prior art to combine two valves in one housing. DE 101 36 416 A1 discloses a combination of this type comprising pressure control valve and delivery flow control valve. A housing of the two valves is configured in a flange design with single-sided connections. Since the housing has to be fastened to an outer surface of an associated hydraulic apparatus, the space requirement is correspondingly great.
In contrast, the disclosure is based on the object of providing a valve arrangement having at least two valves, the space requirement of which is minimized.
This object is achieved by a valve arrangement having the features of the disclosure.
The valve arrangement according to the disclosure has a combination of at least two valves, a common housing of the two valves being configured as an insertion cartridge. The space requirement of the valves is minimized by way of this compact arrangement.
Further advantageous refinements of the disclosure are described in the dependent patent claims.
Each valve preferably has a control piston which can be moved in a valve bore.
It is particularly space-saving if the compact insertion cartridge is inserted partially or entirely into a hydraulic apparatus. The apparatus can be, for example, a variable displacement pump. In particular, it is therefore preferred if the insertion cartridge can be screwed about its center axis into the hydraulic apparatus.
In order to minimize the production outlay, it is preferred if the valve longitudinal axes of the valve bores run parallel to the center axis.
One preferred development of the valve arrangement according to the disclosure has connections which are connected to various or to all valve bores, with the result that the connections can be controlled by various or by all control pistons. In this way, the production outlay for the valve arrangement can be reduced further, and its insertion cartridge can be reduced further in size.
Depending on the design, it can be advantageous if the valve bores have different diameters.
In one particularly preferred exemplary embodiment having two valves, the valve arrangement according to the disclosure is a pressure/delivery flow regulator for a variable displacement pump. Here, in addition to a connection for a load signaling line, further connections are provided on the outer circumference of the insertion cartridge or on the end side.
In order to screw in the insertion cartridge, an apparatus for torque transmission is preferred which is arranged within an end-side face of the insertion cartridge. Since apparatuses for torque transmission are thus avoided on the outer edge and on the outer circumference of the insertion cartridge, the diameter of the insertion cartridge and, in particular, that of a receptacle for the insertion cartridge on the hydraulic apparatus are minimized.
Here, at least one circular-cylindrical section is preferred which is spaced apart from the center axis and on which or within the circumference of which an action face for a tool is formed.
Here, if the circular-cylindrical section forms an eccentric circular-cylindrical hole, the insertion cartridge is configured as an eccentric screw.
In another preferred variant, a setting screw is screwed into an associated valve bore and serves to set a parameter (for example, spring stress) of the corresponding valve. Here, a total of six circular-cylindrical sections are provided on a hexagon socket of the setting screw in each case between its edges. In this way, six action faces for the tool for screwing in the insertion cartridge are integrated into the hexagon socket, as a result of which the setting screw has a dual function.
In another variant with minimum outlay for the circular-cylindrical sections, the latter are arranged in the valve bores.
As one preferred addition to the valve arrangement according to the disclosure, a special key is proposed as tool, which special key has at least one projection with a circular-cylindrical section. Said projection can be brought into contact with at least one associated circular-cylindrical section of the insertion cartridge or can be inserted into the hole. In the variant with the hexagon socket, the projection of the tool is accordingly brought into contact here with six circular-cylindrical sections.
The valve bores and/or the eccentric holes can be configured as blind bores.
For screwing in, as an alternative or in addition to the circular-cylindrical sections, the insertion cartridge can have a dihedron with two flat sections.
As a simple securing means against the control pistons falling out, a stop pin is preferred which is arranged approximately transversely with respect to the valve bores and by way of which the travel of the control pistons in the valve bores is limited.
Here, it is simple is terms of production technology if the stop pin is pressed into a transverse bore of the insertion cartridge.
In the following text, different exemplary embodiments of the disclosure will be described in detail using the figures, in which:
Each valve has a valve bore 20, 22, which are shown in
Furthermore, additional circular-cylindrical recesses or holes 8, 10 of small diameter are arranged on the end side on the insertion cartridge 1, which recesses or holes 8, 10 lie diametrically opposite one another with regard to the center axis 6 and are offset with respect to the holes 2, 4 by 90 degrees. The spacing of the axis of the respective hole 8, 10 from the center axis 6 is greater than the spacing of the respective hole 2, 4.
As an alternative, the two holes 8 and 10 can also be used to screw in the insertion cartridge 1, for example if damage to the holes 2, 4 is to be feared. The special key then also has to be modified with respect to that special key shown in
In said first exemplary embodiment, the outer diameter of the insertion cartridge 1 is at a minimum, since no device for torque transmission (for example, an external hexagon) has to be attached to its outer circumference. Moreover, the insertion cartridge 1 of the first exemplary embodiment is screwed into the variable displacement pump in such a way that the end face of the insertion cartridge 1 lies approximately on one plane with the corresponding surface of the variable displacement pump. The required installation space of the valve arrangement according to the disclosure is therefore at a minimum.
Here, the control pistons 24, 26 are loaded firstly by the pressure of the connection 32 and secondly by the force of a respective spring 34, 36.
The prestress of the springs 34, 36 can be set via a respective setting screw 38, 40 which is screwed into a region of the respective valve bore 20, 22, which region is arranged adjacently to the respective end section or hole 2, 4. The spring space on the control piston 26 is open to the outside via a bore 35. Via said bore 35, the spring space and therefore the control piston 26 can be loaded by a control pressure, for example by the highest load pressure of all hydraulic consumers which are supplied at the same time by a pump, on which the valve arrangement is situated. The spring space with the spring 34 is connected to the connection 28 via a groove or flattened portion 37 on the control piston 24.
Furthermore, the valve arrangement 203 and the variable displacement pump 205 have a common tank connection T. Moreover, the valve arrangement 203 has a load signaling connection LS, via which the highest working pressure is signaled from a plurality of consumers which are supplied by the variable displacement pump 205 via the working line 213.
The valve arrangement 203 has a pressure control valve 217 and a delivery flow control valve 219. Both valves 217, 219 are configured as proportionally adjustable 3/2-way valves and have an adjustable spring 234, 236 which acts in the direction of the basic position (shown in
Furthermore, the pump pressure in the working line 213 acts on the control pistons of the valves 217, 219 via the connection P and the control pressure line 215. Therefore, as the pump pressure of the working line 213 increases, the valves 217, 219 are set in such a way that pump pressure is increasingly connected via the control pressure connection P and the control pressure line 215 to the control pressure connection A, and the variable displacement pump 205 is therefore pivoted back.
A continuous transverse bore 223 which will be explained in relation to
A dihedron, of which only one flat section 225a is shown in
The movement of the control pistons 224, 226 and of the assigned spring collars 227, 229 to the right (in
In each case one sealing ring 253 is arranged on the outer circumference of the insertion cartridge 201 between the right-hand (in
A spring space of the delivery flow control valve 219 is connected via a transverse bore to the load signaling connection LS, whereas a spring space of the pressure control valve 217 is connected to the tank connection T via a pressure-medium connection which is formed between the control pistons 226 and the valve bore 222 and via a transverse-bore section.
By way of the basic positions, shown in
A transverse bore 331 is provided between the outer circumference of the insertion cartridge 301 and the pressure-medium connection which is formed between the valve bore 320 and the control piston 224 of the delivery flow control valve 319, which transverse bore 331, on account of its small diameter, represents a throttled connection between the pressure-medium connection and the tank connection T of the valve arrangement according to the disclosure.
Spring collars 327, 329 are formed in each case integrally with a stop pin, the action of which is consistent with that of the stop pins 233, 235 of the first variant according to
Setting screws 338, 340 are screwed via a respective hexagon socket into the valve bores 320, 322 and therefore serve to set the respective prestress of the springs 234, 236. The setting screws 338, 340 are fixed by way of respective lock screws 333, 335 which are likewise screwed into the respective valve bore 320, 322. The lock screws 333, 335 in each case have a continuous hexagon socket which is larger than the respective hexagon socket of the setting screws 338, 340.
Furthermore, a securing ring 337, 339 is inserted into each valve bore 320, 322, with the result that the setting screws 338, 340 and their lock screws 333, 335 are secured against falling out and, in particular, against falling out in a pressure-loaded way.
Finally, the second variant of the third exemplary embodiment according to
In a difference from the first exemplary embodiment according to
In a difference from the first variant of the third exemplary embodiment according to
In a difference from the first variant of the third exemplary embodiment according to
In a difference from the first variant of the third exemplary embodiment according to
A valve arrangement is disclosed having at least two valves and having a housing which is configured as an insertion cartridge. The valve arrangement can have, for example, two valves, of which one is a pressure regulator and the other is a delivery flow regulator. A valve arrangement of this type can be inserted or screwed, for example, into a variable displacement pump, as a result of which the space requirement of the valve arrangement can be minimized.
Number | Date | Country | Kind |
---|---|---|---|
10 2010 015 196 | Apr 2010 | DE | national |
10 2010 048 068 | Oct 2010 | DE | national |
This application is a continuation application of application Ser. No. 13/641,599, filed on Dec. 24, 2012 (now U.S. Pat. No. 8,985,138), which in turn is a 35 U.S.C. §371 National Stage Application of PCT/EP2011/001609, filed on Mar. 30, 2011, which claims the benefit of priority to Serial No. DE 10 2010 015 196.3, filed on Apr. 16, 2010 in Germany and Serial No. DE 10 2010 048 068.1, filed on Oct. 9, 2010 in Germany, the disclosures of which are incorporated herein by reference in their entirety.
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Number | Date | Country |
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296 20 927 | May 1998 | DE |
101 36 416 | Feb 2003 | DE |
20 2007 012 652 | Dec 2007 | DE |
10 2007 044 451 | Mar 2009 | DE |
2 367 095 | Mar 2002 | GB |
Entry |
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International Search Report corresponding to PCT Application No. PCT/EP2011/001609, mailed Aug. 1, 2011 (German and English language document) (6 pages). |
Number | Date | Country | |
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20150226349 A1 | Aug 2015 | US |
Number | Date | Country | |
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Parent | 13641599 | US | |
Child | 14643357 | US |