DE202007008281U1 - solenoid - Google Patents

Abstract

solenoid (2) with at least one energizable coil (6, 8), with an armature component (4), which by energizing the coil (6, 8) from an initial position in at least one stroke position is movable, and with at least one first reset element (36, 40) for resetting the anchor member (4) from the stroke position to the initial position (M), characterized in that at least one second return element (54) is provided which is the armature component (4) in a second section of Return movement subjected to a restoring force before reaching the initial position.

Description

The The invention relates to a solenoid.

starting point the invention are such solenoids in which the anchor and possibly Actuation tappet attached thereto Energizing coils each from an initial position to an end position or Hublage be spent and then after switching off the power by means of mechanical reset elements moved back to the initial position become. The reset elements these known lifting magnets are formed by spring elements, caused by the lifting movement of the armature, i. through their movement from the initial to the final position, be curious.

at the return movement changes from the stroke to the initial position the restoring force generated by the spring elements on the restoring path and participates according to the spring characteristics of the spring elements increasing reset path. In the initial position, the restoring force finally has its lowest value or has the value zero there. Especially at a vertical mounting position of the lifting magnets, in which the weight the armature acts against the restoring forces, or if external forces act on the anchor, the return direction contrary, it is often because of these forces not possible, to return the anchor exactly to the initial position.

In front In this background, it is the object of the invention, a solenoid to create its anchor in at least one stroke position as well can be accurately positioned even in the initial position.

These The object is achieved by a solenoid with the specified in claim 1 Characteristics solved. Advantageous developments of the invention will become apparent from the Dependent claims, the following description and the drawing.

Of the Lifting magnet according to the invention has at least one energizable coil, an armature component, by Energizing the coil from an initial position in at least one stroke position is movable, and at least a first return element for resetting of the anchor component from the stroke position to the initial position. According to the invention is at least a second return element provided, which the anchor member in a return movement in a second Section of the return movement subjected to a restoring force before reaching the initial position.

The Anchor component of the lifting magnet according to the invention forms part of a magnetic excited by a coil Knitting circle. The anchor component can be both an anchor act as well as an anchor with an attached actuating tappet. By energizing the coil, the anchor member of a Initial position in one in the direction of the longitudinal axis of the anchor component movable stroke position movable.

through of the first return element is placed on the anchor component to reset from the stroke position to the initial position a directed to the initial position Restoring force exercised. For this purpose, the first return element expediently designed as a spring element. This spring element is in the Solenoid preferably arranged such that it by the lifting movement the anchor component is stretched.

Around the first return element when resetting to support the anchor component, is a second return element intended. This second return element exercises on the Ancherbauteil also one at least partially in the direction of Initial position of the armature component directed restoring force. The second Return element is designed and arranged so that it does not cover the entire anchor component restoring path from the lifting to the initial position with a restoring force applied. In a first section of the return movement the anchor component, which connects directly to the stroke position is from the second return element no restoring force exercised on the anchor component. Only in a return direction on the first section of the return movement Following second section of the return movement acts the second return element in the direction of the initial position and thus supports the first return element when resetting of the anchor component.

The first portion of the return movement is typically dimensioned such that in it the tension of the spring element or the potential energy stored in it is so great that the first restoring element there alone in forces that counteract the return movement, alone to a return movement in position is. The second section of the return movement expediently begins where the restoring forces exerted by the first restoring element on the armature component have decreased so far due to their relaxation that they are no longer sufficient, in particular for a force acting on the armature component in opposition to the restoring direction, the armature component in FIG to move the initial position. By superimposed in this second portion of the return movement of the restoring force exerted by the first restoring element is exerted by the second restoring element additional restoring force, it is advantageously possible to spend the armature exactly in its initial position, even if one of the armature component directed against the Rückstellbe movement Power acts. The arrangement and Configuration of the second return element are thus preferably selected so that the second return element in the second portion of the return movement still has a greater voltage than the first return element. Preferably, the second return element at the beginning of the second portion of the return movement to its maximum voltage.

The Sizes of the first and second sections of the return movement are more advantageous To the performance characteristics of the magnetic circuit and the first return element, i.e. on the course of the magnetic force over the stroke and the course the restoring force on the restoring path Voted. To the anchor component during the return movement exactly in the To be able to position the initial position it is worthwhile, in the immediate vicinity of the initial situation large restoring forces to disposal to deliver. For this reason, it is beneficial to the second section the return movement, while the second return element the anchor component in addition to the first return element with a restoring force applied, if possible to keep small. Therefore, the second section is the return movement expediently shorter as the first section of the return movement. Preferred is an embodiment in which the second section of the Return movement only forms a section shortly before reaching the initial position.

In a preferred embodiment generates the second return element a force across and preferably normal to the direction of the return movement of the Anchor component. Here, the second return element acts via a Deflection element such on the anchor member, that this of the second Return element with a restoring force in the direction of the return movement is charged. As deflecting a can with the anchor component motion-coupled component or an area of the armature component itself be provided, in which at least one force component of the second restoring element exerted force in the direction of the return movement, i.e. is deflected in the direction of the initial position of the armature component.

Advantageous makes a diagonal and preferably at an acute angle to the direction of the return movement directed contact surface the deflecting element, wherein the second return element transverse to the contact surface to the direction of the return movement acts.

to Formation of the deflecting element may be preferred to the anchor component at least a region may be provided in which the cross-section of the anchor component obliquely in the stroke direction to its longitudinal axis rejuvenated. That is, in this area, the cross section of the armature component increases in the stroke direction and forms a relative to its longitudinal axis diagonally oriented Contact surface. At this oblique contact surface the anchor member preferably acts the second return element, the more advantageous Formed such that it is the contact surface of the Ancherbauteils applied with a compressive force transverse to the longitudinal axis. in this connection is the second return element in the solenoid arranged such that it is the tapered Area of the anchor component during its return movement in the second section of the return movement and preferably contacted shortly before reaching the initial position. The contact surface allows advantageously a force deflection of one of the second return element applied force, such that the direction of action of the second return element, i. the direction of the second return element force applied to the anchor member, deviate from the reset direction within wide limits can. Accordingly, the second return element can be particularly space-saving in the solenoid of the invention be arranged. Conveniently, However, here are the angle of the slopes to the longitudinal axis of the component and the Installation position of the second return element or its direction of action coordinated so that the anchor member on the slope surface with a sufficiently large, in the return direction acting force component acted upon by the second return element becomes.

The second return element is preferably designed as a spring element. This spring element, which is preferably formed by a compression spring, can be such be formed and arranged in the solenoid, that it at the Lifting movement of the anchor component from the initial position to the stroke position is tense and the stored potential energy at the provision of the anchor member in the initial position in the second section of Return movement in the form of a in the direction of the return movement acting restoring force emits.

Especially when the second return element the anchor component during the entire lifting and return movement on its surface contacted, a contact body is advantageously provided on the spring element, which rests against the anchor component. To the in the restoring and lifting movement between Armature component and contact body occurring friction forces preferably low, this contact body is advantageous as a sliding or rolling elements are formed, wherein it is preferably designed so that it as possible low contact surface forms with the anchor component. Preferably, the contact body of a ball in particular a detent ball formed part of a Ball catch connection can be, with the anchor member in the initial position can be held.

In a further preferred embodiment of the lifting magnet according to the invention this is designed as a Doppelhubmagnet. Here is the anchor component by means of two energizable coils from the initial position in two of the initial position in opposite Richtun gene spaced strokes movable. Accordingly, the initial position in this embodiment of the lifting magnet is a central position between a first and a second stroke position is arranged. By means of a first coil The armature component can be moved from the initial position to the first stroke position become. To the provision the armature component, a first return element is provided. By energizing a second coil, the anchor member in the second stroke position to be moved. To reset the anchor component from the second stroke position is expediently another first Return element intended. According to the opposite directions of movement when resetting the anchor member from the first and the second stroke position are the Effective directions of the two first return elements facing each other. Here are the first two reset elements expediently dimensioned such that the restoring forces exerted by them on the armature component in the desired Pick up initial position.

A Another development of the lifting magnet according to the invention looks at the Ancherbauteil one, preferably around the circumference of the anchor component extending, groove in front. This groove is advantageously arranged such that the second return element at engages in the initial position located anchor member in the groove. In particular, in an embodiment of the lifting magnet as Doppelhubmagnet are in this case both the groove bounding side surfaces of the groove relative to the longitudinal axis of the anchor member so inclined formed to be at the bottom of the groove, i. at the in radial Direction of the circumference or the surface of the anchor component furthest spaced portion of the groove, substantially obliquely to each other run. The two oblique faces the groove form in this embodiment, the deflection elements for the second return element. The second reset element or the second return elements can preferably engage in the groove in the initial position of the anchor, so that the anchor is kept exactly in the defined initial position.

Advantageous is the groove as a domed one Trained trough. That is, the cross-sectional contour of the groove has one curvy course uneven slope, to the desired Characteristic of the restoring force in the second section of the return movement is adjusted.

Basically the second return element at any location of the solenoid, i. relative to its longitudinal axis be arranged in the region of the ends as well as the middle. In appropriate Way is possibly also the position of the deflecting element, i. the related on the longitudinal axis the anchor member and the direction of action of the second return element bevel Contact surface, any. This can both the armature and an actuating tappet of the Anchor components z. B. provided at an axial end of the solenoid be.

Prefers has the lifting magnet according to the invention at least one core through which the second return element is guided. As part of the magnetic circle of action of the solenoid is the core typically arranged in one of the coils. A part of the anchor component, Preferably, an actuating tappet provided on this is in axial through the core Directed movable. Preferably, the core has a transverse direction and direction of movement the actuating tappet aligned Opening on, in which the second return element arranged so is that it is transverse to the actuating tappet to its longitudinal axis acts. Conveniently, In this embodiment, a deflecting element or oblique contact surface is provided on the actuating plunger. Advantageously, through the core are two diametrically opposite one another Restoring elements guided.

following the invention with reference to an illustrated in a drawing embodiment explained in more detail. In this demonstrate:

1 a lifting magnet designed as a double-stroke magnet in a cross-sectional view,

2 a force-displacement diagram of a conventional Doppelhubmagneten and

3 a force-displacement diagram of the Doppelhubmagneten invention.

The in 1 illustrated solenoid 2 is as Doppelhubmagnet 2 educated. In the double-stroke magnet 2 is an anchor component 4 through the interior of two in the direction of a common longitudinal axis A successively arranged coils 6 and 8th slidably disposed in the direction of the longitudinal axis A. The first coil 6 is on a bobbin 10 wrapped while the second coil 8th on a bobbin 12 is wound.

The anchor component has an anchor 14 and an actuating tappet 16 for operating external components, devices or the like. The anchor 14 and the actuating tappet 16 can be formed in one piece. At the in 1 illustrated anchor component 4 However, it is a separate actuating tappet 16 concentric through the anchor 14 guided. Here is the actuating tappet 16 so at the anchor 14 attached that a first ram section 16 ' of the actuating tappet 16 at the first coil 6 facing the end of the anchor 14 protrudes and a second tappet section 16 '' at the second coil 8th facing the end of the anchor 14 protrudes. The first tappet section 16 ' of the actuating tappet 16 used to operate an external component.

In which the first coil 6 carrying bobbin 10 is a first core 18 arranged on the second coil 8th or the bobbin 12 remote end of the bobbin 10 engages in these. Similarly, in that, the second coil 8th carrying bobbin 12 a second core 20 arranged. This engages in the bobbin 12 on the first coil 6 or the bobbin 10 remote end of the bobbin 12 one.

Concentric to the longitudinal axis A of the anchor component 4 have the first core 18 an opening 22 and the second core 20 an opening 24 on, wherein the tappet section 16 ' from the opening 22 protrudes and the tappet section 16 '' in the opening 24 protrudes.

The cores 18 and 20 are formed as Konuskerne, ie, in each case at the anchor 14 facing the end of the cores 18 and 20 An end portion is provided which tapers in the direction of the anchor 14 rejuvenated. Corresponding to these conical end regions of the cores 18 and 20 has the anchor 14 at its the core 18 facing side a hollow cone-shaped recess 25 and at its the core 20 facing side a hollow cone-shaped recess 26 on.

The hollow conical recesses 25 and 26 of the anchor 14 are each designed such that they at the recess 25 one the actuating tappet 16 surrounding abutment shoulder 28 and at the recess 26 one the actuating tappet 16 surrounding abutment shoulder 30 form. The breakthroughs 22 and 24 the cores 18 and 20 each in their anchor 14 facing end portion on a paragraph. The one in the opening 22 provided paragraph forms an actuating tappet 16 surrounding spring support 32 and the one in the opening 24 provided paragraph a the actuating plunger 16 surrounding spring support 34 ,

Between the anchor 14 and the first core 18 is a first return element 36 arranged. This reset element 36 relies on the one hand at the in the opening 22 of the first core 18 trained spring support 32 and on the other hand to one of these spring support 32 opposite arranged annular disc 38 off, on the anchor-side abutment shoulder 28 rests. Similarly, between the anchor 14 and the second core 20 another first return element 40 arranged. The reset element 40 relies on both in the opening 24 of the second core 20 trained spring support 34 as well as on an annular disk 42 off, on the anchor-side abutment shoulder 30 rests.

The first two reset elements 36 and 40 are made of compression springs designed as coil springs 36 and 40 formed, with the coil spring 36 the actuating tappet 16 of the armature component 4 in the region of the tappet portion 16 ' surrounds and the coil spring 40 the actuating tappet 16 in the area of the tappet section 16 '' surrounds.

Via an electrical connection 44 is the double-stroke magnet 2 conductively connected to a control device, not shown. With this control device is optionally the first coil 6 or the second coil 8th supplied with current. This allows the anchor component 4 be moved in two from a starting position in opposite directions spaced stroke positions. In 1 is the anchor component 4 represented in its located between the two stroke positions initial position.

Will be the first coil 6 energized, a first magnetic circuit is established, which is located in a 1 not shown housing or yoke, one between the bobbins 10 and 12 arranged first pole plate 46 , the anchor 14 , the core 18 and one on the bobbin 10 fitting magnetic yoke 48 extends.

By energizing the second coil 8th can be constructed in a similar manner, a second magnetic circuit, which is located on a housing or yoke of the solenoid, also between the bobbins 10 and 12 arranged second pole plate 50 , the core 20 and one on the bobbin 12 fitting magnetic yoke 52 extends.

With energized coil 6 becomes the anchor component 4 from the core 18 attracted and the tappet section 16 ' in its first stroke position further from the solenoid 2 moved out. At the same time, the coil spring 36 compressed or tensioned. Should the anchor component 4 be moved back to its initial position, the energization of the coil 6 completed. The coil spring 36 can relax, reducing the anchor component 4 is moved by the spring force in the direction of its initial position. In the initial position becomes the anchor component 4 finally from the there opposing coil springs 36 and 40 held in an equilibrium position.

Act on the anchor component 4 external forces, which are the opposite direction of return, it is with the coil spring 36 no longer possible alone, the anchor component 4 to move exactly to its initial position. For this reason, there are two second reset elements 54 provided as spring elements, each with a coil spring 56 and one on the coil spring 56 mounted spherical contact body 58 , are formed.

Each of the second return elements 54 is in the solenoid 2 through the core 18 guided, being attached to the core 18 two diametrically opposite openings 60 for receiving in each case a second return element 54 serve. The breakthroughs 60 run through the core 18 in the radial direction to that through the core 18 guided actuating tappet 16 , Accordingly, the return act adjusting elements 54 in the radial direction on the circumference of the actuating plunger 16 in the area of the tappet section 16 ' ,

Will be located in the first stroke position anchor component 4 moved in the direction of the initial position, exercises the second return element 54 in a first portion of the return movement to the return element no restoring force, since the spherical rolling elements 58 on a line parallel to the longitudinal axis A of the armature component on the surface of the actuating tappet 16 can slide or roll. This changes in a second section of the return movement, in which the contact body 58 a surface area of the actuating tappet 16 Contact, which has a trough-shaped groove 62 forms. By the side surfaces of the groove 62 are directed obliquely to the direction of the return movement, they form deflection elements, in which a component of the radial on the actuating plunger 16 acting force of the second return elements 54 in the return direction of the anchor component 4 is deflected so that the second return elements 54 provide an additional restoring force. In the initial position hold the second return elements 54 the actuating tappet 16 and thus the anchor component 4 in the manner of a ball catch connection exactly in the desired position.

The following is the advantage of a Doppelhubmagneten 2 according to the invention in comparison with a conventional magnet with reference to in the 2 and 3 shown Kaft-way diagrams shown.

2 shows the curve X1 of a restoring force F over the path S, that of a first return element 36 a conventional Doppelhubmagneten on the reset path S in a first direction Z1 of the return movement until reaching an initial position M on an anchor member 4 is exercised. In addition, in 2 the course X2 of a second restoring force, that of a further first return element 40 is generated via the reset path S in a return movement in a second, the first direction Z1 opposite direction Z2 shown.

In 3 the curves Y1 and Y2 of two opposing restoring forces are shown. Here, the force curve Y1 is one of both of a first return element 36 as well as from a second return element 54 attributable to the restoring movement in the direction Z1 resulting restoring force and the force curve Y2 one of both a first return element 40 as well as from a second return element 54 attributed during the return movement Z2 resulting restoring force.

In the 2 and 3 are the force curves X1, X2, Y1 and Y2 respectively on the anchor component 4 acting restoring force on the last section of the return travel just before reaching the initial position M (eg, about 5 mm before reaching the initial position) shown. In the 3 shown, adjacent to the initial position M return paths in the directions Z1 and Z2 correspond to the return paths on which the second return element 54 the actuating tappet 16 in the area of a trough-shaped groove 62 contacted, ie, it is the second portion of the return movement, in which the second return element 54 on the actuating tappet 16 or the anchor component 4 exerts an additional second restoring force, that of the first return element 36 respectively. 40 applied restoring force is superimposed. In the 2 shown reset paths correspond in terms of distance to in 3 shown return paths.

In the 2 shown force curves X1 and X2 have a linear course, depending on the return direction Z1 or Z2 of the return element 36 respectively. 40 on the anchor component 4 applied restoring force decreases linearly with increasing return travel and when reaching the initial position M has the value 0. Like the in 3 shown Kraftver runs Y1 and Y2 can be seen, takes those of the first return element 36 respectively. 40 and the second return element 54 jointly generated restoring force also decreases and reaches in the initial position the value 0, but the force decrease takes place in the direction of the initial position M progressive, ie, the restoring force decreases in the area shortly before reaching the initial position M initially over long distances significantly lower than in the 2 used conventional Doppelhubmagneten from then drop very steeply in the immediate vicinity of the initial position M to zero. Thus, at a distance H from the initial position M, that of the first return element 36 and the second return element 54 jointly generated restoring force in 3 about three times as large as those in the same Ent distance H from the initial position alone of the return element 36 generated restoring force in 2 , This makes it clear that the Doppelhubmagnet invention 2 a safe return of the anchor component 4 can ensure in the initial position M even in such a return movement opposing forces, in a conventional Doppelhubmagneten with in 2 Force curves shown would cause the anchor component 4 due to a too small restoring force does not reach its initial position M. In addition, the anchor component 4 due to the large restoring forces on both sides of the initial position M safely held in this.

2

lifting magnet, Double-acting

4

anchor component

6

Kitchen sink

8th

Kitchen sink

10

bobbins

12

bobbins

14

anchor

16

actuating ram

16 '

tappet section

16 ''

tappet section

18

core

20

core

22

perforation

24

perforation

25

recess

26

recess

28

contact shoulder

30

contact shoulder

32

spring support

34

spring support

36

Restoring element, coil spring

38

washer

40

Restoring element, coil spring

42

washer

44

connection

46

pole plate

48

yoke

50

pole plate

52

yoke

54

Return element

56

coil spring

58

Contact body

60

perforation

62

groove

A

longitudinal axis

F

Restoring force

X1

force curve

X2

force curve

S

restoring path

Z1

direction

Z2

direction

Y1

force curve

Y2

force curve

H

distance

Claims (11)

Lifting magnet ( 2 ) with at least one energizable coil ( 6 . 8th ), with an anchor component ( 4 ), which by energizing the coil ( 6 . 8th ) is movable from an initial position in at least one stroke position, and with at least one first return element ( 36 . 40 ) for resetting the anchor component ( 4 ) from the stroke position to the initial position (M), characterized in that at least one second return element ( 54 ) is provided, which the anchor component ( 4 ) is acted upon in a second portion of the return movement before reaching the initial position with a restoring force. Lifting magnet ( 2 ) according to claim 1, characterized in that the second portion of the return movement is shorter than a first portion of the return movement and preferably forms only a portion shortly before reaching the initial position (M). Lifting magnet ( 2 ) according to one of the preceding claims, characterized in that the second return element ( 54 ) a force transversely, preferably normal to the direction of the return movement of the armature component ( 4 ), wherein the second return element ( 54 ) via a deflecting element on the armature component ( 4 ) acts that this of the second return element ( 54 ) is acted upon by a restoring force in the direction (Z1, Z2) of the return movement. Lifting magnet ( 2 ) according to claim 3, characterized in that an obliquely, preferably at an acute angle to the direction (Z1, Z2) of the return movement directed bearing surface on which the second return element ( 54 ) acts transversely to the direction (Z1, Z2) of the return movement, the deflection element forms. Lifting magnet ( 2 ) according to one of the preceding claims, characterized in that the anchor component ( 4 ) has at least one region in which its cross-section tapers in the stroke direction obliquely to its longitudinal axis (A). Lifting magnet ( 2 ) according to one of the preceding claims, characterized in that the second return element ( 54 ) is formed as a spring element. Lifting magnet ( 2 ) according to claim 6, characterized ge indicates that on the spring element a on the anchor component ( 4 ) abutting contact body ( 58 ) is stored. Lifting magnet ( 2 ) according to one of the preceding claims, characterized in that the lifting magnet ( 2 ) is formed as a Doppelhubmagnet, wherein the anchor member ( 4 ) by means of two energizable coils ( 6 . 8th ) is movable from the initial position (M) into two stroke positions spaced from the initial position (M) in opposite directions. Lifting magnet ( 2 ) according to one of the preceding claims, characterized in that the deflecting element as a groove ( 62 ) and preferably as one around the circumference of the anchor member ( 54 ) running groove ( 62 ) is arranged, which is arranged such that the second return element ( 54 ) in the initial position (M) located anchor member ( 4 ), into the groove ( 62 ) intervenes. Lifting magnet ( 2 ) according to claim 6, characterized in that the groove ( 62 ) forms a curved trough. Lifting magnet ( 2 ) according to one of the preceding claims, characterized in that the second return element ( 54 ), preferably two diametrally opposed second return elements ( 54 ), through a core ( 18 ) of the lifting magnet ( 2 ) is or are.