Applicant hereby claims foreign priority benefits under U.S.C. ยง119 from European Patent Application No. EP15154615.7 filed on Feb. 11, 2015, the content of which is incorporated by reference herein.
The present invention relates to a hydraulic device comprising a first member movable relative to a second member, said first member having a pressure chamber opening in a face of said first member which is in contact with a contact face of said second member, said second member having a low pressure area, wherein a throttling flow path is provided in a groove connecting said pressure chamber and said pressure area when said pressure chamber is approaching said low pressure area.
Such a hydraulic device is known, for example, from EP 0 679 227 B1.
The throttling flow path is used to produce a pressure equalization to avoid problems that can occur during the transition from a relatively high pressure in the pressure chamber to a relatively low pressure in the low pressure area.
In some cases, cavitation noise and cavitation damage can be observed when a liquid filled volume, i.e. the pressure chamber, is depressurized through the throttling flow path connected to the low pressure area.
The object underlying the invention is to reduce the risk of cavitation noise and cavitation damage in the hydraulic device.
This object is solved in a hydraulic device as described at the outset in that a total throttling resistance of the flow path increases during the duration of the throttling.
When a fluid volume is depressurized through the throttling flow path the pressure differential sets the fluid in motion so that fluid flows through the throttling flow path from the high pressure area within the pressure chamber towards the low pressure area. The pressure differential that drives the fluid through the throttling flow path decreases during the throttling. However, due to the inertia of the fluid, the flow through the throttling flow path tends to continue even after pressure equalization has been achieved. This causes the risk that the pressure in the pressure chamber undershoots the pressure in the low pressure area. If the pressure difference between the initial high pressure in the pressure chamber and the low pressure in the low pressure area is substantially larger than the pressure difference between the low pressure area and the vapor pressure of the liquid, then there is risk that the pressure in the pressure chamber reaches the vapor pressure of the liquid so that cavitation bubbles are formed. When these bubbles are subjected to increasing pressure, they can implode and cause cavitation noise and cavitation damage to the structural materials of the device. When, however, during the throttling the throttling resistance of the flow path increases, the liquid passing the throttling flow path is slowed by the increasing flow resistance so that the undershooting of the low pressure level in the low pressure area can be avoided or at least kept small. The risk that vapor develops can be avoided. During the throttling a pressure equalization is permanently possible. However, the velocity and therefore the kinetic energy of the fluid flowing through the flow path is reduced thus preventing undershooting.
In a preferred embodiment a throttling resistance of said groove increases in a direction of flow through said groove. In other words, the differential throttling resistance per unit of length increases. The increase of the throttling resistance of the groove is a simple way to increase the total resistance of the throttling flow path.
Preferably, a hydraulic diameter of said groove decreases in a direction of flow through said throttling flow path. The hydraulic diameter is one factor influencing the throttling resistance of the throttling flow path.
This can be realized in a preferred embodiment in that a flow area of said groove decreases in a direction of flow through said throttling flow path. This is a rather simple means, which can easily be produced.
In a preferred embodiment, said groove is located in said contact face of said second member contacting said first member. Such a groove can easily be machined. When this groove is only partly covered by the first member, in other words when the groove is in overlapping relation with the pressure chamber, the throttling flow path is established.
In this respect, it is preferred that a width of said groove perpendicular to a moving direction of said first member relative to said second member decreases in a direction of flow through said throttling flow path. This is a simple means to decrease the flow area.
In an additional or alternative embodiment a depth of said groove perpendicular to said contact face decreases in a direction of flow through said throttling flow path. This as well is a possibility to decrease the flow area of the throttling flow path in direction of flow.
In a preferred embodiment, said groove has a form of a triangle in said contact face. In other words, when said contact face is viewed from the side on which the first member is arranged, the groove has a form of a triangle.
In an alternative or additional embodiment, it is preferred that said groove has a section perpendicular to said face in form of a triangle. It is therefore possible to linearly reduce the depth of the throttling groove towards the location where the groove contacts the low pressure area or it is possible to keep constant the depth and give the groove the form of a triangle or it is possible to use a combination of both.
Preferably, said first member comprises at least two pressure chambers which are separated by a wall, wherein a thickness of said wall in direction of movement of said first member relative to said second member is smaller than a length of said throttling flow path. When the wall between the two pressure chambers has been moved over the throttling flow path, there is always a connection between the two pressure chambers. However, when the wall is moved towards the low pressure area, the pressure resistance of the flow path increases.
A preferred embodiment of the invention will now be described in more detail with reference to the drawing, wherein:
The hydraulic device 1 furthermore comprises a second member 5. The first member 2 and the second member 5 contact each other, i.e. a second member 5 has a contact face 6 against which a face 7 of the first member rests. The first member 2 is movable relative to the second member 5 in a direction 8 shown by an arrow. In the present example the first member 2 is rotated relative to the second member 5.
The second member 5 has a low pressure area 9. When the opening 4 of the pressure chamber 3 approaches the low pressure area 9, a throttling flow path 10 is established in order to enable a pressure equalization between the pressure chamber 3 and the low pressure area 9 before the pressure chamber 3 comes in full overlapping relation with the low pressure area 9. The throttling flow path 10 is illustrated by a number of arrows.
The throttling flow path 10 is established by means of a groove 11 formed in the contact face 6 of the second member 5. This groove 11 has the form of a triangle when viewed from the first member 2. In other words, the width of the groove 11 perpendicular to the moving direction 8 of the first member 2 relative to the second member 5 decreases in a direction of flow through the throttling flow path 10. Such a triangle is chosen because it is simple to machine. However, other forms of the groove 11 are possible as soon as the width decreases in moving direction 8. In this case, the groove 11 can have a constant depth, wherein the depth is the direction perpendicular to the contact face 6.
In another embodiment not shown in the drawing, the groove 11 can have a depth which decreases in moving direction 8, i.e. in direction of flow through said throttling flow path 10. In this case, the width of the groove 11 can be kept constant.
However, it is possible to combine both possibilities, i.e. to have a decreasing width and a decreasing depth in moving direction 8.
The decreasing depth 11 can be realized as well by a triangle section.
As can be seen in
In this case a throttling flow path 10 has a first section, which is in communication with the pressure chamber 3 under high pressure and a second section, which is in communication with the next pressure chamber 3 with low pressure. When the wall 12 moves in direction 8 of rotation, the cross-section of the flow path 10 in the second section through which the fluid can escape to the pressure chamber 3 under low pressure decreases and therefore the throttling resistance of the throttling flow path 10 increases slowing down the flow of liquid and therefore the kinetic energy of the fluid.
The effect of such an increasing differential flow resistance of the throttling flow path 10 is explained in connection with
While the present disclosure has been illustrated and described with respect to a particular embodiment thereof, it should be appreciated by those of ordinary skill in the art that various modifications to this disclosure may be made without departing from the spirit and scope of the present disclosure.
Number | Date | Country | Kind |
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15154615.7 | Feb 2015 | EP | regional |