DE4408380C2 - Pump with two optional pressure outlets - Google Patents

Description

The invention relates to a pump with a housing and two choice wise pressure outlets in particular with a pressure medium for windscreen washers in motor vehicles, with one by one movable wall divided into a first and a second partial chamber pressure chamber, with the movable wall of the mün into the first sub-chamber ending pressure outlet or the pressure outlet opening into the second partial chamber is closable, and with a reversibly rotatably driven pumps rotor receiving pump chamber, on its cylindrical inner wall in Circumferential direction at a distance from one another leading to the first partial chamber first pressure channel and a second pressure leading to the second partial chamber open into the channel and into the coaxial to the axis of rotation of a drive shaft Suction port opens, the pump chamber and the pressure chamber are arranged side by side and wherein the pressure channels with straight Ver run approximately in a plane arranged transversely to the axis of rotation of the pump Always lead to the pressure chamber.

It is with such a pump (DE 41 36 348 A1 and EP 0 271 318 A2) known, the movable wall of the pressure chamber in a plane transverse to Level of the pump chamber, so to arrange along the axis of rotation, which is a appropriate size required.

The object of the invention is therefore a pump of the beginning to create mentioned type that allows a small size.

This object is achieved in that the movable Wall in one opposite the level of the pump chamber certain angle inclined plane is arranged.

If the specific angle is approximately 30 °, the required installation space can be added at the same time, the channels are kept largely straight.  

The plane of the movable wall intersects the plane of the pump chamber especially around the axis of rotation, so is a particularly flow inexpensive straight guidance of the channels possible.

The channels open on approximately the same on the cylindrical inner wall of the Pump chamber circumferential line in the pump chamber, so is the Pump chamber can be designed with a small axial extent.

The radial circumferential line runs centrally on the cylindrical inner wall of the Pump chamber, so the velus rich, not in a flow feasible circulations of the pressure medium in the pump chamber far avoided.

The mouths of the pressure channels extend approximately over the width of the cylindrical inner wall of the pump chamber, so an optimally low axial extension with optimal avoidance not in a flow achievable circulations of the print medium achieved.

The pressure channels preferably open tangentially to the cylindrical one Inner wall into the pump chamber. The pressure channels can also be on two parallel to each other on the cylindrical inner wall of the pump chamber radially flow into the pump chamber.

A small size and ease of manufacture with few components reached when pump chamber and pressure chamber have a common housing own, which consists of two interconnectable housing halves, the connection plane of the housing halves being approximately in the plane of the pump chamber is arranged.

It leads to a simple, easy to assemble design if the movable wall is a flexible membrane with its radial circumferential Edge area between the two housing halves is kept clamped.  

If the movable wall is permanently open by a force in the closing direction acts on the first pressure outlet, the first pressure outlet below a certain pressure difference between the first and second subchambers closed and above the determined pressure difference with higher pressure is opened in the first subchamber opposite the second subchamber, so the first pressure outlet is always kept closed, when the pump is not in operation. Print medium that is in a to the first pressure outlet connected and arranged higher than the pump Line is not able to flow back to a container via the pump, from which the pump draws the pressure medium. Lead the first Pressure outlet connected line to an area lower than the pump, the container cannot leak out through the pump.

The prestressing of the membrane can save space in terms of component and installation space can be achieved in that the membrane in the closing direction on the first pressure outlet directed self-bias.

Another way to achieve the bias of the membrane is in that the membrane is supported on the housing of the pressure chamber preloaded spring in the closing direction on the first pressure outlet strikes.

A perfect closing of the pressure outlets through the membrane is there achieved by that the mouth areas of the pressure outlets approximately pipe protrude like a nozzle into the sub-chambers assigned to them.

An embodiment of the invention is shown in the drawing and will described in more detail below. Show it:

Fig. 1 is a view of outlets of a pump with two selectively applied pressure,

Fig. 2 is a side view of the pump according to Fig. 1,

Fig. 3 shows a section of the pump taken along the line II in Fig. 1,

Fig. 4 shows a section of the pump taken along the line II-II in Fig. 2,

Fig. 5 is a schematic representation of a side view of the pump in the area of the plane of the pump chamber and pressure chamber.

The pump shown has a housing 1 , in the right area of which a reversible electric motor is arranged, which can be connected to a power source via a plug connection 2 .

The motor shaft projects axially as a drive shaft 3 into a pump chamber 4 , which is cylindrical in the present exemplary embodiment and in which a pump rotor, which is carried by the drive shaft 3 and can be driven in a reversibly rotatable manner, is arranged.

The range of the electric motor relative to the pump chamber 4 is sealed by having its radially outer cylindrical surface tightly inserted into the housing 1 and cylindrical with its inner bore, the drive shaft 3 by closing ring seal 6 relative to the pump chamber. 4

On the side facing away from the electric motor of the pump rotor 5 , a suction port 8 opens out axially to the axis of rotation 7 of the drive shaft 3 into the pump chamber 4 .

As can be seen in FIG. 5, pressure channels 9 and 10 open into the pump chamber 4 in opposite directions tangentially at their cylindrical inner wall. The pressure channels 9 and 10 lead to a pressure chamber 11 arranged in the housing 1 . The pressure chamber 11 is divided by a flexible membrane 12 into a first sub-chamber 13 and a second sub-chamber 14 , wherein in the first sub-chamber 13 a first pressure outlet 15 and approximately diametrically opposite in the second sub-chamber 14 a second pressure outlet 16 open. The mouth areas of the pressure outlets 15 and 16 are formed in the manner of a pipe socket projecting into their subchambers 13 and 14 , the sealing surfaces 17 and 18 of the pressure outlets 15 and 16 , on which the membrane 12 can rest sealingly, approximately parallel to the plane of the Membrane 12 are.

The level 19 of the membrane 12 is arranged relative to the level 20 of the pump chamber 4 at an angle of 30 °.

The openings of the pressure channels 9 and 10 into the pump chamber 4 extend across the width of the cylindrical inner wall of the pump chamber 4 . They lead to the pressure chamber 11 with a straight course in the plane 20 of the pump chamber 4 . Characterized in that the pressure chamber 11 is arranged inclined by 30 ° to the plane 20 of the pump chamber according to the plane of the membrane 12 , the pressure channel 9 opens into the first subchamber 13 and the pressure channel 10 into the second subchamber 14 without the pressure channels 9 and 10 from it straight course must deviate.

The housing of the pump chamber 4 and pressure chamber 11 is formed from two interconnectable housing halves 21 and 22 , the connection plane of the housing halves 21 and 22 being formed from the central, at 30 ° to each other sloping planes of the pump chamber 4 and the pressure chamber 11 .

The housing half 22 is formed in one piece with the housing part receiving the electric motor and the housing half 21 is formed in one piece with the housing part having the suction connection 8 , so that the housing halves 21 and 22 which are connected to one another by means of ultrasonic welding form the housing 1 in their connecting plane. When the two housing halves 21 and 22 are joined together, the diaphragm 12 with its radially circumferential edge region 23 is also clamped between the two housing halves 21 and 22 and the two subchambers 13 and 14 are held tightly separating from one another.

The membrane 12 is provided with an inherent prestress by which it is prestressed in the closing direction on the first pressure outlet 15 .

From the two pressure outlets 15 and 16 , pressure channels 24 and 25 lead to pressure connecting pieces 26 and 27 , which extend parallel to one another to a small extent approximately in the opposite direction.

In one direction of rotation of the pump rotor 5 , pressure medium, in particular washing liquid of a windscreen washer system of a motor vehicle, is conveyed via the pressure channel 9 to the first partial chamber 13 , in which a membrane 12 is lifted off from the sealing surface 17 of the first pressure outlet 15 and presses onto the pressure outlet 16 becomes. As a result, the pressure medium can be conveyed via the pressure outlet 15 and the pressure channel 24 to a washer nozzle on the rear window of a motor vehicle, for example.

In the other direction of rotation of the pump rotor 5 , pressure medium is conveyed via the pressure channel 10 to the second partial chamber 14 , in which a pressure which presses the membrane 12 onto the pressure outlet 15 is built up. Via the pressure outlet 16 and the pressure channel 25 , the pressure medium can then be conveyed to a washer nozzle on the windshield of a motor vehicle, for example.

Claims (12)

1. Pump with a housing and two pressure outlets which can optionally be pressurized with a pressure medium, in particular for windshield washer systems in motor vehicles, with a pressure chamber divided by a movable wall into a first and a second partial chamber, the pressure outlet opening into the first partial chamber through the movable wall or which opens into the second partial chamber pressure outlet can be closed with a reversibly rotatably drivable Pum penrotor receiving pump chamber, on the cylindrical inner wall in the circumferential direction at a distance from one another leading to the first partial chamber leading first pressure channel and leading to the second pressure chamber leading second pressure channel and in the coaxial to the axis of rotation of a drive shaft, a suction port opens, the pump chamber and the pressure chamber being arranged side by side, and the pressure channels having a straight course approximately in a plane transverse to the axis of rotation of the pump chamber for pressure Renew chamber, characterized in that the movable wall is arranged in a plane ( 19 ) inclined by a certain angle relative to the plane ( 20 ) of the pump chamber ( 4 ). 2. Pump according to claim 1, characterized in that the certain Angle is about 30 °. 3. Pump according to claim 1 or 2, characterized in that the plane ( 19 ) of the movable wall intersects the plane ( 20 ) of the pump chamber ( 4 ) approximately on the axis of rotation ( 7 ). 4. Pump according to one of the preceding claims, characterized in that the pump chamber-side mouths of the pressure channels ( 9 , 10 ) extend approximately over the width of the cylindrical inner wall of the pump chamber ( 4 ). 5. Pump according to one of the preceding claims, characterized in that the pressure channels ( 9 , 10 ) open tangentially on the cylindrical inner wall in the pump chamber ( 4 ). 6. Pump according to claim 1, characterized in that the pressure channels ( 9 , 10 ) on two parallel to each other on the cylindrical inner wall of the pump chamber ( 4 ) open radially circumferential lines in the pump chamber ( 4 ). 7. Pump according to one of the preceding claims, characterized in that the pump chamber ( 4 ) and pressure chamber ( 11 ) have a common housing ( 1 ) which consists of two interconnectable housing halves ( 21 , 22 ), the connecting plane of the housing halves ( 21 , 22 ) is arranged approximately in the plane ( 20 ) of the pump chamber ( 4 ). 8. Pump according to claim 7, characterized in that the movable wall is a flexible membrane ( 12 ) which is held clamped with a radially encircling the edge region ( 23 ) between the two housing halves ( 21 , 22 ). 9. Pump according to one of the preceding claims, characterized in that the movable wall is permanently acted upon by a force in the closing direction on the first pressure outlet ( 15 ), the first pressure outlet ( 15 ) below a certain pressure difference between the first and second sub-chamber ( 13 , 14 ) is closed and above the determined pressure difference with higher pressure in the first sub-chamber ( 13 ) compared to the second sub-chamber ( 14 ). 10. Pump according to claim 9, characterized in that the membrane ( 12 ) has a self-bias directed in the closing direction on the first pressure outlet ( 15 ). 11. Pump according to claim 9, characterized in that the membrane ( 12 ) by a on the housing of the pressure chamber ( 11 ) supported, biased spring in the closing direction is acted on the first pressure outlet ( 15 ). 12. Pump according to one of the preceding claims, characterized in that the mouth regions of the pressure outlets ( 15 , 16 ) protrude approximately like a pipe socket into the sub-chambers ( 13 , 14 ) assigned to them.