DE10304638B4 - Switching relay with two magnetic coils and method for producing a switching relay with two magnetic coils - Google Patents

Abstract

Switching relay with two magnetic coils (2, 3) with magnetic core (24), an armature (10), a yoke (4), two movable switching contacts (15, 16), a fixed contact (18, 19), the armature (10) is movably mounted between the two magnet coils (2, 3) and can be switched into two different switching positions depending on the energization of the magnet coils (2, 3), one of the two switching contacts (15, 16) depending on the switching position of the armature (10) is pressed by the armature (10) against the fixed contact (18, 19), characterized in that
the magnetic cores (24) are arranged next to one another in the longitudinal direction,
that each magnetic core (24) has a pole piece (13) which, starting from one end of the magnetic coil (2, 3), is assigned to the armature (10) arranged in the longitudinal direction between the magnetic coils (2, 3).

Description

Switching relay with two solenoid coils and method for producing a switching relay with two solenoid coils.

The invention relates to a switching relay with two magnetic coils according to the preamble of claim 1 and method for producing a switching relay with two magnetic coils according to the preamble of claims 11 and 13.

Electromagnetic relays are in various designs are known and are used in various technical fields, especially in used in automotive engineering to switch currents.

From DE 4122704 C2 is an electromagnetic Relay in the form of a polarity reversal relay with two coils and one common Anchor known. The coils are arranged in a longitudinal axis, with between a contact space is formed for the two coils. The two coils is assigned a yoke plate that runs along the two long sides of the coils is. In the area of the contact space, the armature is pivotable on the Yoke plate attached. Between the armature and a magnetic core A contact spring is arranged in a coil. At one end is the contact spring in the area of the yoke plate on a contact pin supported. A second end of the contact spring has a contact piece and is arranged between two counter contacts. The contact spring is biased in such a way that the contact spring in a rest position abuts the first or the second counter contact. Now becomes one of the two coils, the armature is energized in the direction of the Coil swiveled. Doing so the armature is arranged between the armature and the core pole face Contact spring from the rest position to a working position. In the Working position is the contact spring on the second counter contact on. By correspondingly timed energization of the two coils can the two contact springs alternately in the respective working position be moved.

The object of the invention is in providing a relay that is more compact in structure having.

Furthermore, the invention has the Task on an advantageous method for producing a double relay provide.

The objects of the invention will be by the features of claim 1 and by the features of the claim 11 and 13 solved.

Further advantageous embodiments of the invention are in the dependent claims specified.

Out DE 36 30 467 A1 a relay is known which has a mounting base made of insulating material to which the contact system and the magnet system are attached. Furthermore, a cover cap is provided, which extends to the bottom of the mounting base. Coil and contact connections are led out of the mounting base. The core of the magnet system is arranged in the direction of the longitudinal axis of the cover cap. A coil former is integrally formed on the mounting base on the side opposite the floor, and an opening, which is open at least on one side and in which the pole piece is inserted, is provided between the mounting base and the inner flange of the coil base.

Out DE 197 27 991 C1 an electromagnetic relay is known which has a magnet system with a coil and a coil body and with a substantially L-shaped core. The core is guided with its long leg through the coil, so that an armature with a short leg is mounted on its free end so that it can be rolled. The armature is also essentially L-shaped.

Out DE 33 40 735 C2 a DC tariff switching relay is known which has a double coil body with two windings. The double bobbin is made in one piece and serves to hold the two windings. The double bobbin is made of thermoplastic material in one piece and in the stretched state. The double bobbin can be aligned by bending it into two parallel bobbins.

Out JP 2000 011838 A (Abstract) An electromagnetic relay and a method for mounting the iron core of the electromagnetic relay are known. The relay has a support frame for an armature, which has a terminating edge lying outside the winding. The end edge is to be adjusted to an end face of a pole piece that is connected to the magnetic core. To determine the distance, the magnetic core has a press-in end, which is pressed into the support frame with the appropriate depth. In this way, a precise determination of the desired distance is possible.

A major advantage of the invention is that the two coils are not arranged along an axis are, but are arranged side by side. Between the two coils a contact space is formed in which the armature is arranged. The new choice of arrangement of the coils makes it particularly compact Construction of the relay possible.

In a preferred embodiment According to the invention, the coils have a common coil body.

Depending on the embodiment, it can also be advantageous be for each coil form its own bobbin separately.

In a further preferred embodiment form the pole piece is integrally formed with a core of a coil.

Due to the one-piece embodiment, the production of the pole piece with the magnetic core inexpensively manufacture.

The pole piece preferably has on one side, which is assigned to the anchor, a contact surface for the anchor.

Through the contact surface allows the armature to be placed on the pole piece and thereby the Holding the anchor needed Holding force realized. In a corresponding manner, the anchor points in an area of the contact surface is also assigned a flat second contact surface.

In a preferred embodiment is the contact surface formed as a separate component that attaches to the pole piece is. In this way, a very precise production of the contact surface can be made independently of the shape of the pole piece getting produced. This is a more flexible structure in manufacturing given.

In a further preferred embodiment the yoke plate has recesses and the magnetic cores are in the recesses inserted. In a preferred embodiment the magnetic cores are firmly connected to the yoke plate. Farther In a preferred embodiment, the yoke plate is designed as a flat surface. This is an inexpensive one Production of the yoke plate given.

The magnetic cores are preferably over a Weld, an adhesive layer or caulking the yoke plate to the core connected.

In a further preferred embodiment the yoke plate is U-shaped trained and guided with one leg each in a magnetic coil.

Due to the U-shaped design of the yoke plate the coils can be adjusted. In addition, the Yoke plate take over the function of a magnetic core.

The legs are preferably the Yoke plate passed through the coil and with one pole piece each connected. With that takes over one leg of the yoke plate is the holder for the pole piece. Preferably the function of the magnetic core in this embodiment taken from the legs of the yoke plate.

In a preferred embodiment a contact rivet is provided as a double contact.

A simple adjustment procedure A relay with two coils consists of having the two coils to insert a magnetic core into recesses in the yoke plate and after adjusting the pole pieces with respect to a target position to firmly connect the magnetic cores to the yoke plate. To this Way becomes a very precise and easy adjustment of the pole pieces provided.

The invention is based on the following of the figures explained. Show it:

1 a schematic representation of a relay,

2 a schematic representation of the relay from a second perspective,

3 a cross section through the relay,

4 a second cross section through the relay,

5 a side view of the relay,

6 a one-piece bobbin for two coils,

7 a U-shaped yoke plate, and

8th a yoke plate with pole piece.

1 shows a perspective view of a relay 1 with two coils 2 . 3 that on a yoke plate 4 are upset. The yoke plate 4 can be formed in one part or in several parts. The first and second coil 2 . 3 are each arranged with their longitudinal axes next to one another, preferably parallel to one another and on the yoke plate 4 applied side by side. The spools 2 . 3 are each on a bobbin 5 . 6 ( 3 . 4 ) applied, the coils 1 . 2 each between an upper and a lower flange 7 . 8th are arranged. The top flange 7 has electrical connections 9 for contacting the first or second coil 2 . 3 on. The connections 9 are with the wire of the coils 2 . 3 connected.

Between the first and the second coil 2 . 3 a contact space is formed in which an anchor 10 is arranged. The anchor 10 is with the yoke plate 4 in the area between the first and the second coil 2 . 3 connected to a lower end, the anchor 10 movable on the yoke plate 4 is stored. For storing the anchor 10 points the yoke plate 4 bearing recesses 11 ( 2 ) on the opposite long sides of the yoke plate 4 are introduced. The anchor 10 has retaining tabs 12 ( 2 ) at the bottom of the anchor 10 on the outside of the anchor 10 are trained and in the bearing recesses 11 the yoke plate 4 intervention. In this way, a bracket of the anchor 10 on the yoke plate 4 achieved a lateral tilting of the anchor 10 towards the first and second coils 2 . 3 allowed.

At the top of the first and second spools 2 . 3 is a pole piece 13 provided that is in the direction of the anchor 10 extends in the form of an arch and into a contact plate 14 transforms. The pole piece 13 and the contact plate 14 represent a pole piece, which the magnetic field from the magnetic core 24 towards anchor 10 passes. The contact plate 14 is from the upper end of the first or second coil 2 . 3 laterally along the first or second coil 2 . 3 led down a predetermined distance. Between the anchor 10 and the first and second coils, respectively 2 . 3 is a first or second spring contact 15 . 16 arranged. The first and the second spring contact 15 . 16 are with a lower end in the area of the lower flange 8th supported. The spring contacts 15 . 16 are designed in the form of a leaf spring and up to the anchor 10 out into a switching area 17 guided. In the switching area 17 is an electrically conductive first leg 18 formed with the two leg ends, the first and the second spring contact 15 . 16 includes. Between the first and the second spring contact 15 . 16 is in the switching range 17 a counter contact 19 educated. The two side contacts of the counter contact 19 are preferably represented by a contact rivet.

The first and the second spring contact 15 . 16 each have two contact surfaces in the upper end region, which are formed on both sides of the spring contact. The coat hanger 18 and the counter contact 19 have a first and a second pin 20 . 21 on.

The spring contacts 15 . 16 are electrical with a first and a second contact pin 22 . 23 connected, each in the lower flange 8th the first or the second coil 2 . 3 are supported.

2 shows a view of the relay of the 1 from underneath. The shape of the mounting of the first and the second spring contact is clear 15 . 16 on the contact pins 22 . 23 to recognize. The spring contacts 15 . 16 are with a lower end around the first and second contact pin 22 . 23 bent, the bent end of the first or second spring contact against the lower flange 8th is excited and thus the first or the second spring contact 15 . 16 against the central counter contact 19 biases. The first and second spring contacts are thus in the rest position 15 . 16 on the counter contact 19 on. Between the first and the second spring contact 15 . 16 is the anchor 10 arranged.

The pole piece 13 is each with a magnetic core 24 connected in the first or second coil 1 . 2 is arranged and through a coil interior parallel to the longitudinal axis of the first or second coil 2 . 3 is aligned. The magnetic core 24 preferably fills the entire coil interior and is in the lower region of the first or second coil 2 . 3 through the lower flange 8th led out and preferably extends into recesses 25 the yoke plate 4 ,

In a simple embodiment, the recesses 25 be dispensed with and the magnetic cores 24 of the coils 2 . 3 are on the yoke plate 4 welded.

The pole piece 13 is preferably via a spherical contact surface with the magnetic core 24 contacts and extends leg-shaped starting from the upper end of the first or the second coil 2 . 3 inward towards the anchor 10 ,

In a preferred embodiment, the spring contacts have 15 . 16 in a contact area where the anchor 10 when the first or the second coil is energized 2 . 3 towards the contact plate 14 is moved, a recess 26 on.

In addition, preferably either the anchor points 10 or the pole piece 13 in the area of the recess 26 an increase 27 on, which is designed for example as a spherical plate.

In 2a is a cross section through the pole piece 13 , the first spring contact 15 and the anchor 10 shown with the anchor 10 is in a switching position in which the first spring contact 15 to the assigned contact of the bracket 18 rests and the anchor 10 through the recess 26 through to the system on the pole piece 13 comes. The increase 27 can also be at anchor 10 be trained. It is only essential that the anchor 10 and the correspondingly assigned pole piece 13 come into contact with each other. By anchoring the anchor 10 is the adhesive force with which the anchor 10 on the pole piece 13 is guaranteed. At the same time acts in the position of the anchor 10 does not rest on the pole piece, the entire surface of the pole piece, so that the attraction is increased by the larger area. There is thus a lower current for attracting the armature 10 to or to the pole piece 13 sufficient. In a simple embodiment, the recess 26 to be dispensed with.

3 shows in the lower area in 3a a side view of the relay 1 and at the top in 3b the cross section BB through the relay 1 , It is clear in 3a the increase 27 on the contact plate 14 to recognize the anchor 10 is facing. Furthermore, in 3a the implementation of the magnetic core 24 down to the yoke plate 4 shown.

In a preferred embodiment, the pole piece 13 formed as a separate component and is by caulking the magnetic core in the upper end region of the magnet coil with the magnetic core 24 contacted. The pole piece 13 and the contact plate 14 can be formed in one piece or as separate parts.

In 3b the cross section BB is shown, which the windings of the first and the second coil 2 . 3 , the first and the second bobbin 5 . 6 and the magnetic cores 24 shows. In addition, the contact plates 14 with the associated increases 27 shown. Furthermore, the anchor is 10 who is in the rest position between the assigned increases 27 is arranged, shown. It is also located between the anchors 10 and the contact plates 14 the first and the second spring contact 15 . 16 with the recesses 26 , The cutouts 26 are chosen in such a way that the total increase 27 through a recess 26 can protrude.

4 shows in a lower representation in 4a the relay 1 in a top view and in an upper representation in 4b a cross section AA through the relay 1 ,

In the illustrated embodiment, the attachment of the first and the second coil via the magnetic core is clear 24 in the yoke plate 4 to recognize. In addition, the magnetic core is in the illustrated embodiment 24 in one piece with the pole piece 13 and the contact plate 14 educated.

Preferably the pole piece 13 with the contact plate 14 and the increase 27 made of the same material as the magnetic core 24 ,

A simple procedure for adjusting the relay with the two coils 2 . 3 is in 5 shown schematically. Thereby a yoke plate 4 with recesses 25 intended. The first and second coils are fixed to the coil body 5 . 6 connected magnetic cores 24 on. There are also coils in the upper end 2 . 3 pole pieces 13 with system plates 14 and increases 27 intended. The magnetic cores 24 protrude in the lower area of the coil 2 . 3 over the lower flange 8th out. In addition, the end areas of the magnetic cores point 24 an almost adapted cross-section to the recesses 25 on. For mounting and adjusting the relay 1 are two coil modules, which have a magnetic core, a coil body, a coil and a pole piece, with the respective magnetic core 24 into the two recesses 25 the yoke plate 4 inserted. Then the pole pieces 13 or the areas caused by the increases 27 are formed, adjusted to each other to a target distance. Then the magnetic cores 24 firmly with the yoke plate 4 connected. The connection is made, for example, by a welding process, caulking the yoke plate 24 or gluing the yoke plate 4 with the magnetic cores 24 , Then the other components are attached.

By the method according to the invention, the coils and thus the pole pieces 13 with respect to a target distance and a target position and only then the coils 2 . 3 about the magnetic core 24 firmly with the yoke plate 4 To connect, a simple and precise method for producing a double relay is provided.

6a shows one for two coils 2 . 3 one-piece coil former 30 consisting essentially of two identical bobbin holders 31 is formed over a fle xibles hinge 32 are interconnected. The one-piece bobbin 30 has two coil holders 31 on, each having an upper and a lower flange 7 . 8th exhibit. The two lower flanges 8th are about the flexible joint 32 connected with each other. Any spool holder 31 has a continuous core recess 33 on that to hold the magnetic core 24 serves.

For the assembly of the two coils 2 . 3 becomes the one-piece bobbin 30 bent into an assembly position where the coil holder 31 are arranged almost parallel to each other, as in 6b is shown. The joint 32 is for example made of a flexible film made of plastic. The one-piece coil former is preferably 30 made of a plastic piece with the joint 32 educated. The one-story formation of the bobbin 30 offers a simple and inexpensive manufacturing process for the two identically constructed bobbins.

7 shows a perspective view of the U-shaped yoke plate 4 , The yoke plate 4 consists essentially of a plate 34 , which is rectangular. Starting from two narrow rectangular sides of the plate 34 extend two legs 35 , The yoke plate has a U-shape in cross section. The width of the legs 35 is somewhat reduced compared to the width of the plate 34 , The legs are in the assembled state 35 into the recesses of the first and second bobbins 5 . 6 or in the core recesses 33 of the one-piece bobbin 30 introduced. In this embodiment, the legs preferably take over 35 the function of the magnetic core 24 , At least the legs are preferred 35 made of a magnetically conductive material. By bending the legs accordingly 35 an adjustment of the pole pieces 13 is achieved in the assembled state. In this way, the U-shaped yoke plate enables 4 a simple and inexpensive adjustment procedure for the first and second coil 2 . 3 ,

8th shows the U-shaped yoke plate 4 with a pole piece 13 , The pole piece 13 is magnetically conductive with the upper surface of the leg when assembled 35 connected. In 8th is just a single pole piece 13 shown, but in the assembled state, the relay 1 two pole pieces assigned to each other 13 having. The pole piece 13 has a contact plate 14 with a contact surface. In addition, the pole piece points 13 a mounting recess 36 over which the pole piece 13 magnetically conductive with one leg 35 is contactable. Preferably the pole piece 13 about a brazing process with one leg 35 connected. The contact plate 14 has an increase in a preferred embodiment 27 on which the contact surface for the anchor 10 is trained.

The U-shaped yoke plate 4 consists of a soft iron material and can therefore be bent into an adjustment position to adjust the pole pieces. This is a simple and reliable and also precise adjustment of the pole pieces 13 to each other possible. Due to the advantageous adjustment method, a precise position of the pole pieces relative to one another can be achieved, with the legs 35 the yoke plate 4 be bent into a corresponding position to each other. The bending process takes place in the assembled state of the coils 2 . 3 instead of. For mounting the coils 2 . 3 become the coils with the bobbins 5 . 6 or with the one-piece bobbin 30 on the thighs 35 postponed and then two pole pieces 13 via a soldering process with the ends of the legs 35 connected. The pole pieces 13 are in the form of a cross section Angle formed with two legs. A longer leg of the pole piece 13 comes with one end of one leg 35 magnetically connected and a shorter leg of the pole piece is to the side of the corresponding coil 2 . 3 arranged and between the coil 2 . 3 and the anchor 10 positioned. The contact surface for the armature is on the shorter leg of the pole piece 10 educated.

After assembling the coils 2 . 3 can the adjustment process of the pole pieces 13 , ie the contact surfaces of the pole pieces 13 , be performed.

1

relay

2

first Kitchen sink

3

second Kitchen sink

4

yoke plate

5

first bobbins

6

second bobbins

7

upper flange

8th

lower flange

9

connections

10

anchor

11

bearing recess

12

retaining tab

13

pole piece

14

bearing plate

15

first spring contact

16

second spring contact

17

switching range

18

hanger

19

countercontact

20

first pin

21

second pin

22

first pin

23

second pin

24

magnetic core

25

recess

26

recess

27

increase

28

second increase

29

second relay

30

one-piece bobbins

31

spool holder

32

joint

33

Kernausnehmung

34

plate

35

leg

36 connecting recess

Claims (13)

Switching relay with two solenoid coils ( 2 . 3 ) with magnetic core ( 24 ), an anchor ( 10 ), a yoke ( 4 ), two movable switch contacts ( 15 . 16 ), a permanent contact ( 18 . 19 ), the anchor ( 10 ) movable between the two solenoids ( 2 . 3 ) and is dependent on the energization of the solenoid coils ( 2 . 3 ) can be switched to two different switching positions, depending on the switching position of the armature ( 10 ) one of the two switching contacts ( 15 . 16 ) from the anchor ( 10 ) against the fixed contact ( 18 . 19 ) is pressed, characterized in that the magnetic cores ( 24 ) are arranged side by side in the longitudinal direction so that each magnetic core ( 24 ) a pole piece ( 13 ) that starts from one end of the solenoid ( 2 . 3 ) in the longitudinal direction between the solenoids ( 2 . 3 ) arranged anchors ( 10 ) assigned. Switching relay according to one of claims 1 to 5, characterized in that the yoke plate ( 4 ) is bent into a U-shape and at least partially with one leg each in a magnetic coil ( 2 . 3 ) and that the legs with the pole pieces ( 13 ) are connected. Switching relay according to claim 1, characterized in that the magnetic coils ( 2 . 3 ) a common one-piece bobbin ( 30 ) exhibit. Switching relay according to one of claims 1 or 2, characterized in that the pole piece ( 13 ) in one piece with a core ( 24 ) a magnetic coil ( 2 . 3 ) is trained. Switching relay according to one of claims 1 to 3, characterized in that on an inside of the pole piece ( 13 ) the anchor ( 10 ) is assigned a contact area ( 14 ) for the anchor ( 10 ) or the switch contact ( 15 . 16 ) is trained. Switching relay according to claim 4, characterized in that the contact surface ( 14 ) is designed as a separate component which is connected to the pole piece ( 13 ) is attached. Switching relay according to one of claims 1 to 5, characterized in that the yoke plate ( 4 ) Recesses ( 25 ) and that in the recesses ( 25 ) Cores ( 24 ) of the magnetic coils ( 2 . 3 ) are inserted and with the yoke plate ( 4 ) are firmly connected. Switching relay according to claim 6, characterized in that the yoke plate ( 4 ) with the magnetic cores ( 24 ) via a weld seam, an adhesive layer or caulking the yoke plate ( 4 ) or the magnetic core ( 24 ) connected is. Switching relay according to claim 8, characterized in that the legs by the magnetic coil ( 2 . 3 ) are guided and with the pole piece ( 13 ) are connected. Switching relay according to one of claims 1 to 9, characterized in that the fixed contact has four contact surfaces, that two contact surfaces on opposite inner sides of a contact ( 18 ) are arranged so that a contact rivet ( 19 ) is arranged, which on two the inner sides of the contact ( 18 ) facing sides has contact surfaces. Procedure for adjusting a switching relay ( 1 ) with two magnetic coils ( 2 . 3 ), an anchor ( 10 ), a yoke plate ( 4 ), two switch contacts ( 15 . 16 ), a permanent contact ( 18 . 19 ), the anchor ( 10 ) movable between the two solenoids ( 2 . 3 ) and is dependent on the energization of the solenoid coils ( 2 . 3 ) can be switched to two different switching positions, depending on the switching position of the armature ( 10 ) one of the two switching contacts ( 15 . 16 ) from the anchor ( 10 ) against the fixed contact ( 18 . 19 ) is pressed, whereby in the magnetic coils ( 2 . 3 ) a magnetic core ( 24 ) is formed, characterized in that the magnetic cores ( 24 ) from the lower ends of the solenoids ( 2 . 3 ) protrude that the magnetic cores ( 24 ) in the area of the upper ends with one pole piece each ( 13 ) that the solenoids ( 2 . 3 ) with the magnetic cores ( 24 ) on the yoke plate ( 4 ) that the pole pieces ( 13 ) are adjusted to each other in a predetermined position and that the magnetic cores ( 24 ) on the yoke plate ( 4 ) are attached. A method according to claim 11, characterized in that the yoke plate ( 4 ) two recesses ( 25 ) that holds the magnetic cores ( 24 ) that the magnetic cores ( 24 ) with the lower ends in the recesses ( 25 ) that the pole pieces ( 13 ) and after the adjustment the magnetic cores ( 24 ) with the yoke plate ( 4 ) are firmly connected. Procedure for adjusting a switching relay ( 1 ) with two magnetic coils ( 2 . 3 ), an anchor ( 10 ), a yoke plate ( 4 ), two switch contacts ( 15 . 16 ), a permanent contact ( 18 . 19 ), the anchor ( 10 ) movable between the two solenoids ( 2 . 3 ) and is dependent on the energization of the solenoid coils ( 2 . 3 ) can be switched to two different switching positions, depending on the switching position of the armature ( 10 ) one of the two switching contacts ( 15 . 16 ) from the anchor ( 10 ) against the fixed contact ( 18 . 19 ) is pressed, whereby in the magnetic coils ( 2 . 3 ) a magnetic core ( 24 ) is formed, characterized in that the yoke plate ( 4 ) U-shaped with legs ( 35 ) is designed such that one leg ( 35 ) is guided by a magnetic coil that the legs ( 35 ) in the area of the upper ends with one pole piece each ( 13 ) that the pole pieces ( 13 ) by bending at least one leg ( 35 ) can be adjusted to each other in a predetermined position.