DE1273693B - Electromagnetic relay with a magnetically generated rest position of the rotating armature - Google Patents

Description

Electromagnetic relay with a magnetically generated rest position of the rotating armature The invention relates to an electromagnetic relay with a two-part iron core and a two-wing rotating armature, which is magnetically generated rest position from a rotation around when the electromagnet system is excited executes its axis and thus the opening and closing of a contact arrangement causes. The object of the invention is, in such a relay, the mechanical Design the structure in such a way that shaking and shock loads are possible can have little effect. The requirement is a constructive solution to choose which is particularly suitable for automated production, and it Above all, it is of particular importance that not only a small number of individual parts is required, but that these parts are also easy to manufacture.

There are already known electromagnetic relays in which a Rotary armature for actuating the contact arrangement is present. However, these show the disadvantage that the assembly of the required items is relatively expensive is, so that considerable manufacturing costs arise for such a relay system. It is also known, the iron core of such a relay from two ferromagnetic To form components. It is also known to carry out the rest position of the rotating armature to produce a permanent magnet acting on an armature wing. However, it is so far not succeeded in creating an electromagnetic relay of the aforementioned type, that can be manufactured and assembled in the desired simplicity. Here comes especially the design of the ferromagnetic components is of particular importance to. The aim is to produce these only as cut parts without special follow-up tools for bending operations are required.

The disadvantages of known relays of the type specified in the introduction are avoided according to the invention that the iron core consists of two similar, T-shaped ferromagnetic components with inside the excitation coil mirror-inverted webs and assigned to the rotating armature as pole shoes Cross dividing consists. A preferred embodiment of the invention provides that the magnetically generated rest position of the rotating armature by a rod-shaped Permanent magnet is made to the transverse part of one of the T-shaped ferromagnetic components is parallel. Due to the shape of the T-shaped ferromagnetic components and the rod-shaped permanent magnet results not only a significant simplification in production, but also in assembly. In contrast to known embodiments in which the iron core in many cases are only subsequently provided with corresponding pole pieces must, which requires additional operations, the structure of the magnetic System largely simplified. Because the T-shaped components along their entire length have the same thickness and between them after their insertion into the excitation coil there is a positive connection, there is an effective core cross-section, twice the value of the cross-section of a single ferromagnetic component is equivalent to.

In an advantageous development of the invention, the swivel armature is frame-shaped and mounted on both sides with pins on vertical brackets. The swivel anchor is included executed cranked in the horizontal near the fulcrum. The one to achieve a defined rest position of the rotating armature provided permanent magnet is by a Elbow attached to a bracket.

An advantageous embodiment of the invention also provides that the excitation coil is horizontal and parallel to the base plate of the electromagnet Systems runs. The contact arrangement actuated by the rotating armature is between the excitation coil and the base plate arranged. The pivot anchor is positioned in such a way that that it is located approximately in the middle under the excitation coil. To operate the Contact arrangement can be the frame-shaped rotating armature on both longitudinal parts of the Assign an actuator to the frame, with electrical isolation of the rotating armature from the contact arrangement at the end of the actuators a glass ball for insulation serves. These actuators are located on the one assigned to the base plate Side of the swivel anchor. To an extensive conclusion of the electromagnet system before To achieve environmental influences, a cap can be placed on the base plate.

Further details of the invention emerge from the following Description of an exemplary embodiment. It shows F i g. 1 the top view of a designed as a relay electromagnet system, the protective cap of the relay is shown in section, F i g. 2 shows a section along the line 2-2 according to FIG. 1, Fig. 3 shows a section along the line 3-3 according to FIG. 2, P'i g. 4 one Section along the line 4-4 according to FIG. 2, fig. 5 is a plan view of the base plate the arrangement according to FIG. 2, fig. 6 shows a side view of the excitation coil with an iron core, partly in section, F i g. 7 shows a side view of the arrangement according to FIG. 6, F i G. 8 is a side view of the rotating armature, FIG. 9 is a plan view of the anchor according to FIG F i g. 8, Fig. 10 a drieti view of the base plate of the relay with contact arrangement, F i g. 11 is a side view according to FIG. 10, fig. 12 a general view of all Individual parts of the relay on a reduced scale.

In the F i g. 1 to 5 is a section of the protective cap. allows better representation of the details. The protective cap 18 is open at its lower end and shaped such that by placing it on the base plate 15, the entire. Relay unit completes. A small air opening 19 is only provided at the upper left end (FIG. 2). On the base plate 15 there are two L-shaped brackets 20 and 21 which are fastened to the base plate by spot welding 22, 23. The brackets 20 and 21 have a vertical and a horizontal arm. The horizontal arms are provided with the reference numerals 27 and 29 in the drawing, while the vertical arms have the reference numerals 26 and 28 (FIG. 6). A projection 30 is attached to the vertical arm 28 , by means of which a permanent magnet 31 is held on the bracket 21 and can be additionally secured, for example by soldering. The two armature supports 24, which are fastened to the base plate by spot welding 25, are each provided with a bore 32 at their upper end, which are used to receive the bearing pins 52 ′ of the armature 45.

According to FIG. 6 and 7, the electromagnetic system has an excitation coil 34 which has rectangular core openings. The excitation coil 34 protected by a bandage 41 is provided with two electrical connection lines 39 and 40 . An iron core is arranged in the excitation coil, which has two similar T-shaped members 42, which consist of a web 43 and a transverse part 44 , see FIG. 12. These T-shaped members 42 can be inserted mirror-inverted into the right-angled openings 37 of the excitation coil 34 and then, when pushed one over the other, form the iron core of the electromagnet system. The cross members 44 then serve as effective pole shoes for the armature 45. These T-shaped, flat members 42 are arranged in the assembled position in such a way that the lower T-shaped member with its cross member on the right side of the coil and the upper T-shaped member Link lies with its transverse part on the left side of the bobbin. The bracket arm 27 below is soldered to the lower T-shaped member, while the bracket arm 29 located on the other side is attached to the free end of the T-shaped member above.

In the F i g. 8, 9 and 12 are various details of the anchor 45 shown, which cooperates with the transverse parts (pole pieces) of the T-shaped links. The armature 45 is in the form of a frame and is close to its pivot point executed cranked in the horizontal. The pivot point of the armature 45 is through the Hinge pins 52 'indicated, which are located in the bores 32 of the carrier. Of the Anchor 45 consists, in particular, of FIG. 9 and 12 emerges from a frame with the parallel ends 46 and 47 and the likewise parallel arm parts 50 and 51, which are angled towards one another via a central part 49. About the pins 52 'is a rotary movement of the two-winged armature 45 is possible.

The armature 45 are two actuators 53 for the contact arrangement assigned. These actuators are at the bottom. of the armature 45, preferably fixed by soldering. To an electrical separation of the armature 45 from the contact arrangement To achieve, the actuators 53 each have a glass ball at their ends 55 for insulation.

If the components of the electromagnet system are assembled in the manner as shown in particular in FIGS. 1, 2 and 3 show, then the armature 45 will rotate when the excitation coil 34 has current flowing through it. The end 46 of the armature 45 is then brought up to the component 42 provided with a pole piece, so that the part 47 of the armature is placed under the pole piece 44 of the upper T-shaped member 42. After switching off the excitation of the coil 34, the permanent magnet 31 rotates the armature 45 clockwise, and the armature takes with its end piece 47 the in FIG. 2 rest position shown.

In the F i g. 5, 10, 11 and 12 show the individual components that are located on the base plate 15. This carries a number of electrical connections 56 ... 59 or 56 '. . . 59 '. These electrical connections are passed through the base plate 15 and are preferably insulated by a glass seal 60. The connections 56 ... 59 or 56 '. . . 59 'are attached side by side in parallel alignment lines. The electrical connections 59 and 59 'are connected to the coil connections 35 and 40, a power source which is not shown in the drawing is used to control the excitation coil 34. Two L-shaped electrical contact pieces 61 and 61 'are soldered to the electrical connections 56 and 56'; two other L-shaped brackets 62 and 62 ', however, are connected to the electrical connections 57 and 57'. The brackets 62 and 62 'are combined with corresponding contact pieces 63 and 63' which are located above and below the contacts 61, respectively. Furthermore, there are two electrically conductive L-shaped angle pieces 64 and 64 'which are soldered to the electrical connections 58 and 58'.

On the base plate 15 there are also two contact springs 65 and 65 ' provided, of which the contact spring 65 on the carrier 64 and the contact spring 65 'is attached to the carrier 64'. At the free end of the contact spring 65 or 65 'are the contact pieces 66 and 66'. From Fig. 11 can be seen like the contact spring 65 'between the contacts 61' and 63 'with its contact piece 66 'is switchable. In the position shown, the contact spring 65 'is an electrical Connection between the contact pieces 63 'and 66' established. Every contact spring can by the actuator 53 of the armature 45, through the insulating Glass ball 55, are actuated. Thus, as shown in particular in FIG. 2 shows switch the contact arrangement from the rest position to the working position. the The starting position of the armature or the contact arrangement is shown in FIGS. 2 to 4 emerges. In this case, the excitation coil 34 is de-energized and the armature 45 is held in a clockwise direction by the permanent magnet 31. This leaves the parts 46 and 47 of the armature 45 of the pole pieces 44 of the T-shaped Links 42 removed.

On the other hand, the excitation coil 34 is applied to a voltage of sufficient size is applied, an attractive force on the parts 46 and 46 is applied to the pole pieces 44 47 of the armature 45 exerted and this then rotates against the action of the permanent magnet 31, counterclockwise. This movement of the armature 45 causes the glass balls 55 actuate the contact springs 65 and 65 'and move them downwards, so that a separation of the contact pieces 66 and 66 'from the contact pieces 63 and 63 'occurs and instead a contact connection with the contact pieces 61 and 61 'is made. This position of the armature or the contact arrangement is so Maintained long until the current in the field winding 34 is interrupted and the armature 45 and thus the contact arrangement again in the starting position already described returns.

The electromagnetic relay is considerably enlarged in the drawing Scale shown. The following are intended as a guide to the true size of the relay External dimensions, based on the base plate or the protective cap of the relay, are used. The length is about 20 mm and the width and height each about 10 mm. Despite this smallness of the entire system in the specified volume including armature and switching means is housed is due to a stable structure of the parts and the absence of sensitive Components achieved that the relay described even under rough operating conditions is usable.

Claims (13)

Claims: 1. Electromagnetic relay with a two-part iron core and a two-winged rotating armature, which rotates around its axis from a magnetically generated rest position when the electromagnet system is excited and thus causes a contact arrangement to open or close, as it is indicated that the Iron core consists of two similar, T-shaped ferromagnetic components (42) with webs (43) arranged in mirror image within the excitation coil (34 ) and transverse parts (44) assigned to the rotating armature (45) as pole shoes. 2. Electromagnetic Relay according to Claim 1, characterized in that the magnetically generated rest position of the rotating armature (45) produced by a rod-shaped permanent magnet (31) is that of the transverse part (44) of one of the T-shaped ferromagnetic Components (42) is parallel. 3. Electromagnetic relay according to claim 1, characterized characterized in that the T-shaped components (42) have the same overall length Have thickness and between them after their insertion into the excitation coil (35) there is a positive connection. 4. Electromagnetic relay according to claim 1, characterized in that the pivot armature (45) on both sides with pins (52 ') vertical bracket (24) is mounted. 5. Electromagnetic relay according to claim 4, characterized in that the rotating armature (45) has a frame-like shape, which is cranked in the horizontal near the pivot point. 6. Electromagnetic Relay according to claim 1, characterized in that the permanent magnet (31) by a Elbow (30) is attached to a bracket (21). 7. Electromagnetic Relay according to Claim 1 or the following, characterized in that the excitation coil (35) lies horizontally and parallel to the base plate (15) of the electromagnetic system is arranged. B. Electromagnetic relay according to Claim 7, characterized in that that a rotating armature (45) actuated contact arrangement between the excitation coil (35) and the base plate (15) is provided. 9. Electromagnetic relay after Claim 8, characterized in that the bearing of the rotating armature (45) is approximately located in the middle under the excitation coil (35). 10. Electromagnetic relay according to claim 1 or following, characterized in that the opening of the winding core the excitation coil (35) for receiving the T-shaped components (42) at right angles, is preferably square. 11. Electromagnetic relay according to claim 1 or the following, characterized in that the frame-shaped rotating anchor (45) an actuator (53) attached to both longitudinal parts of the frame for Actuation of the contact arrangement is assigned, with electrical isolation the rotating armature (45) from the contact arrangement at the end of the actuating members (53) a glass ball (55) is used for insulation. 12. Electromagnetic relay after Claim 11, characterized in that the actuators (53) are attached to the side of the rotating armature (45) assigned to the base plate (15). 13. Electromagnetic relay according to claim 12, characterized in that on the base plate (15) has a cap (18) for mechanical protection of the sheet metal magnet system can be attached, Publications under consideration: German Patent No. 96'7,503; German interpretation document No. 1138162.