DE102019121192A1 - EMPTY STROKE ADJUSTMENT OF A MAGNETIC ACTUATOR - Google Patents

Abstract

The invention relates to a method for adjusting an idle stroke of a magnetic actuator, comprising the steps: (a) Providing a pole tube (2) for receiving a magnet armature (5) that can be moved along a longitudinal axis (A), a pole core unit being arranged on a front side of the pole tube , having a through hole for receiving a plunger (6), wherein the pole core unit has a flat front surface, (b) introducing the plunger with a preferably flat front end and the magnet armature such that the plunger and magnet armature are in engagement, (c) positioning the Plunger in such a way that the front end of the plunger has a predetermined axial distance from the front surface, and (d) setting a rear stop position by engaging a stop element (9) with the magnet armature, in particular on a rear side of the magnet armature, and fixing the stop element on the Magnetic actuator, in particular on the pole tube and / or by laser serv weld.

Description

FIELD OF THE INVENTION

The present invention relates to a method for adjusting the idle stroke in a magnetic actuator and a manufacturing method for a magnetic actuator, a corresponding magnetic actuator, a batch of magnetic actuators and a system with such a magnetic actuator and an external component operated by the magnetic actuator.

BACKGROUND OF THE INVENTION

Electromagnets or magnetic actuators for actuating valves or other components, such as slides or levers, are used, for example, in automatic transmissions in automobiles. It is often an operational requirement of the magnetic actuator that a plunger, which is used to actuate such components external to the magnetic actuator itself, is definitely completely retracted into the magnetic actuator in the de-energized case, i.e. in a corresponding exit hole on a front side of the magnetic actuator is sunk.

In order to meet this condition, it is known to design the magnetic actuator in such a way that, in the de-energized case, the front side of the plunger enters the through hole by a certain distance, called idle stroke, that is, is spaced from a front surface of the magnetic actuator to the inside thereof. In this case, the idle stroke must be provided, for example, sufficiently large to ensure that the ram moves completely into the magnetic actuator, despite the component tolerances of the individual components that contribute to this idle stroke, such as the plunger and magnet armature. However, a large idle stroke leads, on the one hand, to a high impact speed of the plunger on the external component upon initial actuation of the magnetic actuator with corresponding noise and material abrasion and, on the other hand, to a relatively slow response. Furthermore, in this case a large number or a batch of such magnetic actuators shows a large scatter in their response behavior.

In order to reduce the idle stroke and possibly also its specimen variance in a batch, it is conceivable to measure at least the individual components that contribute to the idle stroke, such as the plunger and armature, during installation and to position them accordingly in the magnetic actuator to be manufactured. However, this makes production complex, since the corresponding components of each individual magnetic actuator have to be measured individually during its production.

Alternatively, it would also be conceivable to use corresponding individual components such as plungers and magnet armatures with a small component tolerance. However, this increases the component costs significantly.

SUMMARY OF THE INVENTION

The object of the present invention is therefore to provide a method for adjusting an idle stroke of a magnetic actuator or a manufacturing method for a magnetic actuator and a corresponding magnetic actuator that creates or enables a simplified and cost-effective manufacturing method for a magnetic actuator, in particular with a small idle stroke and small specimen variation . In addition, it is the object of the present invention to specify a corresponding batch and a corresponding system for the interaction of the magnetic actuator with an external component to be actuated.

The problem is solved by the independent claims. Advantageous refinements and developments are given in the dependent claims.

The present invention creates a method for adjusting an idle stroke in a magnetic actuator and provides a magnetic actuator with an adjusted idle stroke with the following steps.

Provision of a preferably cylindrical pole tube with a preferably cylindrical pole tube cavity for receiving a magnet armature which can be moved along a longitudinal axis of the pole tube (step (a)). In this case, the pole tube comprises a pole core or generally a pole core unit at an axial end of the pole tube or the pole tube cavity, which is referred to below as the front or front end of the pole tube, the magnet armature being on the pole core or the front end is moved or urged in this direction. The pole core consists of magnetic material, is optionally a part or a section of a preferably one-piece pole core tube and is part of the magnetic circuit of the magnetic actuator when the magnetic actuator is in operation.

The pole core is generally also a part or section of a pole core unit, the remaining part of the pole core unit being completely or partially made of a different material than the pole core, in particular an amagnetic material, and being firmly connected to the pole core. In the simplest case, however, the pole core unit is formed entirely by the pole core and accordingly consists entirely of magnetic material. A pole core unit is therefore referred to below, even if it consists exclusively of the pole core.

The pole core unit has an axial, usually cylindrical, through-hole for receiving and guiding a plunger, which usually lies on the longitudinal axis or is designed concentrically therewith. Furthermore, the pole core unit has a flat front face on a front side facing away from the pole tube or the pole tube cavity, which is usually perpendicular to the longitudinal axis and thus defines an exit plane of the magnetic actuator for the tappet. The flat front side surface preferably directly adjoins the through hole and / or completely surrounds the through hole and / or forms the complete front side of the pole core unit and thus of the magnetic actuator, facing away from the pole tube.

In a further step (b), a corresponding, preferably one-piece and / or cylindrical plunger, which usually consists of an amagnetic material, is introduced into the through hole of the pole core unit. On a front side facing away from the pole tube or the pole tube cavity, the tappet has a front axial end which is preferably partially or completely flat and perpendicular to the longitudinal axis of the tappet and thus an engagement or actuation surface of the tappet or the magnetic actuator Are defined. The longitudinal axis of the plunger coincides with the longitudinal axis of the through hole and, accordingly, usually also with the longitudinal axis of the magnetic actuator. Furthermore, the plunger or its front end is dimensioned so that it can be completely received or sunk into the through hole and thus positioned axially on a rear side of the front face of the pole core unit or the exit plane of the pole core unit or the magnetic actuator.

Furthermore, the magnet armature is introduced into the pole tube cavity of the pole tube and brought into engagement with the rear end of the tappet. In the simplest case, the magnet armature and the plunger are not firmly connected to one another and merely touch each other when they are brought into engagement. This can be done using gravity, for example, by positioning the magnetic actuator or the pole tube vertically in the gravitational field with the front facing down and successively filling the plunger and the magnet armature into the magnetic actuator to be created. Alternatively, the plunger and magnet armature can also be firmly connected to one another. In this case, the engagement or the (permanent) connection of the plunger and magnet armature occurs preferably before the introduction of the plunger and magnet armature into the magnet actuator to be created, which allows the plunger and magnet armature to be introduced into the magnet actuator as a common unit and corresponding assembly steps to be saved .

In a further step (c), the plunger is axially positioned in the through hole of the pole core unit and thus also the magnet armature engaging with the plunger in such a way that the front end of the plunger is a predetermined axial distance from the flat front surface of the pole core unit and thus the exit plane of the magnetic actuator for the plunger, that is, has moved into the through hole by the corresponding predetermined distance, this predetermined distance or this predetermined distance forming the idle stroke of the magnetic actuator and preferably in the range between 5 and 100 μm and, for example, 5, 10, 15, 20, 30, 50, 70 or 100 µm, each of the values mentioned can also be an upper or lower limit of the stated range. The positioning is done, for example, with the aid of a spacer element which rests on a flat support surface on which the flat front surface is positioned and which engages in the through hole so that the front end of the plunger engages the spacer element. In this case, the spacer element has a thickness which is equal to the predetermined distance, that is to say is equal to the idle stroke and, for example, has an outer diameter which is smaller than or equal to the diameter of the through hole.

In a further step (d), a rear stop position for the magnet armature and thus also for the plunger which is in engagement therewith is established by bringing a stop element into engagement with the magnet armature, in the simplest case being placed directly on the magnet armature and on the Magnetic actuator, in particular the pole tube, to create a rear mechanical stop for the armature, is fixed. This stop element, which is preferably arranged on a rear side of the magnet armature, defines the rear end of the travel path of the magnet armature. In the simplest case, the stop element is brought into engagement with a rearward axial end facing away from the pole core or the rear side of the magnet armature or is placed thereon. Furthermore, the fixing of the stop element is usually permanent fixing, which is preferably done by welding, laser welding, soldering and / or caulking of the stop element, preferably on or in the pole tube.

With the help of the described method for producing a magnetic actuator or for adjusting an idle stroke of a magnetic actuator, a magnetic actuator or electromagnet actuator is created, comprising a pole tube with a magnet armature that can be moved in the pole tube along the longitudinal axis and with a pole core unit arranged on a front side of the pole tube is, wherein the armature moves towards the pole core unit when energized or pushed towards the front becomes. The pole core unit has an axial through-hole for receiving a tappet, which preferably lies on the longitudinal axis or concentrically therewith. On a front side facing away from the pole tube or the magnet armature, the pole core unit has a flat front face, preferably designed as described above. In the through hole of the pole core unit, a corresponding, preferably one-piece and / or cylindrical, triangular, square or hexagonal plunger is arranged, which has a greater axial length than the through hole, so that, depending on the operating state of the magnetic actuator, at least one of the front and rear axial ends of the plunger protrudes beyond the through hole in the axial direction. As described above, the plunger has on its front side a preferably flat, front axial end which can be completely sunk into the through hole.

The magnetic actuator also has a stop element for the magnet armature, which defines a rear stop position for the magnet armature. When the magnet armature is in engagement with the stop element and the plunger, which is usually the case when the magnet actuator is de-energized, the front end of the plunger is at a predetermined axial distance from the flat front surface of the pole core unit, which represents the idle stroke of the magnetic actuator.

The manufacturing or adjustment method according to the invention creates a magnetic actuator with an adjusted idle stroke, in which, with regard to the idle stroke, the tolerance chain of the contributing individual components, such as plunger, magnet armature, stop element, etc., which can add up to several tenths of a millimeter, is omitted and this is increased accordingly Allows component tolerances of these individual components (plunger, armature, stop element, etc.), and thereby creates an idle stroke of the magnetic actuator, the tolerance or variance of which in the simplest case depends exclusively on the accuracy or the repeatability of the positioning of the plunger in step (c) and thus only from a single process step, in that the various components contributing to the idle stroke are jointly positioned, adjusted or fixed. The idle stroke tolerance is preferably even smaller than the component tolerance of one or each individual component, preferably smaller than the sum of the component tolerances of the plunger, magnet armature and / or stop element. In particular, such an idle stroke can be adjusted or mechanically set with little variance or scatter, without the individual components having to be measured, so that the manufacturing or adjustment method according to the invention can preferably be carried out without a measuring step. The idle stroke tolerance is preferably determined exclusively by the repeatability of step (c).

The magnetic actuator according to the invention is intended to interact with an external component, for example a slide, a valve, a lever, etc., which in the de-energized case usually rests on the front surface of the magnetic actuator or the pole core unit, so that when the magnetic actuator is energized, the plunger - after overcoming the idle stroke and exiting the through hole - exerts a force on the external component and pushes it away from the pole core unit, the external component preferably being displaceable linearly along the longitudinal axis of the magnetic actuator.

The low idle stroke spread according to the invention also allows a small amount of idle stroke to be provided (e.g. a few hundredths of a millimeter), while at the same time ensuring that the front of the plunger is completely retracted into the through hole on the front or does not protrude beyond it when the power is off . Accordingly, a magnetic actuator with a fast response behavior can be provided which at the same time enables a relatively low exit speed of the plunger from the through hole when current is started and thus possibly a correspondingly low impact speed of the plunger on the external component to be actuated.

When deflected away from the front, the external component preferably exerts a mechanical counterforce or restoring force, for example with the help of a spring element, on the plunger, so that on the one hand the deflection of the external component can be controlled by energizing the magnetic actuator and on the other hand the plunger in the de-energized case is pushed into the through hole. Accordingly, the magnetic actuator itself preferably has no restoring element, such as a spring element.

In particular, the method according to the invention makes it possible to create a batch with a large number of magnetic actuators which have a very low scatter in terms of their idle stroke and their response behavior. The idle stroke in a batch preferably has a variance, specimen variance or tolerance deviation of less than 50 μm, less than 20 μm, less than 10 μm or less than 5 μm from a predetermined axial distance or target idle stroke a batch of between 100 and 10,000, particularly preferably immediately one after the other manufactured or adjusted magnetic actuators, the number of the plurality of magnetic actuators being, for example, 100, 200, 500, 1000, 2000, 5000 or 10,000, with each of the values mentioned also including an upper or the lower limit of the stated range

In the method according to the invention, the method steps mentioned are preferably carried out in the order mentioned above or, for example, step (c) is carried out before the magnet armature is introduced.

In a preferred embodiment, the stop element is designed as a preferably flat, circular cover that closes the rear end of the pole tube, preferably completely and / or fluid-tight, so that any hydraulic fluid present in the pole tube cavity cannot flow off via the rear axial end of the pole tube. The cover is preferably fixed directly to the pole tube, in particular to a magnet tube of the pole tube. Such a cover enables a full-surface stop for the rear of the magnet armature. The cover is preferably designed in one piece and / or consists of an amagnetic or a magnetic material. To fix it, the cover is preferably welded all the way around, preferably with the aid of a laser.

The magnet armature is usually an essentially cylindrical or exactly cylindrical body, the longitudinal axis of which coincides with that of the pole tube. Correspondingly, the pole tube has a corresponding, usually cylindrical, cavity or magnet space in which the magnet armature can be moved linearly along the longitudinal axis. The longitudinal axis of the pole tube is also the longitudinal axis of the magnetic actuator.

The pole tube can be constructed in one piece, two pieces or in several pieces and accordingly have two or more pole tube components. Such pole tubes are for example in the DE 10 2016 103 168.2 and in the publications mentioned therein and their disclosure content with regard to the design of the pole tube and the electromagnet or the magnetic drive is included in the present document.

Correspondingly, the pole tube preferably comprises a magnet tube and a pole core tube as pole tube components, and particularly preferably precisely these two pole tube components, the pole core preferably forming a section of the preferably one-piece pole core tube. The magnet tube has a through hole and the pole core tube has a blind hole for the magnet armature. These recesses, i.e. through hole and blind hole, together with an axial air gap usually located between them, tapering or conical and / or stepped on the magnet tube and / or pole core tube, create the pole tube cavity or magnet space of the pole tube for the movable Magnet armature, that is to say that space in which a magnet armature of the magnet actuator moves linearly or in a straight line along its longitudinal axis. Correspondingly, the recesses in the magnet tube and pole core tube have the same inner shape that corresponds to the outer shape of the magnet armature, which is usually cylindrical and has the same inner diameter, so that, apart from the axial air gap, due to the concentric arrangement of the two pole tube components or their recesses, a pole tube cavity with offset-free wall is created. The pole core usually forms an axial, front-side end of the magnet space, usually the bottom of the blind hole in the pole-core tube, and also serves, if necessary, as a front-side stop for the magnet armature.

The pole core or the pole core tube and the other pole tube component (s) of the pole tube consist of a magnetic or magnetically conductive or ferromagnetic material. Correspondingly, the pole tube is, for example, together with a magnetic housing, which extends in a manner known per se around a magnet coil surrounding the pole tube or on the outside thereof, during operation or when the magnet coil is energized, part of the magnetic circuit of the Magnetic actuator.

The inner diameter of the pole tube, that is to say the inner diameter of the through hole of the magnet tube and the blind hole of the pole core tube, is preferably in the range between 5 and 50 mm and is, for example, 5, 6, 7, 8, 10, 11, 12, 13, 15, 20 , 25, 30, 40 or 50 mm, whereby each of the stated values can also be an upper or lower limit of the stated range. The diameter of the plunger is preferably in the range between 1 and 20 mm and is, for example, 1, 2, 3, 5, 7, 10, 12, 15 or 20 mm, each of the values mentioned also being an upper or lower limit of the said range can. The magnetic force generated by a magnetic actuator is preferably in the range between 0 and 50 N and is, for example, 0, 1, 2, 3, 5, 10, 15, 20, 25, 30, 40 or 50 N, each of the values mentioned also including one Can be the upper or lower limit of the stated range. Furthermore, the stroke of the magnetic actuator is preferably in the range between 0.5 and 50 mm and is, for example, 0.5, 0.7, 1.0, 1.5, 2.0, 3.0, 5.0, 10, 15 , 20, 30, 40 or 50 mm, whereby each of the stated values can also be an upper or lower limit of the stated range

Figure list

• 1 einen Längsschnitt durch ein Ausführungsbeispiel eines erfindungsgemäßen Magnetaktuators, und
• 2 ein Flussdiagramm eines Ausführungsbeispiels des erfindungsgemäßen Justage- bzw. Herstellungsverfahrens.

Further advantages of the invention are described below on the basis of the exemplary embodiment explained in the accompanying figures. The exemplary embodiment represents a preferred embodiment which in no way encompasses the invention restricts. The figures shown are schematic representations that do not necessarily reflect the real proportions, but rather serve to improve the clarity of the exemplary embodiment. The figures show in detail:

• 1 a longitudinal section through an embodiment of a magnetic actuator according to the invention, and
• 2 a flow chart of an embodiment of the adjustment or production method according to the invention.

DETAILED DESCRIPTION

1 shows a longitudinal section through a magnetic actuator according to the invention 1 along its longitudinal axis A. in the de-energized case. The magnetic actuator comprises a pole tube 2 , which is a pole core tube 3 and a magnet tube 4th includes. Pole core tube 3 and magnet tube 4th in this exemplary embodiment run stepped or conically towards an axial air gap between them. The pole core tube 3 has a blind hole for the magnet armature 5 on, in which the along the longitudinal axis A. of the magnetic actuator 1 movable magnet armature 5 retracts when energized. The pole core tube 3 comprises, in addition to the partially conical walls of the blind hole, a pole core connected to it in one piece 3a .

In the illustrated embodiment is on the pole core 3a another component 3b made of a-magnetic material with the pole core 3a firmly connected, axially on the front of the pole core 3a and is arranged concentrically therewith and together with the pole core 3a forms the pole core unit. In an alternative, not shown embodiment, the entire pole core unit is through the pole core 3a formed and it is not a further component 3b available. In the pole core unit is one on the longitudinal axis A. lying, cylindrical through hole formed in which a plunger 6th to be led. The pole core unit, which in this case consists of the pole core 3a and the other component 3b exists, as of the armature 5 facing away from the front a completely flat front surface or front surface, which in the present case is on the further component 3b the pole core unit is formed, into which the through hole of the pole core unit opens perpendicularly and which at the same time the front end of the magnetic actuator 1 forms. To the pole tube 2 around is a solenoid in a known manner 7th arranged as well as an outer magnet housing 8th to close the magnetic circuit when energized.

On the rear of the pole core tube 3 remote axial end of the pole tube 2 is a rigid, here metallic cover 9 as a rear stop element for the magnet armature 5 arranged. The lid closes 9 the rear end of the pole tube completely and possibly fluid-tight or pressure-tight. On the rear end of the pole tube 2 is also an electrical connection unit or connector unit 10 for the electrical supply of the solenoid 7th arranged. In the present exemplary embodiment, magnet armatures are used 5 and plunger 6th not firmly connected. Alternatively, magnet armatures can be used 5 and plunger 6th but also be firmly connected to each other.

In the in 1 The magnet armature is in the de-energized case shown 5 with the lid 9 in engagement, i.e. the two components are in contact. The ram is also there 6th with the magnet armature 5 in engagement, that is, these two components also touch. On the front of the magnetic actuator 1 , that is to say on the flat front surface of the pole core unit or its further component 3b is the front end of the plunger, which in the present case is flat 6th retracted a predetermined distance into the through hole, which in the present case is an idle stroke 11 referred to as.

The magnetic actuator 1 is provided with an external component 20th cooperate with the help of the plunger 6th can be deflected and for example along the longitudinal axis A. is linearly displaceable. The external component 20th is for example with the help of a preload spring 21st in the opposite direction, on the magnetic actuator 1 too crowded and is therefore flush with the flat front surface of the magnetic actuator in the de-energized case 1 or its pole core unit, in this case the further component 3b , at. When energized, the armature becomes 5 towards the pole core 3a pushed and thus moves the plunger 6th towards the outside of the armature 1 and thus on the external component 20th to. In doing so, tappets overcome 6th and magnet armature 5 the previously adjusted, predetermined idle stroke 11 and the plunger strikes because of the adjusted idle stroke 11 or the small number of copies of the idle stroke 11 always, that is, in each copy of the MatAkt 1 according to the invention, at the same or at least essentially the same speed to the external component under the same energization conditions 20th or comes with the external component 20th engaged. In other words, the specimen variance of the impact speed is also low. In addition, the idle stroke is 11 typically in the range of a few hundredths of a millimeter (in the present exemplary embodiment between 5 and 100 μm, in particular at 20 μm) and is therefore relatively small, so that the impact speed of the ram 6th , the resulting material abrasion and the resulting noise development are low or negligible.

Is the spring constant or the return force characteristic of the preload spring 21st known so may so that, for example, a regulating stroke magnet and, if necessary, a proportional magnet can be created.

In the illustrated embodiment, the magnetic actuator 1 an axial length of 34 mm, the pole core unit or its further component 3b by 0.05 mm from a front end of the outer housing of the magnetic actuator 5 survives.

In 2 is the manufacturing or adjustment method according to the invention for the magnetic actuator 1 shown schematically.

In step (a), a pole tube as described above with a pole core unit with a flat front face and a through hole is provided. Step (b) can then be divided into several individual steps. In step (b1), a plunger 6th introduced into the through hole. In a further step (b2) the magnet armature is inserted into the pole tube 2 brought in. In a further step (b3) the magnet armature 5 with the ram 6th brought into engagement, for example, the armature 5 on the ram 6th placed using gravity.

In a further step (c) the plunger 6th positioned in such a way that its front end is a predetermined distance, namely the idle stroke 11 from the flat front surface of the pole core unit.

In the following step (d), a rear stop element, for example in the form of a cover 9 , with the axial back of the armature 5 brought into engagement, for example on the axial rear side of the armature 5 and then the lid 9 with the surrounding pole tube 2 , especially its magnet tube 4th welded, for example circumferentially, so that the pole tube is fluid- and / or pressure-tight on the back. This makes the idle stroke 11 fixed or adjusted.

In the exemplary embodiment shown, the method steps are carried out in the order mentioned. Alternatively, step (c) can also be carried out before step (b2). As a further alternative, step (b3) can also be carried out before the introduction of the plunger (step (b1)) and magnet armature (step (b2)) and magnet armature 5 and plunger 6th be introduced as a common unit in the armature.

List of reference symbols

A.

Longitudinal axis

1

Magnetic actuator

2

Pole tube

3

Pole core tube

3a

Pole core

3b

amagnetic, further component

4th

Magnetic tube

5

Magnet armature

6

Plunger

7th

Solenoid

8th

outer magnet housing

9

cover

10

Connector unit

11

Idle stroke

20th

external component

21st

Preload spring

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• DE 102016103168 [0026]

Claims (15)

A method for adjusting an idle stroke of a magnetic actuator (1), comprising the steps: (A) providing a pole tube (2) for receiving a magnet armature (5) which can be moved along a longitudinal axis (A), a pole core unit being arranged on a front side of the pole tube, having a through hole for receiving a plunger (6), the pole core unit being a has flat front surface, (b) Introducing the plunger with a preferably flat front end and the magnet armature such that the plunger and magnet armature are in engagement, (c) positioning the plunger such that the front end of the plunger is at a predetermined axial distance (11) from the front surface, and (d) Establishing a rear stop position by bringing a stop element (9) into engagement with the magnet armature, in particular on a rear side of the magnet armature, and fixing the stop element on the magnet actuator, in particular on the pole tube and / or by laser welding. Procedure according to Claim 1 , characterized in that the method steps are carried out in the order mentioned or step (c) is carried out before the magnet armature (5) is introduced. Procedure according to Claim 1 or 2 , characterized in that in step (c) the predetermined distance (11) is in the range between 5 and 100 µm. Method according to one of the preceding claims, characterized in that in step (b) first the tappet (6) is introduced into the through hole and then the magnet armature (5) is introduced into the pole tube (2) and preferably the tappet and magnet armature are not firmly connected, or the plunger and magnet armature are introduced into the through hole or the pole tube as a unit that is firmly connected to one another. Method according to one of the preceding claims, characterized in that step (c) is carried out with the aid of a spacer element which preferably has a thickness which is equal to the predetermined spacing (11). The method according to any one of the preceding claims, characterized in that the method includes a magnetic actuator (1) according to one of the Claims 7 to 13 creates. Magnetic actuator (1), which is preferably after one of the Claims 1 to 6th is produced or adjusted, comprising - a pole tube (2) with a magnet armature which can be moved in the pole tube along a longitudinal axis (A), - a pole core unit which is arranged on a front side of the pole tube, having a through hole for receiving a plunger (6) and having a flat front surface, and a plunger with a preferably flat front end, the through hole being set up such that the front end of the plunger can be completely received in the through hole, characterized in that the magnetic actuator has a rear, preferably laser-welded stop element (9), and the front end of the plunger has a predetermined axial distance (11) from the front side surface when the magnet armature is in engagement with the stop element and the plunger. Magnetic actuator (1) Claim 7 , characterized in that the predetermined distance (11) between the front end of the plunger (6) and the flat front surface of the pole core unit is in the range between 5 and 100 µm. Magnetic actuator (1) Claim 7 or 8th , characterized in that the flat front surface of the pole core unit adjoins the through hole and / or completely surrounds the through hole and / or forms the front side of the pole core unit. Magnetic actuator (1) according to one of the Claims 7 to 9 , characterized in that the plunger (6) and the magnet armature are firmly connected to one another or are not firmly connected to one another and / or the magnetic actuator has no resetting spring element or no pretensioning spring. Magnetic actuator (1) according to one of the Claims 7 to 10 , characterized in that the stop element (9) is a cover which closes the pole tube and is preferably fixed to the pole tube (2). Magnetic actuator (1) according to one of the Claims 7 to 11 , characterized in that the pole core unit consists of the pole core (3a) or comprises the pole core and comprises at least one further component (3b) which is firmly connected to the pole core and is made of a different material than the pole core, preferably of an amagnetic material consists. Magnetic actuator (1) according to one of the Claims 7 to 12 , characterized in that the pole tube (2) consists of a pole core tube (3), which preferably comprises the pole core (3a) in one piece, and a magnet tube (4). Batch comprising a plurality of magnetic actuators (1) according to one of the Claims 7 to 13 or a variety of according to one of the Claims 1 to 6th manufactured or adjusted magnetic actuators, characterized in that the predetermined axial distance (11) in the plurality of magnetic actuators of the batch has a tolerance deviation of less than 50 µm, less than 20 µm, less than 10 µm or less than 5 µm . System comprising a magnetic actuator (1) according to one of the Claims 7 to 13 or one after one of the Claims 1 to 6th produced or adjusted magnetic actuator, as well as an external component (20) actuated by the magnetic actuator, which is preferably set up to exert a restoring force on the plunger (6), so that the magnetic actuator in the system is particularly preferably set up as a lifting control magnet, preferably as a proportional electromagnet to work, the system or the magnetic actuator is preferably intended for use in a transmission, in particular in an automatic transmission of a motor vehicle.

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