WO2013029758A1

WO2013029758A1 - Electromagnetic pump

Info

Publication number: WO2013029758A1
Application number: PCT/EP2012/003539
Authority: WO
Inventors: Robert Wellnitz; Stefan Quast; Axel MÜLLER; Bernd Köhler
Original assignee: Thomas Magnete Gmbh
Priority date: 2011-08-31
Filing date: 2012-08-21
Publication date: 2013-03-07
Also published as: DE102011111926A1

Abstract

The invention relates to an electromagnetic pump comprising an axially-moving armature (12) which has a ferromagnetic armature cone (18), a coil (6) which surrounds said armature (12), a first flange (7), and a second flange (8), said first flange (7) and second flange (8) protruding into the coil (6) and surrounding a pump chamber (35), and the armature being arranged within this pump chamber. According to the invention, an electromagnetic pump whose geometric and ferromagnetic structure can be altered and adapted to different armatures, and a method by means of which a metering cylinder can be easily installed in an electromagnetic pump, are achieved by the first flange (7) having a ferromagnetic pole ring (9) on a section which delimits the pump chamber (35).

Description

Electromagnetic pump

The invention relates to an electromagnetic pump according to the preamble of claim 1 and a method for producing an electromagnetic pump according to the preamble of claim 9.

DE 42 05 290 A1 shows an electromagnetic pump comprising a coil, a first inlet side and a second outlet side flange projecting into the coil, wherein an inlet side is sealed with a suction valve, a magnetically displaceable armature with a piston rod which together upon excitation of the coil be displaced in the direction of the suction valve and are moved by a spring in the outlet side direction when de-energized and discharge liquid outlet side or can intake side suction via the suction valve. The armature has an inlet-side armature cone, the first flange being complementary to the armature cone

having trained cone receptacle. The conical seat has at its inlet side inlet an inwardly directed, angled projection, against which a metering cylinder is admitted on the inlet side and is held on the intake side by the suction valve. Disadvantageously, the pump can not be adapted to different pumping performance requirements without adapting the flanges to the armature. DE 10 2008 058 046 A1 shows an electromagnetic pump with an armature axially movably arranged in a pump chamber

Anchor cone and a reciprocating piston, wherein the pump chamber is formed by a first flange and a second flange and disposed within a coil. The two flanges are made of a ferromagnetic material in order to influence the magnetic field generated by the coil in such a way that the armature is axially deflected in the pump chamber during energization of the coil. In order to move the armature back to the starting position after the current supply is between the armature cone and the

CONFIRMATION COPY first flange arranged a spring element whose bias counteracts the force of the magnetic field.

DE 199 37 988 A1 shows an electromagnetic pump with a closed pump chamber on one side, wherein the pump chamber is surrounded by a coil. The pump room will be another end of one in the

Pump flange projecting flange limited, wherein in the pump chamber consisting of a first anchor ring, a second anchor ring and a reciprocating armature is arranged axially movable. In a region of the pump chamber facing away from the flange, a pole ring arranged separately from the flange by a non-magnetic ring is placed in order to guide the magnetic field in the region of the pump chamber which does not delimit the flange. The pole ring is separated by a first non-magnetic ring from a second pole ring, which second pole ring a

Surrounds the end of the pump chamber. In a rest position of the pump, the pole rings each surround one of the two anchor rings in the radial direction.

DE 30 29 470 A1 shows a circulating pump with a first flange and a second flange, each defining a cylindrical pump space frontally. In the pump chamber, an armature is arranged axially movable, wherein the armature is driven by the energization of two coils. In the radial direction of the pump chamber is bounded by non-magnetic wall sections and a magnetic wall section, wherein the non-magnetic wall sections a distance between the flanges and the

define the magnetic wall section.

DE 1 937 184 U shows an electromagnetic pump with a pump chamber in which an actuator driven by a coil is arranged. Of the

Pump chamber is surrounded laterally in the radial direction in a first region of a bobbin and in a second region of a magnetizable tube, wherein the pump space is bounded end face at one end by a valve (no reference numeral) and the other end of a rubber buffer. DE 43 32 056 C2 shows an electromagnetic valve. The valve is actuated by an armature, with a magnetic field circuit by means of a coil

magnetizable components B is generated, namely a flange, an attraction element 58 and a sleeve. The sleeve serves on the one hand to transmit the magnetic field, and on the other hand to allow the armature to slide axially.

DE 10 2008 043 962 A1 shows a pressure regulating valve, wherein an armature surrounding a coil is arranged in a magnetic part of the valve. One

Hydraulic part is arranged fluid-tight with respect to the magnetic part. A

Anchor chamber is formed by a pole tube arranged in the coil, wherein at a side facing away from the hydraulic part of a flange projects into the pole tube and the coil. At the end facing the hydraulic part is a magnetizable disc and a flange not projecting into the coil

arranged.

It is the object of the invention to provide an electromagnetic pump whose geometric ferromagnetic structure changeable and to

different armature is adaptable and to provide a method by which a metering cylinder can be easily mounted in an electromagnetic pump.

This object is achieved by an electromagnetic pump having the features of claim 1 and by a method having the features of claim 9.

An electromagnetic pump according to the invention comprises an axially movable ferromagnetic armature with an armature cone, which is surrounded by a coil. Furthermore, the pump has a first flange and a second flange, wherein preferably at least one of the two flanges protrudes into the coil and wherein the two flanges surround a pump space in which the armature is arranged. In an interior of the coil and in ferromagnetic components in the interior of the coil, when the coil is energized, a magnetic field is generated, whereby the ferromagnetic armature is displaced in the direction of movement. The first flange has a ferromagnetic pole ring on a section delimiting the pump chamber. Through the use of a pole ring, the magnetic field advantageous

specified requirements can be adjusted without having to change the other parts of the pump constructively. Furthermore, the first flange can be made of a non-ferromagnetic material, which advantageously allows the use of more stable materials. Further, such a geometry of a primary air gap of the electromagnetic pump between the pole ring and the anchor cone can be designed in a simple manner.

In an advantageous embodiment, the pole ring has an outer

Peripheral surface, which is inserted into a ring receiving the first flange and is held at least circumferentially thereto. As a result, a space for the pole ring is advantageously created, wherein the pole ring advantageous radial forces on the peripheral holder forming an outer

Can transmit peripheral surface.

Advantageously, an inner contour of the pole ring is designed to be complementary to the armature cone. Due to the complementary configuration of the pole ring to the armature cone, the exchange of the pole ring and the armature, the magnetic field advantageous to changing working conditions or

Design requirements are adjusted without any adjustment of the other immovable parts of the pump must be made. Further advantageously, the pole ring at least partially surrounds the armature cone in the radial direction. Hierduch is advantageously created a radial boundary between the anchor cone and the first flange.

In an advantageous development, the pole ring consists of a different ferromagnetic material than the first flange. This can do that

Magnetic field of the pump can be advantageously adapted to the particular requirement. Advantageously, the pole ring of a harder ferromagnetic Material as the first flange, so that the life is extended due to lower wear in an abutment of the armature to the pole ring. Advantageously, the pole ring in the first flange, in particular in the

Receiving surface, pressed. This advantageously a simple and at the same time solid connection between the pole ring and the first

Core flange reached. Alternatively, the pole ring may be bolted to the first core flange in a thread. This is advantageous a detachable

Connection created. But the pole ring can also be glued or verschweist in the first flange.

The armature has a piston rod, wherein the piston rod in an advantageous embodiment of the pump passes through a central opening of the pole ring. In this case, a radial gap between a lateral surface of the

Piston rod and the central opening of the pole ring arranged. This advantageously prevents tilting of the piston rod on the pole ring.

In a further advantageous embodiment, an armature biasing spring element extends in the radial gap between the reciprocating piston and the pole ring. The spring element biases the anchor in

Return movement direction, wherein the spring element is advantageously supported on the one hand on the armature and on the other hand on the first flange or a metering cylinder inserted in the first flange. This is the

Spring element advantageously associated with an extended travel, so that a

Spring element can be used with an increased spring force, so that a return movement of the armature is started sooner. Furthermore, the same spring can advantageously be used in different pole rings. In an advantageous embodiment, a metering cylinder is inserted into a receiving portion of the first flange, wherein the pole ring is advantageously limited to the pump chamber facing side of the receiving portion and facing the metering cylinder. As a result, the dosing is advantageous in set the receiving portion, the dosing cylinder at the other end abuts against the first flange or another component in the first flange. As a result, the metering cylinder is not compressed during assembly, so that deformation of an inner space of the metering cylinder is avoided, so that movement of the armature in the metering cylinder is advantageously not impaired.

In an advantageous development of the invention, the first flange at one end has a suction nozzle, wherein the first flange may advantageously be formed integrally with the suction nozzle. Alternatively, the suction can be screwed by a thread with the first flange.

In an advantageous embodiment, the armature is displaced in the direction of the pole ring when the coil is energized. Advantageously, a magnetic force between the pole ring and the armature during the energization is amplified.

Alternatively, however, the armature can also be displaced in a direction away from the pole ring, in the direction of the second flange. It is understood that in this case the second flange has an anchor counter-cone, wherein a cone of the anchor cone points with its pointed end in the direction of the second flange. Further, in this case, the primary air gap is disposed between the second flange and the armature cone, with a secondary air gap between an end portion of the pole ring facing the pole ring

Anchor cone and the pole ring is arranged. Alternatively, the pole ring can also be arranged in the second core flange, wherein the

Anchor countercone is then advantageously arranged in the pole ring.

Preferably, the armature has an outlet facing piston surface. Advantageously, a fluid can be pumped into the outlet during a movement of the armature in the direction of the outlet.

In an advantageous development, the diameter of the receptacle of the pole ring is the same size or larger than the diameter of the receiving portion of the metering cylinder. This is advantageous a projection created against which the pole ring can be stored. As a result, the metering cylinder can advantageously be fixed in the first flange.

Advantageously, the metering cylinder is adjacent to a valve module. As a result, it is advantageous to achieve a two-sided clamping of the metering cylinder with the simultaneous use of a valve, so that a simple mounting of the electromagnetic pump is made possible.

In an advantageous development of the diameter of the opening of the pole ring is formed smaller than the diameter of the receiving portion of the flange, so that advantageously a projection is provided, which is the

Clamping metering cylinder.

In an advantageous embodiment, the metering cylinder has a directed in the axial direction to the pole ring cylindrical projection, wherein the metering cylinder is acted on the projection of the pole ring against the first flange and thereby fixed. As a result, an area is advantageously created that can absorb axial forces acting on the metering cylinder so that deformations of the metering cylinder due to the clamping do not take place in the region of the piston rod receptacle. Indicates the cylindrical one

Projection a small thickness, so its stiffness against the stiffness of the other dosing is reduced, so that advantageous

Deformations due to the clamping are even more reduced. Further features, properties and embodiments of the invention will become apparent from the following description of an embodiment and from the dependent claims.

Fig. 1 shows a preferred embodiment of an electromagnetic pump according to the invention with pole ring in a de-energized

Status

Fig. 2 shows a detail of the embodiment shown in Fig. 1 1 shows an electromagnetic pump 1 in a de-energized state, comprising a first housing part 2, a second housing part 4 provided with an outwardly projecting electrical connection 3

Coil carrier 5, a wound on the bobbin 5 coil 6, an inlet-side first flange 7 and an outlet-side second flange 8. The bobbin 5, the first flange 7 and the second flange 8 surround one lying between the first flange 7 and the second flange 8 Pump chamber 35. In the first flange 7, a pole ring 9, a metering cylinder 10 and a suction valve 11 are arranged immovably. The electromagnetic pump 1 further comprises one arranged in the pump chamber 35

movable armature 12. The armature 12 comprises a hollow cylindrical

Anchor cone 18 and an inlet in the anchor cone 18 inlet, hollow cylindrical piston rod 19 and an outlet side in the

The first housing part 2, the second housing part 4 with the exception of the electrical connection 3, the bobbin 5, the coil 6, the two flanges 7, 8 and the armature 12 are formed as a rotational body and concentric with each other around a arranged common axis.

The first flange 7 and the second flange 8 are caulked oppositely in the bobbin 5. In this case, the first flange 7 and the second flange 8 provided therefor Verstemmbereiche 77, the one

enable frictional connection of the two flanges 7, 8 to the bobbin 5. To the bobbin 5 and the coil 6 are in this

Order the second housing part 4 and the first housing part 2, wherein the second housing part 4 the coil carrier 5 laterally, ie the inlet side and the outlet side, in an outer region 78 surrounds. Between the first flange 7 and the bobbin 5, a gap 80 is axially provided, wherein the flange 7 in the region of the gap 80 has a relation to the Verstemmbereich 77 enlarged circumference with a thread 79. The gap 80 is filled by an inwardly projecting end portion 81 of the first housing part 2, which is bolted to the first flange 7. The inlet-side first flange 7 has a cylindrical inner space with an inner diameter, which widens several times starting from an inlet side 13, so that a plurality of regions with different inner diameters results. Here, a defined as an inlet channel 14 first inner region of the first flange 7 is arranged with a smallest inner diameter in the first flange 7. The inlet channel 14 opens into a second inner region of the first flange 7 defined as a valve receptacle 15. The inlet channel 14 and the valve receptacle 15 are in direct fluid communication with one another. The valve receptacle 15 in turn opens into a third inner region of the first flange 7 with a larger inner diameter defined as a receiving region 16. Finally, the receiving region 16 in turn opens into a fourth inner region of the first flange 7 defined as a ring receiver 17.

The suction valve 11 comprises a suction valve housing 36, a valve stem 37 and a valve spring 38 biasing the valve stem 37 in the inlet direction 13. The suction valve housing 36 is of rotationally symmetrical construction and protrudes with an inlet-side end portion 39 into the valve seat 15, the outer surface of the inlet-side end portion 39 being flush on the inner surface of the valve seat 15 abuts. Adjacent to the inlet-side end section 39 is a radially outwardly extending valve housing flange 40 which has a

Bearing surface 41 for engagement with a formed between the valve seat 15 and the receiving portion 16 step 42 forms. Adjoining the valve housing flange 40 on the outer surface of the valve housing 36 is an annular groove 43, wherein the annular groove 43 into an outlet-side cylindrical portion 44 of

Valve housing 36 passes. The annular groove 43 is connected via a channel, not shown in the valve housing 36 with the valve seat 15 in fluid communication. At an outlet-side end face 45 of the valve housing 36 is a

protruding projection 46 is arranged, which defines on the outlet-side end face 45 of the valve housing 36, a projection 47 of the recess 46 recessed shoulder 47 of the valve housing. The valve housing 36 has a substantially cylindrical inner region 48 in which the valve tappet 37 is arranged. At its inlet-side end 49, the valve tappet 37 has a spring clip 50, against which the valve spring 38 is supported on the inlet side. On the outlet side, the valve spring 38 is supported on an inwardly directed constriction 51 of the inner region 48 of the valve housing 36. The valve stem 37 also knows one on one of the valve spring 38th

on the opposite side of the constriction 51 located plunger head 52, which has a against the Enschnürung 51 directed sealing ring 53.

At the outlet-side end face of the valve housing 36 of the metering cylinder 10 is affiliated, which in a cylindrical inner channel 54 has a complementary to the outer contour of the valve housing 36

Valve housing receptacle 55, wherein the valve housing receptacle 55 surrounds the projection 46 and the cylindrical outer surface 44 of the valve housing 36. The metering cylinder 10 is in this case with a stepped shoulder 56 of the receiving region 55 on the projection 46 and the shoulder 47 of the

Valve housing 36 ajar. The remaining inner channel 54 has a

Inner diameter corresponding to the outer diameter of the piston rod 9, wherein a clearance between the inner surface of the inner channel 54 and the piston rod 19 is provided in each case.

The metering cylinder 10 has on its outside two outer regions 57, 59 with different diameters, wherein a first inlet-side outer region 57 has a smaller outer diameter than the

Inner diameter of the receiving portion 16 of the first flange 7, so that a cavity 58 between the metering cylinder 10 and the

Receiving portion 16 of the first flange 7 is formed. The cavity 58 is in fluid communication with the annular groove 43 of the valve housing 36. The second outlet-side outer region 59 has an outer diameter which corresponds to the inner diameter of the receiving region 16 of the first flange 7, so that an at least substantially fluid-tight portion is formed between the receiving region 16 and the metering cylinder 10. The two outer regions 57, 59 share the outer surface of the dosing cylinder 10 approximately in half. From an outlet end of the cavity 58 is a radial bore 60 in the inner channel 54 of the metering cylinder 10, so that a fluid connection is made from the inner channel 54 to the cavity 58. At an outlet-side end face 61, the metering cylinder 10 has a

Projection 62, which protrudes from an outer shoulder 63 of the outlet-side end face 61 of the metering cylinder 10 and forms a contact surface for the pole ring 9. Further, the end face 61 has a mouth flange 64 which projects into an inner portion 65 of the pole ring 9 provided with a smallest inner diameter of the pole ring 9.

The pole ring 9 is pressed into the ring receptacle 17, wherein the pole ring 9 has a cylindrical outer region 66 whose outer diameter corresponds to an inner diameter of the ring receptacle 17. In its interior, the pole ring 9 on the outlet side, a counter-cone 67 which extends to the

Inlet side 13 tapers and opens into an inner ring section 68. The inner diameter of the inner ring portion 68 is offset outwardly relative to the inner ring portion 65 and forms an armature end stop 69 designed as a shoulder.

The armature cone 18 of the armature 12 has on the inlet side an outer ring area 20, which outer ring area 20 constitutes the smallest outer diameter of the armature cone. Adjacent to the outer ring region 20 extends a conical region 21 formed with increasing outer diameter, which, after a recessed step 22, extends into an up to an outlet side

End side 23 of the armature cone 18 extending cylindrical secondary region 24 passes. In this case, the outer ring region 20 and the cone region 21 form a primary region 20, 21. The hollow cylindrical anchor cone 18 furthermore has an inner space comprising three cylindrical regions whose central region 25 corresponds to the outer diameter of the piston rod 19

corresponding inner diameter. An inlet-side inner region 26, which extends up to an inlet-side end 27 of the anchor cone 18, has an enlarged relative to the central region 25 Inner diameter, so that a step for supporting a return spring 28 is provided. Finally, the cylindrical inner region 24 has an outlet-side inner section 34 that is also widened with respect to the central region 25 and extends up to the outlet-side end side 23 of the anchor cone 18. In the outlet-side inner portion 34 is the

Damping assembly 33 is inserted, wherein the damping arrangement 33 has an outlet channel 29 closing cup 30, which merges into a plate-shaped head portion 31, which head portion 31 has an outer diameter corresponding to the inner diameter of the outlet-side inner portion 34 of the anchor cone 18. For closing the outlet channel 29, the cup 30 has in its outer region elastic damping elements 32, which surround an edge of the outlet channel 29 in a de-energized state of the pump 1 and thus achieve a sealing effect.

The hollow cylindrical piston rod 19 protrudes with its inlet side end into the inner channel 54 of the metering cylinder 10. In its interior, the hollow cylindrical piston rod 19 has a check valve 70, wherein a ball valve formed as a body 71 is biased by a spring 72 against a valve seat 73 arranged on the inlet side. In this case, between the valve body 71 and the valve seat 73 in the closed state of the valve 70, a leakage-like fluid connection between the interior of the hollow cylindrical piston rod 19 and the inner channel 54 of the metering cylinder 10 is provided, thereby preventing sticking between the piston rod 19 and the plunger head 52 of the suction valve 11 becomes. The spring 72 is supported on the outlet side on a in the hollow cylindrical piston rod 19 designed as a mandrel support member 74, which in the hollow cylindrical

Piston rod 19 is pressed. The mandrel 74 is formed integrally with the cup 30 and the dish-shaped head portion 31 of the damper assembly 33. The hollow cylindrical piston rod 19 has, in a central region 75, bores 76 pointing radially into the pump chamber 36 and providing fluid communication from the interior of the hollow cylindrical piston rod 19 into the pump chamber 36

Create pump room 36. The embodiment works as follows:

The pump 1 is shown in Figs. 1 and 2 in a de-energized state. When the coil 6 is switched on, a magnetic field is generated which exerts a force on the armature 12, in particular on the armature cone 18, and displaces it in the inlet direction 13. It flows in the

Pump chamber 36 existing fluid in front of the exhaust passage 29 releasing damper assembly 33. Further, the piston rod 19 is displaced in the metering cylinder 10 in the direction of the inlet channel 14, wherein the check valve 70 opens against the bias of the spring 72, as soon as the inlet side end face of the piston rod 19 has passed over radial bore 60, so that fluid from the inner channel 54 of the metering cylinder in the hollow cylindrical

Piston rod 19 flows. By traversing the radial bore 60, the fluid communication is separated from the inner channel 54 to the cavity 58, so that a defined delivery volume between an inlet side edge of the radial bore 60 and the plunger head 52 is defined in the inner space 54, which in the hollow cylindrical piston rod 19th flows. The duration of the energization of the coil 6 is set in time such that a Bestromungsintervall until a stop of the Ankerkonus 18 at the

Anchor end stop 69 takes place. As soon as a spring force of the return spring 28 exceeds a magnetic force between the armature cone 18 and the pole ring 9 which decreases after switching off the pump, the armature 12 is displaced in the outlet direction. In this case, the check valve 70 closes in the interior of the hollow cylindrical piston rod 19 due to the bias of the spring 72, wherein a suction effect between the piston rod 19 and the plunger head 52 of the suction valve 11 is formed, so that the valve stem 37 is displaced in the outlet direction. Once the edge of the radial bore 60 is passed over, the suction effect between the piston rod 19 and the valve stem 37 is repealed, since a pressure equalization between the inner channel 54 of

Dosing cylinder 10 and the inlet channel 14 via the radial bore 60, the cavity 58 and the channel, not shown, from the cavity 58 to the Valve receptacle 15 takes place. The valve stem 37 is then displaced in the inlet direction by the valve spring 38, wherein the valve stem 38 fluid from the inlet channel 14 via the connection just described in the

Inner channel 54 of the dosing cylinder 10 sucks.

The former in the Bestromungsvorgang in the interior of the

Piston rod 19 sucked fluid is sucked through the radial bores 76 in the piston rod 19 in the pump chamber 35, while the fluid located in front of the damping assembly 33 is discharged on the outlet side.

An assembly of the pump 1 is carried out in a simple manner, wherein in a first step, the suction valve 11 is inserted into the first flange 7. Favored by the stepped interior 14, 15, 16, 17 of the first flange 7 can now successively the metering cylinder 10 and the pole ring 9 in the first

Flange 7 are used, wherein the dosing cylinder 10 is supported at one end to the seated suction valve 11 and the other end is clamped by the arranged in the ring holder 17 of the first flange 7 pole ring 9. The pole ring 9 is supported on a shoulder formed between the receiving area 16 and the ring receptacle 17. The pole ring 9 is caulked with the inner surface of the ring holder 17. This causes the inner ones

Components 9, 10, 11 of the pump 1 held frictionally.

Then or before the first housing part 2, the bobbin 5, the coil 6 and the second housing part 4 is connected to the first flange 7, wherein the first housing part 2 is screwed to the thread 79 with the first flange 7. Then the bobbin 5 is pushed with the coil 6 together with the second housing part 4 on the first flange 7, wherein the bobbin 5 is firmly caulked with the Verstemmbereich 77 of the first flange 7.

Now, the return spring 28 and the armature 12 in the first flange 7 and the pole ring 9 is used. Finally, the second flange 8 is pushed with its Verstemmbereich 77 in the bobbin 5 and caulked there, so that a frictional connection between the Verstemmbereich 77 of the second flange 8 and the bobbin 5 is formed.

A turning or turning of the pump 1 in any of the assembly steps is advantageously not necessary. Furthermore, the pump 1 can advantageously be mounted only from one side, in the present embodiment from the outlet side, so that the pump 1 can be mounted during assembly with the first flange 7 held fixed. This facilitates the insertion of the components, reduces the time of assembly and allows assembly on an assembly line, which advantageously reduces the cost of assembly.

Claims

Electromagnetic pump, comprising

an axially movable armature (12) having a ferromagnetic armature cone (18),

a coil (6) surrounding the armature (12),

a first flange (7),

a second flange (8),

wherein the first flange (7) and the second flange (8) protrude into the coil (6) and surround a pump space (35),

the armature (2) being arranged in the pump space (35), characterized in that

the first flange (7) has a ferromagnetic pole ring (9) on a section which radially outwardly delimits the pump space (35).

Electromagnetic pump according to claim 1, characterized in that the pole ring (9) has an outer peripheral surface (66) which is inserted into a ring receiver (17) of the first flange (7) and is held at least circumferentially thereto.

Electromagnetic pump according to claim 1 or 2, characterized

in that an inner contour (67) of the pole ring (9) is designed to be complementary to the armature cone (18), and that the pole ring (9) at least partially surrounds the armature cone (18) in the radial direction.

Electromagnetic pump according to one of claims 1 to 3, characterized in that the pole ring (9) from another

ferromagnetic material is the first flange (7). Electromagnetic pump according to one of claims 1 to 4, characterized in that the pole ring (9) in the first flange (7) is pressed.

Electromagnetic pump according to one of Claims 1 to 5, characterized in that one connected to the armature (12)

Piston rod (19) passes through a central opening of the pole ring (9), wherein a radial gap between a lateral surface of the piston rod (19) and the central opening of the pole ring (9) is arranged.

Electromagnetic pump according to claim 6, characterized in that a the armature (12) biasing spring element (28) is at least partially disposed in the gap.

Electromagnetic pump according to one of claims 1 to 7, characterized in that a metering cylinder (10) in one

Receiving portion (16) of the first flange (7) is inserted, and that the pole ring (9) the pump chamber (35) facing side of the receiving portion (16) limited and facing the metering cylinder (10).

A method of manufacturing an electromagnetic pump (1) comprising the steps

Inserting a metering cylinder (10) in a first housing part (7), characterized by

Fixing the metering cylinder (10) in the first housing part (7) by inserting a ferromagnetic pole ring (9) in a receptacle (17) in the first housing part (7), wherein the pole ring (9) defines the metering cylinder (10) in the axial direction ,

A method for producing a metering pump designed as an electromagnetic pump (1) according to claim 9, characterized by determining a axial normal force, the bending in the Dosing cylinder (10) causes, wherein the metering cylinder (10) by the pole ring (9) with a clamping force, which is smaller than the normal force, set.