DE10351222A1 - Membrane pump used for conveying a medium for treating exhaust gases in diesel engines comprises a suction side and a pressure side that are short-circuited by a self-cleaning throttle point bridging a sealing region - Google Patents

Abstract

Membrane pump for a liquid medium comprises at least one suction valve (2) and at least one pressure valve, each having a membrane that rests tightly with a sealing region (16) on a counter-sealing surface, and a suction side and a pressure side. The suction side and the pressure side are short-circuited by at least one self-cleaning throttle point (21) bridging the sealing region. Preferred Features: The medium is a 32.5% urea/water solution. The throttle point is a groove in the upper side of the membrane of the suction and pressure valve.

Description

The The invention relates to a diaphragm pump for a liquid medium according to the preamble of claim 1.

diaphragm pumps are used in many areas, often as dosing pumps in the food industry or in laboratory technology. The valves of the diaphragm pump are so tight that at disconnected diaphragm pump the pressure of a trapped fluid volume is maintained.

Of the Invention is based on the object, the generic diaphragm pump so that the Pressure of a fluid volume trapped in the system after shutdown the diaphragm pump over is slowly reduced over a certain period of time.

These Task is in the generic diaphragm pump according to the invention with the characterizing Characteristics of claim 1 solved.

at the membrane pump according to the invention the throttle point ensures that the Pressure of a trapped fluid volume is reduced within a predetermined time. The size of the throttle depends on how big that trapped fluid volumes is and within what time accordingly the pressure of this Medium must be removed. Since this throttle cross-section is very small, it would be over the Time and thus ineffective. To prevent this, was the throttle section is placed on the diaphragm. This one is at everyone confirmation deformed. As a result, any adhering particles are dropped. The throttle point is during the plant cleaned by itself. The diaphragm pump according to the invention will be beneficial for promotion a medium for the exhaust aftertreatment used in diesel engines. The medium Here is a 32.5% urea-water solution. It is sprayed in a known manner in the exhaust stream of the diesel engine. In the winter The medium can freeze at correspondingly low outside temperatures. The caged in the diaphragm pump and in the system medium would Freezing, when under pressure, causes serious damage the diaphragm pump and / or upstream or downstream components of Diesel engines cause. As a result of the inventive training However, the pressure of the trapped in the system volume of liquid on the Throttle be degraded, so that when freezing the medium not under pressure. The throttle point is designed so that they Pumping behavior of the diaphragm pump is not impaired during normal operation.

Further Features of the invention will become apparent from the other claims, the Description and the drawings.

The The invention will be explained in more detail with reference to an embodiment shown in the drawings. It demonstrate

1 in perspective and explosive representation of a diaphragm pump according to the invention,

2 after the diaphragm pump 1 in another perspective and explosive representation,

3 in an oblique view, a suction membrane of the membrane pump according to the invention,

4 in oblique top view of the suction membrane according to 3 .

5 the suction membrane according to 3 in side view,

6 to 8th in representations according to the 3 to 5 a pressure membrane of the membrane pump according to the invention,

9 a plan view of the suction diaphragm according to the 3 to 5 .

10 a section along the line AA in 9 .

11 a section along the line BB in 9 .

12 the detail Y in 10 in an enlarged view,

13 the detail X in 11 in an enlarged view,

14 a plan view of the pressure membrane according to the 6 to 8th .

15 a section along the line AA in 14 .

16 the detail Y in 15 in an enlarged view.

The structure of the diaphragm pump is known per se and is therefore explained only briefly. She has a pump head 1 which is hood-shaped and in which three suction valves 2 are housed. The diaphragm pump also has a central pressure valve 3 whose membrane is advantageously made of thermoplastic elastomer and which is responsible for the promotion of the liquid medium. The suction valves 2 and the pressure valve 3 have valve diaphragms and are in a membrane carrier 4 clipped. It is advantageously made of polyamide and has corresponding Einklipsöffnungen for the suction valves 2 and the pressure valve 3 on. Each of the suction valves 2 is in the embodiment by a compression spring 5 loaded, each on a cone-shaped safety valve part 6 sitting. The pressure valve 3 is installed so that it is against the pump head 1 opens. On its opposite side is the pressure valve 3 with a central plug-in approach 7 provided with the pressure valve 3 in the membrane carrier 4 is held. On the opposite side of the membrane carrier 4 are in the embodiment, three suction valves 2 , which are identical and each have a spherical cap-shaped valve body 8th exhibit. The valve body 8th open opposite to the pressure valve 3 towards an elastic hub membrane 9 , in the embodiment, three reciprocating 10 are attached. For fastening serve screws 11 in the hub membrane 9 be screwed. The reciprocating pistons 10 and the suction valves 2 can be found sealed between the membrane carrier 4 and the hub diaphragm 9 to have the same outline. The membrane carrier 4 with the lifting diaphragm attached to it 9 gets to the bottom of the pump head 1 attached.

The lifting diaphragm 9 is by a (not shown) tumbling mechanism on the reciprocating piston 10 excited to Hubbewegungen. Through these strokes of the membrane 9 arises below the suction valves 2 a negative pressure. He has the consequence that the suction valves 2 lift off from their seat, so that the medium to be delivered is sucked under the negative pressure in the diaphragm pump. In the subsequent stroke movement of the membrane 9 becomes the suction valve 2 closed and the inflowing medium is via the pressure valve 3 , which lifts off its seat, conveyed into a pressure line. From here, the medium reaches the desired process location.

The described diaphragm pump is in exhaust aftertreatment systems of Used diesel vehicles. With the diaphragm pump is a 32.5% Urea-water solution fed to an exhaust gas stream.

The 3 to 5 show a suction valve 2 in detail. It has a diaphragm and dome-shaped valve body 12 , at the back of a plug-in approach 7 ' is centrally provided. The dome-shaped valve body 12 lies on the concave inside 13 ( 2 ) of dome-shaped support bodies 14 of the membrane carrier 4 at. The supporting body 14 stand over the membrane carrier 4 towards the pump head 1 front and have a central opening 15 on, through which the plug-in approach 7 ' the corresponding suction valve 2 is plugged.

The valve body 12 lie with an annular edge 16 ( 4 ) sealing on the lifting diaphragm 9 at. It has three openings 17 passing through the suction valves 3 are covered and over which the medium to be pumped is sucked. The supporting body 14 have slot-shaped openings 18 on, through which the medium to the pressure valve 3 can flow.

The plug-in approach 7 ' the suction valve 2 is made of two ring grooves 19 . 20 Surrounded at a distance that have rectangular outline in the embodiment and parallel to each other. As the 10 and 12 show, the two annular grooves 19 . 20 triangular cross-section. The ring grooves 19 . 20 form circumferential recesses on the outside of the valve body 12 ,

The two ring grooves 19 . 20 are by a radial groove 21 with the sealing edge 16 connected. The groove 21 forms a Druckabbaunut, to the outer edge 22 of the valve body 12 runs. The pressure reduction well 21 also has a triangular cross-section in the exemplary embodiment ( 13 ). The groove 21 extends through the sealing area 16 and forms a channel or a throttle which creates a short circuit between the suction and the pressure side of the diaphragm pump.

The cross section of the groove 21 is so small that the suction behavior of the suction valves 2 in operation is not affected. Because the ring grooves 19 . 20 and the pressure dump 21 in the membrane-shaped valve body 12 There is no danger of clogging of these grooves due to dirt. During operation of the diaphragm pump, the membrane-shaped valve body moves 12 always elastic, possibly resulting in the grooves 19 to 21 Stuck dirt is rinsed again and again.

The pressure valve 3 also has a membrane-shaped, dome-shaped valve body 23 , on the outside of the central plug-in approach 7 projects. With him, the pressure valve 3 in the membrane carrier 4 clipped. He has to receive the pressure valve 3 a dome-shaped support body 24 ( 2 ), which is opposite to the supporting bodies 14 is convexly curved and distributed over its circumference slit-shaped, in axial planes of the valve body 23 lying passage openings 25 having. The valve body 23 of the pressure valve 3 lies with his outside side on the inside of the support body 24 at. To stiffen the valve body 23 outside with three stiffening ribs 26 provided, which lie in axial planes and are arranged at equal angular intervals from each other. The stiffening ribs 26 extend from the neck 7 close to the outer edge 27 of the valve body 23 , The height of the stiffening ribs 26 increases radially outwards. In the area of the plug-in extension 7 is the height of the stiffening ribs 26 Zero.

Inside is the valve body 23 with further stiffening ribs 28 provided at the same height as the outer stiffening ribs 26 are arranged. They extend from a central sleeve 29 ( 6 ) to the outer edge 27 of the valve body 23 , The stiffening ribs 26 . 28 are advantageous in one piece with the membrane-shaped valve body 23 educated. The thickness of the stiffening ribs is advantageous 26 . 28 greater than the thickness of the dome-shaped valve body 23 , The stiffening ribs 28 are not axially above the annular sealing area 30 over, with which the valve body 23 sealing at the (not shown) sealing surface of the pump head 1 is applied.

On the outside of the valve body 23 there is a radial pressure reduction groove 31 extending about half the radial width of the valve body 23 out to its outer circumferential edge 27 extends radially. The groove 31 lies in the area between two stiffening ribs 26 , The radially inner end of the groove 31 closes perpendicular to a transverse groove 32 in relation to the groove 31 is short. The two grooves 31 . 32 have advantageous triangular cross section ( 16 ). The grooves 31 . 32 make like the grooves 19 to 21 the suction valve 2 a short circuit between the suction and the pressure side of the diaphragm pump ago. The cross section of the grooves 31 . 32 is again so low that the operation of the diaphragm pump is not affected. The diaphragm pump is used for an exhaust aftertreatment device in diesel vehicles. Behind the diaphragm pump is located on the pressure side of a memory containing the urea-water solution. This solution can freeze at low temperatures. This leads to an increase in volume, which leads to damage to the diaphragm pump. If the volume of urea-water solution present in the membrane pump and in the system were to be locked under pressure, the volume increase occurring during freezing would lead to considerable damage to the membrane pump or system due to the pressure below which the blocked volume stands. To avoid this, the suction valves are 2 and the pressure valve 3 provided in the manner described with the Druckabbaunut. They are designed so that within a predetermined time, which is advantageously smaller than the time required by a trapped in the system volume for freezing, the pressure can be reduced. It has been found that a pressure reduction of the stored, pressurized liquid amount should take place in a period of about 8 to 12 minutes. It is assumed that the imprisoned volume of the urea-water solution is about 10 cm ³ on the pressure side of the diaphragm pump. Depending on the size of this trapped fluid volume, the cross-sectional area of the grooves 19 to 21 . 31 . 32 chosen so that a pressure reduction can be done reliably within a time in which the entrapped liquid volume does not freeze. The grooves 19 to 21 . 31 . 32 form small notch or throttle points in the sealing area 16 . 30 the suction membranes 12 as well as the pressure membrane 23 , Because the grooves 21 . 31 the respective sealing area 16 . 30 traversing, there is a reliable pressure reduction. The cross-section of the notch grooves is chosen so that a complete pressure reduction of the stored volume of the urea-water solution takes place before it can freeze at low temperatures.

The grooves 19 to 21 . 31 . 32 can by means of laser beam in the membrane 12 . 23 the suction and the pressure valves 2 . 3 be introduced. In a series application, it is advantageous to provide the grooves already during injection of the suction and pressure valves.

The grooves 19 to 21 . 31 . 32 Of course, they can have any suitable cross-sectional shape. In any case, the passage cross-section should be chosen so that on the one hand, the function of the diaphragm pump is not affected, on the other hand, a pressure reduction of the entrapped fluid volume takes place before it can freeze.

Claims (14)

Diaphragm pump for a liquid medium, comprising at least one suction valve and at least one pressure valve, each having a membrane which sealingly abuts a counter-sealing surface with a sealing region, and having a suction and a pressure side, characterized in that the suction and the pressure side by at least one sealing area ( 16 . 30 ) bridging, self-cleaning throttle point ( 21 . 31 ) are shorted. Diaphragm pump according to claim 1, characterized in that the throttle point ( 21 . 31 ) a groove in the top of the membrane ( 12 . 23 ) of the suction and the pressure valve ( 2 . 3 ). Diaphragm pump according to claim 1 or 2, characterized in that the membrane ( 12 ) of the suction valve ( 2 ) is formed dome-shaped. Diaphragm pump according to one of claims 1 to 3, characterized in that the throttle point ( 21 ) of the suction valve ( 2 ) extends radially. Diaphragm pump according to one of Claims 1 to 4, characterized in that the membrane ( 23 ) of the pressure valve ( 3 ) is formed dome-shaped. Diaphragm pump according to one of claims 1 to 5, characterized in that the throttle point ( 31 ) of the pressure valve ( 3 ) extends radially. Diaphragm pump according to one of claims 1 to 6, characterized in that the throttle point ( 21 ) of the suction valve ( 2 ) to at least one groove ( 19 . 20 ) in the top of the membrane ( 12 ). Diaphragm pump according to claim 7, characterized in that the groove ( 19 . 20 ) about the axis of the membrane ( 12 ) of the suction valve ( 2 ) rotates. Diaphragm pump according to claim 7 or 8, characterized in that two mutually parallel grooves ( 19 . 20 ) in the top of the membrane ( 12 ) of the suction valve ( 2 ) are provided. Diaphragm pump according to claim 9, characterized in that both grooves ( 19 . 20 ) with the throttle restriction ( 21 ) are line connected. Diaphragm pump, in particular according to one of claims 1 to 10, characterized in that the cross-section of the throttle point ( 21 . 31 ) is so large that a pressure reduction of a liquid medium in the diaphragm pump takes place before it freezes at low temperatures. Diaphragm pump according to one of claims 1 to 11, characterized in that the throttle point ( 12 . 31 ) has triangular cross-section. Diaphragm pump according to one of claims 1 to 12, characterized in that the Diaphragm pump for pumping a medium used for exhaust aftertreatment in diesel engines becomes. Diaphragm pump according to one of claims 1 to 13, characterized in that the Medium is a 32.5% urea-water solution.