DE102011090186A1 - Device e.g. high-pressure fuel pump, for pressure increase and transferring of fluid, has damper housing or part of housing partially formed in elastically deformable manner to compensate pulsations in low pressure fluid - Google Patents

Abstract

The device (1) has a low pressure damper (2) for compensating pulsations in low pressure fluid, and provided with a damper housing (3), an inlet (4) for the fluid and an outlet (5) for the fluid. A high-pressure outlet (11) for the fluid from a pressure increasing chamber (8) i.e. pump chamber, opens during reaching preset fluid pressure. A piston (9) is movably driven in the chamber. The damper housing or a part of the housing is partially formed in an elastically deformable manner to compensate pulsations in the low pressure fluid.

Description

The invention relates to a device for increasing the pressure and forwarding a supplied under low pressure fluid with a low-pressure damper with an elastically deformable housing.

In fluids supplied under low pressure to a pressure increasing device, such as a fuel pump, undesirable pulsations in the low pressure fluid may occur by opening and closing a valve which regulates the inlet of low pressure fluid into the pump. It is known that these pulsations can be mitigated by the use of low pressure dampers located upstream of the pump inlet in the low pressure fluid feed line.

From the DE 100 07 180 B4 is a high pressure fuel pump known with a low pressure damper. The low-pressure damper has a cylindrical holder, a base and a metal bellows, which is arranged within the holder. If pulsations occur in the low-pressure fluid, the metal bellows can be elastically deformed and thus cushion the effect of the pulsations on the fuel system.

It is an object of the invention to provide a device for increasing the pressure with a low-pressure damper, with a low-pressure damper which can be produced simply and inexpensively. Another object is to provide a low pressure damper suitable for retrofitting existing pressure boosting devices.

These objects are achieved by the device according to claim 1 and the low-pressure damper according to claim 11.

The invention relates to a device for increasing the pressure and forwarding a supplied under low pressure fluid, with a low-pressure damper to compensate for pulsations in the low-pressure fluid. The low pressure damper includes a housing having an inlet for the low pressure fluid in the low pressure damper and an outlet for the low pressure fluid from the low pressure damper.

The apparatus further comprises a pressure-increasing device having a housing, a pressure-increasing chamber formed in the housing, and a movable piston disposed in the pressure-increasing chamber. The pressure increasing chamber has an inlet for the low pressure fluid with a valve device fluidly connecting in a first position the low pressure inlet into the pressure increasing chamber to the outlet from the low pressure damper so that the low pressure fluid flows from the low pressure damper into the pressure increasing chamber. In a second position, the closure device inhibits fluid flow from the low pressure damper into the pressure increase chamber.

The pressure increasing chamber also has an outlet for the fluid from the pressure increasing chamber, which opens upon reaching a predetermined fluid pressure, so that the high pressure fluid can now flow to a consumer.

The damper housing of the low-pressure damper or a part of the housing are formed at least partially elastically deformable to compensate for pulsations in the low-pressure fluid.

For this purpose, the damper housing or a part thereof may have a geometry or shape which is elastically deformable in order to compensate for the pulsations. For example, the housing may be at least partially shaped like a bellows or may be in the form of a pressure box having a wavy outer wall. In this case, the wall thickness of the housing must be sized and the material chosen so that the pulsations cause elastic deformation of the housing, whereby the low-pressure damper volume is increased or decreased in the short term.

Suitable materials could be aluminum or plastic. But other metals could be used with appropriate construction. The housing inner wall of the low pressure damper may have a coating to prevent corrosion of the housing by, for example, an aggressive low pressure fluid. The coating must then undergo the elastic deformations of the housing without the coating detaching itself from the inner wall of the housing.

The damper housing or parts thereof may additionally or alternatively have areas of different thickness to allow the elastic deformability and the associated volume changes of the low-pressure damper. For example, in a section perpendicular to its vertical axis, the damper housing can have portions of different diameters with different projection surfaces. A thinning of the material can then be formed, for example, at a circumferential edge of the transition from a section with a larger projection area to a section with a smaller projection area. With a pressure increase in the low-pressure damper due to a pulsation in the fluid, the section with the smaller projection surface can then escape in a direction away from the section with the larger projection surface, whereby the volume of the low-pressure damper is increased. At the When the overpressure in the low-pressure damper decreases, the section with the smaller projection surface returns to its original position, the volume of the low-pressure damper is reduced again. When a short-term negative pressure due to a pulsation occurs, the section with the smaller projection surface can move in the direction of the section with the larger projection surface.

Additionally or alternatively, the housing or a part thereof may have areas with materials having different elasticities. Such an area may be, for example, the transition described above between two sections of different geometry, or a wall may be connected to the adjoining walls with an elastically deformable material so that the wall can move in pulsation relative to the adjoining walls.

A preferred part of the damper housing, which may be designed elastically deformable as described, is the cover of the damper housing.

In the device for increasing the pressure and forwarding of the low-pressure fluid may be my pump with a pump chamber in which the fluid is compressed. The pump may be a known rotary pump, preferably a linear pump, ie a pump with a pump in which a piston is reciprocated linearly to change the volume of the pump chamber and that in the pump chamber to compress existing fluid.

The closing device may be a valve which is connected to a controller and can be opened and closed depending on predetermined parameters. It can be, for example, a solenoid valve, with a spring, preferably a coil spring, which presses a valve body in the de-energized state to the second position in which the valve is closed, so that no low-pressure fluid can flow into the pressure-increasing chamber or pump chamber. As power is applied to the device, the valve body is moved to the first position, that is, the valve opens and low pressure fluid can flow into the pressure increasing chamber.

Pulsations in the low-pressure fluid usually occur when the closure device interrupts the low-pressure fluid flow into the pressure-increasing chamber, for example, the valve body moves from the first position to the second position. It may therefore be advantageous if the low-pressure fluid does not accumulate in the closing device when the closing device closes or closes but can exit from the closing device or through the closing device back to, for example, a reservoir for the low-pressure fluid. The low pressure fluid may also be fed directly back into the low pressure fluid circuit upstream of the low pressure damper.

The high pressure outlet for the fluid from the pressure increasing chamber may include a check valve which is biased by a spring into a closed position and opens when the pressure of the fluid is greater than the biasing force. However, the high pressure outlet may also be a valve that is opened and closed by a controller, the controller, for example, receiving signals from a pressure sensor in the pressure increasing chamber to determine when an opening pressure for the valve stored in the controller has been reached.

The device may be a fuel pump with an upstream low-pressure damper, the fuel pump forming the pressure-increasing device.

The invention further relates to the low-pressure damper detached from the pressure-increasing device, which is for example in the warehouse or is transported from A to B for connection to a pressure-increasing device. With the low-pressure damper according to the invention, for example, existing high-pressure fuel pumps can be retrofitted.

The low-pressure damper for balancing pulsations in a low-pressure fluid has a damper housing, an inlet for the low-pressure fluid and an outlet for the low-pressure fluid, wherein the damper housing or a part thereof is at least partially elastically deformable.

The low-pressure damper essentially corresponds to the low-pressure damper described in connection with the device for pressure increase and forwarding of a fluid supplied under low pressure. In particular, for the elastic deformability of the housing or a housing part, the possibilities described for the device apply.

In the following, a device with alternative embodiments of the low-pressure damper will be explained in more detail with reference to figures. The embodiments illustrated in the figures do not limit the scope of the invention to what has been shown. Features or combinations of features, which can only be seen in the figures, can advantageously further develop the invention. The figures show in detail:

1 Low-pressure damper housing with elastically deformable cover

2 Low-pressure damper housing with pulsation-damping geometry

3 Low pressure damper housing with material weakening

The 1 shows a section through a partially illustrated fuel pump with a low-pressure damper 2 , which has an elastically deformable lid 15 having.

The low pressure damper 2 includes an inlet 4 for the low pressure fluid, a housing 3 with a lid 15 and an outlet 5 for the low pressure fluid from the low pressure damper 2 , The outlet 5 is with an inlet 10 connected to a valve device which controls the flow of low pressure fluid from the low pressure damper 2 in the pressure booster room 8th , here the pump chamber of the fuel pump, allows or disables.

For this purpose, the valve device has a valve body 12 in plate form, by a spring 16 is biased to a first position in which the low pressure fluid is not in the pump chamber 8th can flow in. The valve device is preferably a solenoid valve. If the solenoid valve is de-energized, the spring force of the spring 16 the valve body 12 in the first position, hold the lock position. As soon as the solenoid valve is energized, the magnetic force pulls the valve body 12 from the first position to a second position where the low pressure fluid enters the pumping chamber 8th the fuel pump can flow.

Preferably, the valve opens at the moment when the piston 9 the downward movement begins so that the low pressure fluid enters the enlarging pump chamber 8th is sucked in. Is the piston 9 in its lowermost position, the valve closes so that as it moves upward, the piston now compresses the fluid in the chamber, increasing the pressure in the fluid. The pump chamber 8th has an outlet connected to a check valve 11 is closed. Upon reaching a predetermined pressure in the fluid, the check valve opens 11 and the pressurized fluid may be out of the pumping chamber 8th a downstream arranged aggregate are provided.

The moment in which the valve closes, is the moment in which preferably pulsations can occur in the low pressure fluid. To dampen these pulsations, upstream of the valve is the low pressure damper 2 intended. In the illustrated embodiment, the low-pressure damper 2 a lid 15 which is wavy from the inside to the outside. Due to this design of the lid 15 may be the volume of the low-pressure damper 2 increase and decrease in pulsations occurring in the low-pressure fluid, whereby the pulsations are attenuated.

In addition to the pulsationsdämpfend formed lid 15 It is advantageous if the pulsating low-pressure fluid at least partially through the outlet even when the solenoid valve is closed 5 can flow out to shorten the time for effective damping of pulsations occurring in the low pressure fluid. For this purpose, the low-pressure fluid, for example, flow through the valve back to a reservoir. To allow backflow through the valve, the valve body can 12 For example, have holes through which the low-pressure fluid can flow into the discharge line with the valve closed, while with the valve open the valve body 12 the openings of the discharge lines on the valve side closes.

The 2 shows a second embodiment of a low-pressure damper 2 in which a part of the housing 3 of the low pressure damper 2 has a geometry that is suitable for pulsations by volume changes of the low-pressure damper 2 compensate. In the illustrated embodiment, the housing 3 of two interconnected parts, of which the lower part is the inlet 4 in the low-pressure damper 2 and the outlet 5 includes while the upper part of the housing 3 , in the broadest sense, as a lid 15 can denote, in the height direction 15 of the low pressure damper 2 is formed wavy. This preserves the housing 3 an elastic deformability, so that when pulsations occur, the volume of the low-pressure damper 2 can be increased and decreased to attenuate the pulsations. By the in the case 2 arranged spring can be influenced by the selection of the spring constant, inter alia, the degree of damping.

Another embodiment of a low-pressure damper according to the invention 2 show the 3 , Like in the 2 the low-pressure damper consists of a lower housing part with inlet 4 and outlet 5 and an upper part that serves as a lid 15 for the housing 3 serves. The two parts are connected so that they are at least in the height direction 14 can not be moved relative to each other. The lid 15 consisting of the two parts may alternatively be integrally formed.

The lid 15 has two in the height direction 14 successively arranged areas 17 . 18 on that in a plane perpendicular to the elevation axis 14 have different projection surfaces, wherein the projection of the first area 17 is bigger, as the projection area of the second area 18 , The two area 17 . 18 are connected in a step-shaped connecting portion, with a first circumference of substantially the circumference of the first portion 17 corresponds to a second extent, which is substantially the scope of the second range 18 equivalent.

In the embodiment, the lid 15 at the transition of the first sections 17 in the connecting section a material weakening 19 on, which is a kind of joint 19 forms, in which the first section 17 with the second section 18 connected via the connecting section. When pulsations occur in low-pressure fluid, the lid can 15 in the joint 19 be raised and lowered, whereby the volume of the low-pressure damper is changed.

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

• DE 10007180 B4 [0003]

Claims (12)

Contraption ( 1 ) for pressure increase and forwarding of a low-pressure supplied fluid, with a low-pressure damper ( 2 ) to compensate for pulsations in the low pressure fluid, with a damper housing ( 3 ) and an inlet ( 4 ) for the low pressure fluid and an outlet ( 5 ) for the low-pressure fluid, a pressure-increasing device ( 6 ) with a housing ( 7 ), in or from the housing ( 7 ) formed pressure booster chamber ( 8th ) and one in the pressure booster chamber ( 8th ) movably arranged driven pistons ( 9 ), a low pressure inlet ( 10 ) in the pressure increasing chamber ( 8th ) with a closing device ( 12 ), which in a first position the low pressure inlet ( 10 ) in the pressure increasing chamber ( 8th ) with the outlet ( 5 ) from the low pressure damper ( 2 ) fluidly connects so that fluid from the low pressure damper ( 2 ) in the pressure increasing chamber ( 8th ) flows and in a second position, a fluid flow from the low-pressure damper ( 2 ) in the pressure increasing chamber ( 8th ) and a high pressure outlet ( 11 ) for the fluid from the pressure-increasing chamber ( 8th ) which opens upon reaching a predetermined fluid pressure, characterized in that the damper housing ( 3 ) or a part of the damper housing is formed at least partially elastically deformable to compensate for pulsations in the low pressure fluid. Device according to claim 1, wherein the damper housing ( 3 ) or a part of the damper housing have a geometry that is elastically deformable to compensate for the pulsations. Device according to one of the preceding claims, wherein the damper housing ( 3 ) or a part of the damper housing have areas of different material thickness and the damper housing ( 3 ) or the part of the damper housing in the areas of different wall thickness is elastically deformable to compensate for the pulsations. Device according to the preceding claim, wherein the damper housing ( 3 ) in a section perpendicular to a vertical axis ( 14 ) Sections ( 17 . 18 ) has different projection surfaces and the material weakening ( 19 ) at a transition from a section ( 17 . 18 ) with a first projection surface to a section ( 17 . 18 ) is formed with a second projection surface. Device according to one of the preceding claims, wherein the damper housing ( 3 ) or a part of the damper housing have regions of different materials with different elasticities. Device according to one of the preceding claims, wherein the elastically deformable part of the damper housing ( 3 ) a lid ( 15 ) of the damper housing ( 3 ). Device according to one of the preceding claims, wherein the locking device ( 13 ) is a solenoid valve which, when de-energized by a spring ( 16 ) is held in the second position, in which no fluid from the low-pressure damper ( 2 ) in the pressure increasing chamber ( 8th ) is moved and when energized in the first position is moved, in the low-pressure fluid in the pressure-increasing chamber ( 8th ) flows. Device according to one of the preceding claims, wherein the low-pressure fluid when the device is in the second position by the closing device ( 13 ) is drained back to a reservoir. Device according to one of the preceding claims, wherein the high-pressure outlet ( 11 ) a check valve ( 11 ) which is biased in a closing direction and opens when the pressure of the fluid is greater than the biasing force. Device according to one of the preceding claims, wherein it is in the pressure-increasing device ( 6 ) around a fuel pump ( 6 ). Low pressure damper ( 2 ) to compensate for pulsations in a low pressure fluid for attachment to a pressure compression device ( 6 ), for example a fuel pump ( 6 ), with a damper housing ( 3 ), an inlet ( 4 ) for the low pressure fluid and an outlet ( 5 ) for the low-pressure fluid, characterized in that the damper housing ( 3 ) or a part of the damper housing is formed at least partially elastic to compensate for pulsations in the low pressure fluid. Low-pressure damper according to the preceding claim, wherein the damper housing ( 3 ) or a part of the damper housing according to one of claims 2 to 6 is formed.

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