DE1020735B - Highly sensitive electromagnetic relay - Google Patents

Description

GERMAN

The invention relates to a highly sensitive relay, e.g. B. telegraph relay, with changeover contact, of the the movable contact member occupies a central position between the two fixed contact members. At a known arrangement of this type, the contact members form parts of the magnetic circuit, in particular the fixed contacts of the changeover contact at the same time the magnetic cores of two pot cores. The fixed contact members are with the movable, designed as an armature contact member by yokes made of magnetic Material connected, but are electrically isolated from the contact members. The point of contact between the pot cores lies in a vacuum chamber. However, these known relays are in their It is expensive to manufacture because, in particular, it is not possible to separate the electrical and magnetic circuits is without the magnetic circuit having stretches of magnetic resistance. In addition, through the Using two ring-shaped permanent magnets the arrangement made so that the movable contact member remains in the position last assumed when the current in the work coils is switched off is. Furthermore, an application of this known relay is not possible in many cases because it can only be provided with a single changeover contact.

The purpose of the invention is to avoid these disadvantages and to reduce the cost of individual parts in relation to the number of contacts for relays of this type to a minimum. According to the invention, this is achieved in that a magnetic circuit of a predetermined direction is continuously closed via the movable contact member and one of the fixed contact members and that this magnetic circuit is superimposed on this magnetic circuit by a further magnetic flux generated by at least one work coil via the other fixed contact member in such a way that reversing the direction of the magnetic flux in the movable contact member, this is attracted by the other fixed contact member, and that after the additional magnetic flux has ceased, the movable contact member is switched back to its rest position caused by the permanent magnetic flux. According to a further embodiment of the invention, several housings carrying the contact members of a changeover contact are assembled according to the modular principle. The magnetic coils and the work coils are each provided jointly for several contact elements of the same type. According to a further embodiment of the invention, the individual contact points are designed in such a way that a magnetic resistance (air gap) is present when electrical contact is made. In order to avoid switching sparks that occur, it is expedient for the housing carrying the contact point to be evacuated and with highly sensitive items
electromagnetic relay

Applicant:
International

Standard Electric Corporation,
New York, NY (V. St. A.)

Representative: Dipl.-Ing. H. Ciaessen, patent attorney,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Stanley H. Towner and Walter M. Sweetenham,

Aldwych, London (Great Britain),

have been named as inventors

Nitrogen, a noble gas, a reducing gas or a gas mixture.

The invention will now be described in more detail below with reference to some of the exemplary embodiments shown in FIGS. It shows
1 shows the perspective view of a contact unit,

FIG. 2 shows the individual parts of the contact unit shown in FIG. 1,

3 shows the use of two such contact units in a relay,

4 shows another embodiment of a relay with two contact units,

Fig. 5 schematically shows the magnetic structure of the relay shown in Fig. 3,

6 and 7 schematically show the magnetic structure of the relay shown in FIG. Working position of the movable contact member,

Fig. 8 is a sectional view of a further form of relay,

9 and 10 schematically the magnetic structure of the relay shown in FIG. 8 with only one the permanent magnetic flux generating magnetic coil or additionally with the work coil and

Figures 11 and 12 are front and side views of another form of relay.

The contact unit shown in Fig. 1 and 2 consists of the three contact members 1, 2, 3 and housing 4 made of glass or other insulating material. The components made of magnetically conductive material

709 809/274

3 4

The I ₁ 2, 3 are shown in the figures as round wires, usually at one or the other end of the two, but can also easily have a flat shape, or in some cases even have contact members. The housing can come into contact with the contact-making end in one piece. In the method described, placed or composed of two parts, as in FIG. 2, an arrangement is therefore made which, after the contact elements 1, 2, 35 have been inserted, are glued to one another regardless of the mechanical position of the cones will. With the help of a tubular clock spring, all contact units of the relay are. This little 6 is the interior of the housing, in which the contact springs are located due to the magnetic force, first evacuated the coil once attracted by one pole and then, before it is closed, referred to below as the rest position , and the other nitrogen or a noble gas or a reduced io time from the other pole, hereinafter referred to as a working gas, such as hydrogen or carbon monoxide, or a gas mixture. By energizing the coils 7 and 8 are on

The contact members 1 and 2 lie with their inner ends of the contact members 1, 2 at a north end axially to one another and are formed in the interior of the pole and a south pole, and by exciting the housing 4 through a small air gap from one another 15 forms a polarizing coil 9 at the ends of the separated. In this air gap, a contact spring 5 protrudes freely from a north or south pole. Depending on the leaf spring 5 attached to the contact member 3 from this polarity, the contact spring is inserted by the magnetic material. It is entirely possible- North Pole or attracted to the South Pole. Hch, to give the housing 4 other shapes or it. A constant magnetic flux, the direction of which does not change, is produced by the coil 9 in a different manufacturing favorable manner. For example, it can be divided horizontally. The switchover of the contact from the rest position instead of the vertical division shown, or it into the working position is achieved by reversing the current in the can from two or more identical different coils 7 and 8. Parts to be composed. Instead of the coil 9, a permanent magnet can also be used

The relay shown in Fig. 3 consists of two 25 are used. In the case of relays, according to the principle

Changeover contacts that work on the polarizing magnetic bridge shown in FIG. 1 is it

Contact unit. The two housings 4 usual to permanently polarize the fixed poles. These

and 4 'are with their broad sides facing each other. Polarity is constant for actuating the armature

and have a common external magnet - vice versa. In the proposed arrangement, at

circle. The coils 7, 8, 9 are each over the two 30 which do not have the pre-magnetization of the fixed poles,

protruding ends of the contact member 1 and 1 ', a better sensitivity is achieved.

2 and 2 ', 3 and 3' arranged. The outer magnet- Another mode of action is supposed to be on. Hand of

The circle is closed by the yokes 10 and 11. Figs. 6 and 7 will be described in more detail. She corresponds

One end 12 of the yoke 10 is bent and corresponds to the arrangement of the relay shown in FIG. Included

protrudes into the coil 7 and is through the insulating 35 Fig. 6 represents the so-called rest state and FIG

plate 13 isolated from the contact members 1 and 1 '. the so-called working state. In order to

This insulating plate 13, however, forms a low clock spring 5 to keep the coil at rest

Magnetic resistance between the yoke 10 and 16 excited, which leads to the premagnetization or polarization

the links 1 and 1 '. The other end 14 of the yoke is used. This will result in the left half of the

10 protrudes in the same way into the coil 9 and is 40 iron circle a magnetic flux, for example in the arrow against the contact members 3 and 3 'electrically isolated direction is generated. L ^T m the contact spring 5, the armature through the plate 15. In the same way, the yoke of the system protrudes to bring it into its working position,

11 with its ends into the coils 8 and 9 and the coils 17 and 18 are additionally excited. By also electrically isolated from the contact members. the first creates a magnetic field similar to that of the

The relay shown in Fig. 4 also has 45 Spulel6 counteracts and weakens this so far, two of the contact units shown in Fig. 1, which that the contact springs by the coil 18 arranged in relation to each other as in the relay of Fig. 3 in the right half of the iron circle. The coil arrangement, however, is such that flux is attracted to the contact member 2. The fact that two coils 16 and 17 are arranged over the contact link corresponding dimensioning of the coils 17 and 18 to the 1, 1 ', while the third coil 50 can operate this relay surrounding the various 18 links 2 and 2' . The magnetic operating conditions are adapted. A further relay arrangement with only two coils, which connects the contact elements 3, 3 'with the GHe, is shown in FIG. 8. Here, the magnetic countries 1, 1 'on the one hand and 2, 2' on the other hand, magnetically connect a circuit between the contact members 1 and 3 and electrically isolate the contact unit 4 via the yoke 25 and between them with the help of the insulating plates 21 to 24. This insulating plate contact members 2 and 3 closed via the yoke 26, forms only a small magnetic resistance. The two yokes 25 and 26 are electrically insulated from the contact-a relay can, in addition to the members 1, 2, 3 shown in the figure, by means of the plates 29, 30, 31, 32, two changeover contacts with further such contacts. These plates only form a switching cycle. 60 wrestle magnetic resistance between the

The operation of the relay of Fig. 3 is now different contact members and the yokes.

on the basis of the schematically shown in Fig. 5 The magnetizing coil 27 encloses the outer,

Magnetic circuit of one of the multiple existing um- free end of the contact member.-. 1 and one end

switch contacts explained in more detail. of the yoke 25. The work coil 28, however, encloses

When the relay is in the idle state, the contact unit 4 is 65. The mode of operation is in the

Clock spring 5 in the middle position between the free FIGS. 9 and 10 illustrated. When the relay

Ends of the two contact members 1 and 2. This is in its normal or rest position is just that

Maintaining an ideal position is particularly excited in the case of a polarizing coil 27. The one thus formed

Mass production difficult. The result is that the magnetic flux is shown in FIG. A minor

In practice, therefore, the contact spring 5 is also formed over the right half 26 of the path

Iron circle. However, the magnetic resistance of this path is relatively high due to the many Air gap. Since the magnetic flux via the yoke 25 is thus greater, the contact spring 5 is removed from the contact member 1 tightened.

A magnetic flux is generated by the coil 28 which is in the same direction as the flux flowing from the Coil 27 is formed, has. Since the contact spring 5 is now arranged within the coil 28, can the flux generated in the pole piece does not enter the contact spring 5, but runs over the pole piece 26. In addition, the one generated by the coil 28 runs Flow only in the right half of the iron circle, so that in this part of the iron circle there is a Reinforcement occurs, through which the contact spring 5 is attracted by the contact member 2 and that Relay is switched on in its working position. With the disconnection of the current in the coil 28 are again the magnetic conditions shown in Fig. 9 and the contact springs in the so-called Brought to rest, d. H. it is attracted to the contact member 1.

In the case of the relays shown in FIGS. 11 and 12, the contact elements 1, 2, 3 and the contact spring 5 are accommodated in a glass bulb 33. The contact members are passed through the base plate 34. The contact members 1 to 3 are externally magnetically coupled to one another by an E-shaped yoke 35 which, however, electrically separates them from one another in the manner described above. As FIG. 12 shows, a yoke 35 is provided for each two contact units 1, 2, 3 and 1 ', 2', 3 '. The coil 36, 37, 38, which each enclose the contact members 1 and 1 ', 2 and 2', 3 and 3 ', results in a mode of operation of the relay which corresponds to that shown in FIG. Such a contact unit with a glass bulb can, however, also be used for a relay, the structure of which corresponds to the relay shown in FIG.

For such relays to work well, it is advantageous to maintain a small air gap between the contact spring 5 and the poles of the contact elements 1 and 2 during the contacts, for example with the help of a plate made of non-metallic material, as is known as a so-called adhesive sheet in electromagnets. While two contact units per relay were provided in the examples described, it is entirely conceivable to use only one contact unit or even more than two units. In addition, various switching combinations suitable for the use of the relay are also possible with the contact elements 1, 2, 3. Instead of the magnetizing coil, the magnetic field of which brings the contact spring into its so-called rest position, a permanent magnet, in particular with a high coercive force, can be used in all of the relay arrangements described.

Claims (11)

Claims: 60 1. Highly sensitive electromagnetic relay with changeover contact, of which the moving Contact member occupies a central position between the two fixed contact members, in particular Telegraph relay, the contact elements of which form part of the magnetic circuit and the fixed contact elements of which outside the housing enclosing the contact point by at least one yoke are magnetically connected to the movable contact member, characterized in that over the movable contact member (3, 5) and one of the fixed contact members (z. B. 1) a magnetic circuit predetermined direction is constantly closed and that this magnetic circuit is another, of at least one work coil (z. B. 28, Fig. 8) generated magnetic flux across the other fixed contact member (z. B. 2) is superimposed in such a way that reversing the direction of the magnetic flux in the movable contact member (3, 5) this attracted by the other fixed contact member (z. B. 2) becomes, and that after the additional magnetic flux has ceased to exist, the movable contact member (5) switched back to its rest position caused by the constant magnetic flux will. 2. Highly sensitive relay according to claim 1, characterized in that the constant magnetic flux is generated by a solenoid (e.g. 9 in Fig. 5). 3. Highly sensitive relay according to claim 1, characterized in that the constant magnetic flux is generated by a permanent magnet. 4. Highly sensitive relay according to claim 1 to 3, characterized in that a plurality of the Contact elements (1, 2, 3) of a changeover contact carrying housing according to the modular principle are assembled and that the magnetic coil (e.g. 9 in Fig. 5) and the work coils (e.g. 8, 7 5j is provided jointly in each case for a plurality of contact members of the same type (e.g. 1, 1 'in FIG. 3) are. 5. Highly sensitive relay according to claim 1 to 4, characterized in that the yokes (z. B. 10 and 11 in Fig. 3) of the contact members (1, 2, 3) each by a plate (z. B. 13 and 15 in Fig. 3) are electrically isolated, but their magnetic resistance is lower. 6. Highly sensitive relay according to claim 1 to 5, characterized in that the contact points are designed so that a residual magnetic resistance when electrical contact is made remains. 7. Highly sensitive relay according to claim 6, characterized in that at the contact points the movable contact member (5) and / or on the fixed contact members (1, 2) partition plates are arranged from non-magnetic material. 8. Highly sensitive relay according to claim 1 to 7, characterized in that the housing (4) is designed as glass tubes (Fig. 11 and 12j. 9. Highly sensitive relay according to claim 1 to 7, characterized in that the housing (4) is made of ceramic or another insulating material. 10. Highly sensitive relay according to claim 8 and 9, characterized in that the housing (4) is evacuated. 11. Highly sensitive relay according to claim and 9, characterized in that the housing (4) with nitrogen or a noble gas or a reducing gas or a gas mixture is filled. 1 sheet of drawings © 709 8CS / 274 12.