This application is a 35 U.S.C. § 371 National Stage Application of PCT/EP2017/053696, filed on Feb. 17, 2017, which claims the benefit of priority to Serial No. DE 10 2016 203 847.8, filed on Mar. 9, 2016 in Germany, the disclosures of which are incorporated herein by reference in their entireties.
The disclosure concerns a piston pump, in particular for a motor vehicle, with a piston which is movably mounted in a housing, with a linear actuator for moving the piston in a first direction, and with a return spring for moving the piston in a second direction, wherein the end face of a first end of the piston delimits a first pressure chamber assigned to a first hydraulic circuit.
Piston pumps of the type cited initially are known from the prior art. Various systems in motor vehicles are actuated hydraulically. These include in particular vehicle braking systems which have one or more high-pressure pumps to support or generate the braking force, and serve for metering the brake pressure. Usually, these high-pressure pumps are formed as piston pumps in which a piston, which is movably mounted in a cylinder, is moved periodically or in reciprocating fashion by an actuator in order to periodically enlarge and reduce the volume of the pump chamber. The pump chamber is connected to a hydraulic circuit for example by one or two check valves, so that hydraulic medium is drawn into the pump chamber on a first movement of the piston and expelled again on a second movement. It is known to form the actuator for moving the piston as a linear actuator which is able to load the piston with an actuator force in a first movement direction. The movement force is generated by a magnetic force provided by a powered magnetic coil of the actuator. Because the piston can be moved thereby in one direction only, a return spring is also assigned to the piston which moves the piston back to the starting position after an actuation process.
The disadvantages of the known solution are the actuation force available, the actuation frequency, and the comparatively high energy consumption of the linear actuator. In particular in comparison with rotating electric motors, the energy consumption is increased, in particular because the piston must be accelerated alternately in different movement directions.
The piston pump according to the disclosure with the features described herein has the advantage that the efficiency of the piston pump is increased, so that the advantages of a piston pump with linear actuator may also be utilized in a high-pressure application in the motor vehicle. Because of the linear actuator, the piston movement may be controlled by changing the amplitude and frequency independently of each other. In this way, a precise pressure build-up at the desired time can be reliably achieved. In contrast to a rotating electric motor as an actuator, noise and wear are also reduced. In particular, there are no weak points which restrict the service life, such as in particular ball-bearings and commutator or slip ring devices. The piston pump according to the disclosure also provides a pumping power which in particular meets the requirements of vehicle braking systems. According to the disclosure, this is achieved in that the end face of a second end of the piston delimits a second pressure chamber. Thus independently of the movement direction of the piston, a pumping and a suction process are performed by the movement of the piston into a respective pressure chamber. The delivery volume of the piston pump is thus doubled.
According to a preferred refinement of the disclosure, it is provided that the linear actuator has an armature fixedly connected to the piston, and a stator arranged stationarily on the housing, coaxially to the piston, wherein the stator lies between the two pressure chambers. The piston pump thus has a particularly compact form in which the stator, and hence the linear actuator, is arranged substantially between the two pressure chambers.
Furthermore, it is preferably provided that the second pressure chamber is assigned to the first hydraulic circuit. Thus the piston pump serves to generate a hydraulic pressure in a hydraulic circuit, wherein a pressure is generated in this hydraulic circuit independently of the movement direction of the piston. Thus both movement directions of the piston serve to fill the one hydraulic circuit and to generate a braking pressure for example. In comparison with conventional piston pumps therefore, because of the two pressure chambers, for example a pressure can be generated in the first hydraulic circuit twice as quickly as before. Alternatively, according to a further embodiment, it is preferably provided that the two pressure chambers are assigned to different hydraulic circuits, so that the second pressure chamber is or can be connected to a second hydraulic circuit. In this way, by means of the advantageous piston pump, a hydraulic pressure can be generated in two hydraulic circuits almost simultaneously.
According to a preferred refinement of the disclosure, it is provided that at least one check valve is assigned to each pressure chamber. Depending on the pressure conditions, the check valve automatically allows the supply into the pressure chamber or the outlet from the pressure chamber, while a backflow is securely prevented.
Preferably, each pressure chamber has a first check valve at an intake port and a second check valve at a pressure port, so that both the intake and the outlet may be regulated by automatic check valves. This gives a simple and compact construction of the piston pump.
Furthermore, it is preferably provided that the first pressure chamber is arranged in a first housing part and the second pressure chamber is arranged in a second housing part, wherein the two housing parts lie closely against each other, enclosing the linear actuator between them. The housing of the piston pump thus becomes a function part. It is substantially formed by two housing parts which each comprise one of the pressure chambers. Because the two housing parts lie against each other and enclose the linear actuator between them, firstly the linear actuator is securely held between the two housing parts with relatively simple geometries, and secondly in a simple fashion an advantageous tightness of the piston pump is guaranteed. Because of the simple geometric form, a precision (necessary at high pressure) can be achieved. Also, the piston pump is simple to install and construct. The two housing parts may be formed as housing halves or as different types of housing parts which are however formed complementarily to each other. In particular, it is provided that each of the housing parts receives at least regions of the linear actuator, in particular the stator of the linear actuator. For this, the respective housing part suitably has a depression adapted to the form of the stator in order to receive this by form fit and in particular snugly. In particular, the housing parts are configured such that in mounted state, the stator is clamped between the two housing parts so that a high tightness is guaranteed.
According to an advantageous refinement of the disclosure, it is also provided that the housing parts have mutually aligned bores which are each fluidically connected firstly to one of the pressure chambers and secondly to a consumer. The bores thus serve as fluid channels of the piston pump. Because the bores are formed aligned to each other, in particular the pressure chambers of the two housing parts can be connected together fluidically. In this way, it is possible in particular for both pressure chambers to be assigned to the same hydraulic circuit in order to jointly supply a consumer with hydraulic pressure. Because of the aligned formation or orientation of the bores, a simple and secure fluidic conduction from the one housing part to the other housing part is guaranteed.
Preferably, it is provided that at least one sealing element, in particular an O-ring, is assigned to the bores, which increases the tightness of the piston pump. In particular, the O-ring is arranged coaxially to the bores. In particular, the O-ring or sealing element lies between the two housing parts resting against each other, and is elastically deformed or pretensioned in order to achieve a particularly great sealing effect.
Furthermore, preferably it is provided that in the region of the bores, one of the housing parts has a protrusion and the other of the housing parts has a depression corresponding to the protrusion, so that on installation, the protrusion is inserted into the depression, creating a form-fit connection between the two housing parts. In addition, a type of labyrinth seal is created which further increases the tightness of the piston pump. The sealing element may, as described above, lie on the end faces between the two housing parts or lie between the casing wall of the protrusion and the casing wall of the depression in order to guarantee a radial seal.
Furthermore, it is preferably provided that the protrusion is held in the depression by force and/or form fit. The force fit is guaranteed for example by a press fit between the protrusion and the depression. The form fit is guaranteed in particular in that on installation, the protrusion and/or the depression is elastically deformed in order to create an undercut which securely holds the protrusion and depression against each other.
The disclosure is explained in more detail below with reference to the drawing. The drawing shows:
The pressure chamber 11 is formed by an insert part 12 which is inserted in the housing part 3 and, with a beaker-like portion, forms the pressure chamber 11. Two check valves 13, 14 are arranged in the casing wall of the insert part 12, of which the one check valve 14 opens when the pressure in the pressure chamber 11 exceeds the pressure in a connected hydraulic channel 16, and the other check valve 13 opens in the direction of the pressure chamber 11 when the pressure in the pressure chamber 11 falls below a pressure in a hydraulic channel 15 leading to the pressure chamber 11. When the first end of the piston 8 protrudes into the pressure chamber 11, the hydraulic medium is pressed into the hydraulic channel 16 through the check valve 14. When the piston 8 is withdrawn from the pressure chamber 11, a reduced pressure is created in the pressure chamber 11 which draws hydraulic medium from the hydraulic channel 15 into the pressure chamber 11.
On the side of the piston 8 opposite the end 10, a further pressure chamber 17 is arranged in the housing part; a second end 18 of the piston 8 protrudes into said further pressure chamber 17 such that said second end 18 delimits the volume thereof. The pressure chamber 17 is also formed by an insert part 18 which is however inserted in the housing part 2. A check valve 19, 20 is arranged respectively on the inlet side and the outlet side in the casing wall of the beaker-like insert part 18, and is connected to a respective hydraulic channel 21, 22 in the housing part 2 in order as required to draw hydraulic fluid from the hydraulic channel 21 and deliver it to the hydraulic channel 22.
The piston pump 1 is thus configured as a double piston pump in which, independently of the movement direction of the piston, a hydraulic pressure is generated in one of the pressure chambers and at the same time a reduced pressure is generated in the other of the pressure chambers in order to draw in fresh hydraulic medium.
When the coil 6 is powered, a magnetic field is generated which moves the armature 7 and hence the piston 8 in the direction of the second pressure chamber 17. The armature 7 is displaced against the force of a return spring 23. When the return spring 23 is in the relaxed state, the armature 7 lies offset to the stator 5, so that by generation of the magnetic field the armature 7 is attracted and hence moved against the force of the spring element 23. As soon as the stator 5 is no longer powered or activated, the return spring 23 pushes the armature 7 back in the direction of the pressure chamber 11, whereby a further pumping process is performed there and a further suction process in the pressure chamber 17.
The linear actuator 4 is to this extent formed as a single-phase reluctance machine. The stator 5 with the coil 6 is arranged coaxially to the armature 7 or piston 8. The armature 7 is in particular made of a ferromagnetic material. The armature 7 is preferably also formed concentrically and separated from the stator by a small working air gap. In particular, all elements of the magnetic circuit or linear actuator 4 are arranged rotationally symmetrically about the piston axis of the piston 8 or piston pump 1. The housing parts 2, 3 are advantageously made of a non-magnetic material and carry the active elements, and thus structurally guarantee as precise a centrality as possible with a minimum air gap.
The coil 6 is powered and activated by a voltage source, for example an on-board network of a motor vehicle, by means of corresponding power electronics. The size of the voltage amplitude and the duration of the power supply determined by the power electronics determine both the deflection/amplitude of the armature 7 or the piston 8, and also its movement frequency. Preferably, the frequency is set in the region of the mechanical inherent frequency of the linear actuator 4.
The two pressure chambers 11, 17 may be connected to different hydraulic circuits. In the present case however, it is provided that the pressure chambers 17, 11 are or can be connected to the same hydraulic circuit. For this, the hydraulic channels 16 and 22, and the hydraulic channels 15 and 21, are respectively connected hydraulically together and to a consumer (not shown here). The merging of the channels 15 and 21, and of the channels 16 and 22, in this case takes place through bores 24, 25 in the housing parts 2, 3, which bores are formed parallel to the piston axis or movement direction of the piston 18.
According to the first exemplary embodiment of
The exemplary embodiment in
The exemplary embodiment of
Number | Date | Country | Kind |
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10 2016 203 847.8 | Mar 2016 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/053696 | 2/17/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/153153 | 9/14/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2283886 | Henkell | May 1942 | A |
2833220 | Robinson | May 1958 | A |
2872101 | Ryba | Feb 1959 | A |
3053194 | Webster | Sep 1962 | A |
4787823 | Hultman | Nov 1988 | A |
6290308 | Zitzelsberger | Sep 2001 | B1 |
20060127251 | Okubo | Jun 2006 | A1 |
Number | Date | Country |
---|---|---|
29 03 817 | Aug 1980 | DE |
2903817 | Aug 1980 | DE |
10 2013 214 216 | Feb 2014 | DE |
102013214216 | Feb 2014 | DE |
10 2013 218 064 | Jun 2014 | DE |
10 2013 218 068 | Jun 2014 | DE |
638585 | Jun 1950 | GB |
2001-41147 | Feb 2001 | JP |
2001-41148 | Feb 2001 | JP |
2001041147 | Feb 2001 | JP |
2001041148 | Feb 2001 | JP |
2005-180332 | Jul 2005 | JP |
2008-101788 | May 2008 | JP |
2008101788 | May 2008 | JP |
2015-530513 | Oct 2015 | JP |
Entry |
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International Search Report corresponding to PCT Application No. PCT/EP2017/053696, dated May 10, 2017 (German and English language document) (7 pages). |
Number | Date | Country | |
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20200309117 A1 | Oct 2020 | US |