DE19910920A1 - Membrane pump, in particular, micromembrane pump with oscillating armature comprises oscillating armature guide element which is produced together with surrounding plastic injection molding - Google Patents

Abstract

The element (37) of the guide system for the oscillating armature (27) is produced together with the plastic injection molding (35), and consists of the same material.

Description

The invention relates to a vibrating armature diaphragm pump, in particular Micropump, for pumping gaseous and / or liquid media, with an electromagnet that has a solenoid with one in it mounted spring-loaded rocker armature includes, with a Diaphragm pump section, which is a divisible by a membrane Has pump chamber, on the one hand via a flow channel to the inlet and on the other hand leads to the outlet via a second channel, with the inlet and valves arranged in the outlet, with a holder for the Diaphragm in which the diaphragm pump section of the diaphragm edge is fixed and with a fastening device by the Electric drive and diaphragm pump section are fastened together, the linearly movable vibrating armature moves as it moves guided. One end of the rocker arm engages to move the Membrane on this, the electromagnet with the solenoid and Coil sleeves, iron angles and electrical connection contacts in total is provided with a plastic coating. Such pumps are said to be improved. There are diaphragm pumps in various variants as  Vibrating armature pumps are known. They usually consist of one elastomer membrane clamped on both sides within a Pump room and two valves - the inlet and outlet valve -. about These valves are flow channels with a suction and pressure port connected. Further flow channels lead to the pump room. In the Movement of the membrane, the valves open automatically, each alternately through the media flow. Regarding the electromagnet to The drive of the pump should be noted that it comes from a magnetic coil an anchor stored in it. The rocking anchors are in Spring plates stored or guided in sleeves. The well-known Vibrating armature diaphragm pumps have a relatively large number of components, moreover, the guidance of the rocker arm piston is imprecise, so that no exact dosing can take place when conveying the media.

The object of the invention is therefore a vibrating armature diaphragm pump type mentioned in such a way that they consist of few components is constructed and there is safe guidance for the vibrating anchor, after all, the pump should be easy to assemble and safe to operate his. This is achieved in that the Vibrating anchor guide made of the same material with plastic encapsulation is trained. The molded-in rocker arm guide allows an exact Alignment of the swing axis with respect to the membrane, so that the Movement of the membrane with each delivery stroke a predetermined amount of the funding medium is achieved. In addition, the Uniform molding a simplification in the manufacture of Vibrating armature diaphragm pump, in particular, are now fewer parts available, so that this also simplifies the assembly itself becomes. In another embodiment of the invention is the second Vibrating anchor guide made of the same material with the membrane holder  educated. This training is still a safe guide for the Vibrating anchor achieved, moreover through the material uniform Training does not require more assembly work, rather it can be done through the Swing anchor also aligns the membrane holder to Electromagnets can be achieved. The vibrating anchor is advantageous loaded at both ends by a spring. In this way the oscillating movement of the armature safely when the pump is operating carried out.

In a particular embodiment of the invention Pump room in the rest position of the pump through one valve in two Sections divided in such a way that no medium from the one section in the other flows. In addition, it is prevented from flowing back from the inlet when the pump is at rest. The valve is advantageously formed by a membrane part, so as to ensure that the labor and assembly effort remains as low as possible. In a particular embodiment of the Invention in the rest position closes the valve by the Membrane part a channel coming from the inlet. That way a valve can be formed in a simple manner without additional effort ensures that the pump chamber is subdivided or that no medium is in the rest position of the pump can flow from the inlet to the outlet, regardless of the position of the pump.

To increase safety, the membrane section is in the rest position pressed by a spring against the inlet channel and can thus be Carry out safety function.  

In a particular embodiment of the invention, the Membrane section under its sealing surface on a hollow body, so that in Sealing position an elastic pressure and adjustment of the membrane the inlet flow channel is achieved.

In a particular embodiment, this is one end of the Oscillating armature limited in its linear movement by a stop, it is recommended that the stopper be spring loaded. Through this This measure ensures that when the medium is conveyed, the same dose is delivered, regardless of how high the back pressure or the suction level of the flow rate. It is recommended here the stop is adjustable in order to achieve that the Delivery rate is changeable.

The adjusting screw allows the stroke to be limited mechanically. Hereby the delivery rate may be reduced, but each stroke of the Pump achieves the same delivery rate.

In a special embodiment of the invention Diaphragm coil connected in series with a diode. That way of the applied AC voltage only one half-wave effective, so that the armature moves through the spring Restoring force moved back to the starting position.

In a particular embodiment of the invention, the inlet and the outlet valve is arranged on a rubber-elastic plate, here the valve body has protrusions that penetrate the plate intervention. This measure allows inexpensive production of the two valves, since these are now arranged in a flat plate,  intervene in the openings through the projections, furthermore ensures that the plate is precisely aligned with the pump section. It is recommended that the rubber-elastic plate be between one Inlet and outlet supporting support body and a valve body clamped supported, the valve body places the membrane on the Membrane holder firmly. This measure also allows the number of to assembly components to reduce, moreover, a safe Sealing achieved. At the same time, such training allows both the rubber-elastic valves as well as the membrane in one operation can be attached to each other.

In a further embodiment of the invention, in which the pump as a feed pump for particularly liquid aggressive media, such as Sulfuric acid is used, the supporting body carrying the inlet and the outlet and the pump body forming a boundary of the pump chamber a propylene plastic and the valves and diaphragm from an EPDM and / or FKM material are constructed. By such Material selection is not only possible, harmless media, either Water, be it to convey air, but also aggressive media, since the Material is selected so that even when sulfuric acid is extracted does not attack the material or pump.

A particularly easy to manufacture version results if the Guide formed with the same material as the plastic encapsulation the side facing away from the diaphragm pump section is arranged.

In the drawing, the subject of the invention is in several Exemplary embodiments shown and that show:  

Fig. 1 to Fig. 4 each in a sectional view of various vibrating armature diaphragm pumps and

Fig. 5 is a membrane in section.

The vibrating armature diaphragm pump 10 consists of a diaphragm pump 11 and an electromagnet 12 .

The diaphragm pump comprises a connector body 13 with an inlet connector 14 and an outlet connector 15 . The sockets 14 , 15 can be closed by an inlet valve 16 or an outlet valve 17 . The two valves are provided on a rubber-like valve plate 18 , in this case the valve plate is clamped between the nozzle body 13 and a valve body 21 . To secure the position and precise alignment of the valve plate, it has openings through which pin-like projections on the valve body engage. An inlet flow channel 19 leads from the inlet valve to the pump chamber 22 , while an outlet flow channel 20 flows from the pump chamber 22 to the outlet valve 17 , in this case the nozzle body 13 , the valve body 21 and the pump chamber 22 with the membrane form the membrane pump section already mentioned.

The pump chamber 22 has a membrane 23 which is inserted at its outer edge into a membrane holder 24 , the membrane being fixed via the valve body 21 . It should also be stated here that the membrane carries on its side facing the valve body a spherical elevation 42 which engages in a position of the membrane in a pan-like recess 43 of the valve body 21 ( FIGS. 1 and 4) or in a valve seat (item. 45) seals ( Fig. 2 and 3). On the side facing away from the spherical elevation 42 , the diaphragm 23 is provided with a receptacle in which one end of a guide rod 30 of the oscillating armature 27 firmly engages, so that the membrane 23 is also moved when the oscillating armature moves.

The membrane holder 24 has on the side facing away from the membrane 23 a frustoconical extension 25 which carries a guide 26 in the center, into which a guide rod 30 of the oscillating armature 27 is guided during its movement. This frustoconical extension 25 engages in a passage 31 of the electromagnet 12 , the passage 31 being formed by sleeves 32 . The sleeves each end with one end in a frame made of sheet iron. The sleeves themselves sit in a bobbin 33 around which the solenoid 34 is arranged.

Here, the sleeves 32 and thus the passage are exactly aligned with the magnet coil 34 , so that the frustoconical extension 25 with its guide 26 is also exactly aligned with the magnet. When the vibrating armature moves, it is then guided exactly in the center of the magnet coil.

The solenoid 34 , frame with sleeves 32 and bobbin 33 are provided with an overmold 35 , whereby in the overmold 35 there are also fixed contacts 36 which carry one end out of the overmold. The end of the electromagnet facing away from the diaphragm 23 has a guide 37 in which a further guide rod 30 of the oscillating armature is guided, in this case the extrusion coating 35 in the region of the guide 37 is so large that a spring 28 can be supported with one end , while the other end of the spring engages the oscillating armature 27 so that it is loaded in the direction of the valve body 21 . The encapsulation 35 also precisely guides the guide 37 to the coil former 33 . The vibrating armature is thus moved in two guides to magnet coil 34 in an exactly aligned manner.

The guide 37 extends away from the pump side and opens into a hollow cylinder which is also integrally formed on the extrusion coating 35 . Concerning the electromagnet, it should be summarized that it is a completely molded plastic component. During manufacture, the following parts are placed in the injection mold, the magnetic coil 34 , which is wound on the coil body 33 , the coil sleeves 32 , the electrical connection contacts 36 and the diode. After the encapsulation with plastic, this component forms the basic body for the complete pump. It is attached to the diaphragm pump, either by a screw connection or by a snap connection.

If an alternating voltage is now applied to the magnetic coil 34 , which generates an alternating magnetic field, a diode lies in series with the magnetic coil, so that only one half-wave is effective for driving. The ferromagnetic oscillating armature 27 is attracted by this magnetic field. After the voltage has dropped, it is pressed back into the zero position by the spring 28 (see FIG. 2). Each time the voltage changes, a lifting movement of the oscillating armature 27 is generated.

During the suction stroke, the membrane is withdrawn from the valve body 21 . A negative pressure is generated in the expanding pump chamber 22 . Medium can flow into the pump chamber 22 through the inlet connection 14 , in this case the inlet valve 16 opens, in which it is moved against the valve body.

On the return stroke to the starting position, the medium is pressed out of the pump chamber 22 by the membrane 23 , the outlet valve 17 thereby opening, in which it is pivoted by the valve body 21 against the nozzle body. The medium can then flow to the outlet port 15 via the outlet flow channel 20 . At the outlet pressure, the inlet valve is closed because the corresponding valve seals the inlet when it is moved against the nozzle body. With a further stroke movement, the medium gets back into the pump chamber via the inlet valve and via the inlet connection piece and the inlet flow channel, while further delivery then takes place again.

As can be seen from FIG. 2, the diaphragm 23 with its spherical elevation 42 is pressed into the valve seat (item 45) by the spring 28 with the electromagnet switched off, so that the inlet flow channel 19 opening into the recess is then closed with others Words in the event of power interruption and when switching off, the inlet is sealed so that no medium can get into the pump chamber. To understand the drawings should be noted here that the inlet flow channel 19 is guided in the embodiments of FIG. 2 and FIG. 3 up to the opening 45 (valve seat).

In the embodiments according to FIGS. 1 and Fig. 4 springs 30 are arranged on two guide rods. With each stroke movement either the lower or the upper spring is tensioned so that an oscillating stroke movement takes place. In such an embodiment, the second inlet valve is formed in the rest position from item 42 spherical elevation on the diaphragm and item 45 valve seat on the pump body, not closed, since the two springs 28 , 29 assume a central position. During its movement, the guide rods 30 are moved securely in the guide 26 of the truncated cone extension 25 or in the guide 37 of the encapsulation 35 , so that the oscillating armature 27 is always held exactly in the middle and cannot hit the sleeves, although the magnetic forces try to get him there. It should be mentioned here that the springs for the oscillating armature are designed either as a conical spring, a cylindrical spring or even as leaf springs. In the case of training as leaf springs, at least the lower spring would engage the end of the guide rod, the guide rod itself protruding somewhat from the guide in any position.

In the embodiment according to Fig. 3 and Fig. 4 of the hollow cylinder of the extrusion coating 35 has a hollow cylinder-like extension 38, in which a stop 39 is arranged. The stop is loaded by a spring 40 , the spring force being adjustable via an adjusting screw 41 .

Of the oscillating armature to the left, corresponding to the suction stroke of the pump is seen with respect to Figs. 3 and FIG. 4, then, moved to the end position of the guide rod against the stop 39 at each movement. This stop can now be adjusted so that sooner or later the guide rod hits the stop during the swinging movement. In this way, the lifting height of the oscillating armature can be adjusted so that the diaphragm only defines the pump chamber by a certain amount in a precisely defined manner. The suction volume is then always dependent on the setting of the stop and can be kept constant with every stroke.

In Fig. 3, in the rest position, the membrane is moved so far in the direction of the valve body that the inlet flow channel 19 is closed.

In Fig. 4, the intake stroke has just ended. The guide rod lies on the stop 39 .

Recess 43 forms a counterstop by which the lifting height is limited. In the exemplary embodiment according to FIG. 5, the membrane 23 has a cavity 44 under spherical elevation 22 .

Through this cavity, the ball-like projection is designed resilient 42 so that the cup-shaped recess 3 it can adapt better to the flow channel 43 in the examples of FIG. 2 and FIG. Himself.

With regard to the stroke setting, it should also be mentioned that without stop if there is a high back pressure or a changed suction head, the delivery rate changes because the stroke decreases. The stroke is not mechanical fixed, but depending on the balance of spring force, Magnetic force and compressive force in the pump room. For the formation of the Equilibrium is also only the constant period of a phase of 50 Hz, approx. 20 milliseconds.

For many applications, a high constant flow rate is important. Such pumps are then used as metering pumps. In order to achieve constant delivery rates, the stroke is mechanically limited on the pump side by a stop of the membrane (elevation 42 at recess 43 ) in the pump chamber; on the opposite side by a mechanical stop 39 which can be locked by means of a screw 41 . This adjusting screw 41 mechanically reduces the stroke in order to reduce the total delivery quantity, but the same delivery quantity is achieved with each stroke. In addition, the drive is given time to travel all the way between the two stops even when there is a high back pressure. This is achieved in that is controlled by an electronic control with adjustable frequency and duty cycle.

As already mentioned, the illustrated embodiments are only examples of realizations of the invention. These are not limited to this, but many other modifications and applications are still possible, for example the diaphragm pump could be made of such a material that aggressive media can also be conveyed. Such media are, for example, for the nozzle body and the valve body, polypropylene plastic, while the valves and diaphragm would be made of a material EPDM (ethylene-propylene-terpolymer rubber) and / or FKM (fluorine rubber) material. It remains to be added here that the spherical elevation in conjunction with the pan-like recess acts as a valve. This valve is practically closed by the spring of the oscillating armature in the rest position of the electromagnet. As soon as the pump is switched on and the electromagnet is connected to the power supply, the membrane swings back and forth so that the membrane does not engage with the ball-like elevation during its delivery into the pan-like recess (exemplary embodiment, FIG. 2). It should also be mentioned that the guide of the oscillating armature in the area of the membrane can be integrally formed on the extrusion coating, the truncated cone-shaped attachment would then be omitted. A special component would then have to be used for the other guide, which would then also carry the stop with spring and adjusting screw. The special component could then carry the frustoconical approach, which would have to engage in the passage of the sleeve of the electromagnet and would have to be particularly fastened. 10 vibrating armature diaphragm pump
11 diaphragm pump
12 electromagnet
13 nozzle body
14 inlet connection
15 outlet connection
16 inlet valve
17 exhaust valve
18 valve plate
19 inlet flow channel
20 outlet flow channel
21 valve body
22 pump room
23 membrane
24 membrane holder
25 truncated cone
26 leadership
27 rocking anchors
28 lower spring for 27
29 upper spring for 27
30 guide rods for 27
31 round in 12
32 sleeves
33 bobbin
34 coil
35 overmolding
36 connection contact
37 leadership of 30
38 hollow cylinders
39 stop
40 spring for 39
41 adjusting screw for 39
42 spherical elevation on 23
43 pan-like recess in 21
44 cavity in 23
45 valve seat in pos. 12

Claims (17)

1. vibrating armature diaphragm pump, in particular micropump, for the promotion of gaseous and / or liquid media, with an electromagnet which comprises a magnet coil with a spring-loaded vibrating armature mounted therein, with a diaphragm pump section which has a pump chamber which can be divided by a diaphragm, on the one hand via a Flow channel leads to the inlet and on the other hand via a second channel to the outlet, with valves arranged in the inlet and outlet with a holder for the membrane, in which the membrane edge is defined by the membrane pump section and are fastened to one another by a fastening device by the electric drive and the membrane pump section, Here, the linearly movable oscillating armature is guided in its movement, in this case one end of the oscillating armature engages the membrane to move it, the electromagnet with the magnet coil and coil sleeves, iron angles and electrical connection contacts n are provided with a plastic encapsulation, characterized in that the rocker arm guide ( 37 ) is made of the same material as the plastic encapsulation ( 35 ). 2. vibrating armature diaphragm pump according to claim 1, characterized in that the second vibrating armature guide ( 26 ) is made of the same material with the membrane holder ( 24 ). 3. vibrating armature diaphragm pump according to claim 1 or 2, characterized in that the vibrating armature ( 27 ) is loaded at both ends by a spring ( 28 ). 4. vibrating armature diaphragm pump according to one of claims 1 to 3, characterized in that the pump chamber ( 22 ) in the rest position of the pump by a valve ( 23 , 42 , 45 ) is divided into two sections such that no medium from one section in the other flows ( Fig. 2 and Fig. 3). 5. vibrating armature diaphragm pump according to one of claims 1 to 4, characterized in that the valve ( 23 , 42 , 45 ) is formed by a diaphragm part ( 42 ). 6. vibrating armature diaphragm pump according to one of claims 1 to 5, characterized in that in the rest position the valve ( 42 , 45 ) by the membrane part ( 42 ) closes a coming from the inlet channel ( 19 ). 7. vibrating armature diaphragm pump according to claim 6, characterized in that in the rest position of the diaphragm part ( 42 ) is pressed by a spring ( 28 ) against the inlet channel ( 19 ) or valve seat ( 45 ). 8. vibrating armature diaphragm pump according to one of claims 1 to 7, characterized in that the membrane part ( 42 ) has a hollow body ( 44 ) under its sealing surface. 9. vibrating armature diaphragm pump according to one of claims 1 to 8, characterized in that the one end of the vibrating armature ( 27 ) is limited in its movement by a stop ( 39 ). 10. A vibrating armature diaphragm pump according to one of claims 1 to 9, characterized in that the stop ( 39 ) is spring-loaded. 11. A vibrating armature diaphragm pump according to one of claims 1 to 10, characterized in that the stop ( 39 ) is adjustable. 12. vibrating diaphragm pump according to one of claims 1 to 11, characterized in that a second opposite stop ( 43 , 45 ) limits the stroke in the other direction. 13. A vibrating armature diaphragm pump according to one of claims 1 to 12, characterized in that the magnet coil ( 34 ) is connected in series with a diode. 14. A vibrating armature diaphragm pump according to one of claims 1 to 13, characterized in that the inlet and the starting valve ( 16 , 17 ) on a rubber-elastic plate ( 18 ) is arranged, in this case the valve body ( 21 ) has projections which are in openings in the Engage the plate ( 18 ). 15. A vibrating armature diaphragm pump according to claim 14, characterized in that the rubber-elastic plate ( 18 ) is held clamped between a nozzle body ( 13 ) carrying the inlet and the outlet and on a valve body ( 21 ), at the same time the valve body ( 21 ) places the diaphragm ( 23 ) on the membrane holder ( 24 ). 16. A vibrating armature diaphragm pump according to one of claims 1 to 15, characterized in that when the pump is designed as a feed pump for in particular liquid aggressive media, such as sulfuric acid, the nozzle body ( 13 ) carrying the inlet and outlet and the valve body ( 21 ) forming a limitation of the pump chamber ) made of a polypropylene plastic and the valves ( 16 , 17 ) and membrane ( 23 ) made of an EPDM and / or FKM material. 17. A vibrating armature diaphragm pump according to one of claims 1 to 16, characterized in that the material-uniformly formed with the plastic extrusion coating ( 35 ) guide ( 37 ) is arranged on the side facing away from the diaphragm pump section ( 21 , 25 ).