DE1135578B - Polarized protective tube contact relay - Google Patents

Description

The invention relates to a polarized protective tube contact relay, the contacts of which located inside a closed glass tube. Those facing each other at a small distance Contact springs are made of ferromagnetic material and pull themselves under the action of a Magnetic field, which is generated by an excitation coil sitting on the glass tube.

To be able to convert such an operating current relay into a closed current relay, or that To strengthen or weaken the field generated by the excitation coils, one has to do with the protective tube In addition to the excitation winding, additional permanent magnets are provided. With a known protective tube changeover contact includes a U-shaped or tubular permanent magnet, the contact system in the area of the contact lugs, so that its field Working air gap essentially transversely to the contact springs in the area caused by the movement of the changeover contact spring defined level interspersed. Above or next to this permanent magnet are one or two Arranged excitation coils, which provide the necessary excitation to actuate the contact.

Such a construction has shortcomings both mechanically and electrically. So it causes difficulties, the permanent magnet body and the excitation coils, which have a relatively high Have weight to attach to the delicate glass tube. Apart from the difficult one Assembly, the dimensions of the protective tube contact relay are proportionate through this training great. In switch cabinets, where a large number of such relays are arranged, makes this deficiency is particularly noticeable. Due to the presence of several air gaps between the excitation coil and the contact system, which is penetrated by the magnetic field, results in a relatively high resistance of the magnetic circuit, to overcome it a high number of ampere-turns is required.

According to the present invention, these shortcomings are eliminated in that the radial or axially magnetized permanent magnet is simultaneously designed as a bobbin and as a carrier of the Excitation winding is used. As a result of this measure, a separate excitation coil is no longer required at all. The excitation winding is applied directly to the permanent magnet, which is designed as a coil body wrapped. This means that there are special fasteners that were previously used to hold the excitation coil and of the permanent magnet on the glass tube were required. Trained as a bobbin

Applicant:

Max Baermann,
Bensberg-Wulfshof (District Cologne)

Max Baermann, Bensberg-Wulfshof (Cologne district),
has been named as the inventor

The permanent magnet is in direct contact with the protective tube on all sides, without any air spaces are. The magnetic field is generated in the immediate vicinity of the working air gap, so that next to In a particularly space-saving design, the magnetic resistances are also small. It will therefore only a low magnetization field strength and thus a low number of ampere turns to operate the Contacts needed. The relay produced according to the invention therefore work very economically because you Power consumption is low.

The permanent magnet coil body is expediently made of a mixture formed from a powdery one permanent magnetic material and a solidifying binder, preferably a thermoplastic Plastic, and is made by one of the known compression or injection molding processes. as Permanently magnetic material, a material is preferably used which has a low permeability and has a high coercive force.

An advantageous further development consists in having several within the permanent magnetic coil body To arrange protective tube contacts, one or more of which at least on a quarter of its circumference are surrounded by magnetized, permanently magnetic material. This way work within a Relay several protective tube contacts as normally closed contacts, while the remaining protective tube contacts that are connected to the Surfaces that are not magnetized continue to act as working contacts. However, will be a or several inner sides of the permanent magnet coil body facing the protective tube contacts magnetized in the opposite direction, so remain in a certain direction of the coil current im same relay one or more contacts closed because the field generated in the coil the

209 635/302

If a field of the same size is generated, the contact connection is separated by the resilient one Effect of the contact springs.

A plurality of protective tube contacts can also be arranged within the permanent magnetic coil former 5 will. Thus, FIGS. 2 and 3 show a protective tube contact relay with four protective tube contacts 7, 8, 9 and 10 arranged inside the bobbin 4.

In this embodiment, the sides of the permanent magnet facing the four protective tube contacts Coil body alternately magnetized in opposite directions. As from Fig. 2 it can be seen, has the protective tube contact 7 to

has the same direction as the permanent magnetic field assigned to the contacts, while the others Contacts whose assigned magnetic field is opposite to the field generated by the excitation coil, to open. The permanent magnet bobbins are axially magnetized. The strength of the bias and the responsiveness that can be achieved with it can be easily adjusted by turning the individual protective tube contacts adjustable. For this reason, the protective tube contacts are within them surrounding permanent magnet coil body arranged rotatably.

In a further embodiment of the invention
The permanent magnet body can consist of a rubber-like flexible material known per se, with an ordered inside of the coil body on the left embedded, powdery permanent magnet material side and on the right a south of low permeability, which is on the pole, while the protective tube contact 9 is attached -Protection tube is pulled up. Due to its elastic arranged inside of the coil, it has a south pole on the left and the properties of the permanent magnet body have a north pole on the right. Now the excitation can be identified on the protective tube contact. The permanent coil is connected to a direct current source in such a way, the magnetic body is tubular here, so that the excitation field on the left side of the coil and can preferably with pole pieces and a north pole // 'and on the right side of the soft magnetic, a space for the recording Coil generates a south pole S ' , the result is the circuit positions of the protective bodies shown in FIGS. 2 and 3, which include the exciter winding. In this case, it recommends 25 tube contacts. The contacts of the protective tube 7 are designed to radially magnetize the permanent magnet body. closed because the field caused by the permanent magnetic By such a design you get special coil body the same Richders sensitive protective tube contact relay. has processing, as the electromagnetically generated

Using the field shown in the drawing, so that a summation and thus an example of seduction If the invention occurs subsequently, there will be increased attraction of the contacts. On the contrary. It shows that the contacts of the protective tube 9 are open,

Fig. 1 is a longitudinal section of the protective tube contact because the two fields opposite direction Relay, exhibit and focus on their magnetic action

Fig. 2 cancel a longitudinal section with four within on the contact springs 1 and 2. Will the of the permanent magnet coil body arranged 35 current direction of the coil current reversed, see above Protective tube contacts according to the line I-I of Fig. 3, open the contacts of the protective tubes 7 and 10,

FIG. 3 shows a section along the line II-II in FIG Side view with four protective tube contacts,

4 shows a part of the permanent magnet coil body in a perspective view,

5 shows a device for magnetizing the permanently magnetic coil body,

6 shows a protective tube contact with a tubular permanent magnet body drawn on,

7 shows a protective tube contact relay with a tubular permanent magnet body, pole pieces and Inference body.

The protective tube contact relay according to FIG. 1 consists of the two contact springs 1 and 2, which of a glass body 3 are enclosed. Immediately above the glass body is the permanent magnet Coil body 4 arranged, which consists of a mixture of a powdery permanent magnetic

Material with a solidifying binder, 55 end flange 12 a south pole. The spool end flanges such as a thermoplastic 11 and 12 can be made of the same material as

while the contacts of the protective tubes 8 and 9 close. If the excitation current is switched off, so all protective tube contacts remain closed.

Of course, there is also the possibility of only one or two facing the protective tubes To magnetize the inner surfaces of the bobbin so that these contacts work as normally closed contacts, while the other, not pre-magnetized, act as working contacts. As can be seen from Fig. 3, the protective tube contacts are rotatably arranged within the permanent magnet coil body to to be able to set the desired sensitivity in a simple manner.

In Fig. 4 a part of the bobbin of Figs. 2 and 3 is shown in perspective. Like from this figure can be seen, is located in the area of one end flange 11 of the permanent magnet coil body 4 a north pole and. in the realm of the other

substance, consists. The field winding 5 is applied to the bobbin 4. The bobbin is in magnetized in the axial direction, so that there is a north pole on one side and a north pole on the other South Pole is located. As a result of the magnetic field generated by the permanent magnet coil body the contact springs 1 and 2 attract each other and touch at the contact point 6, so that

consist of the coil body 4, but they can also be made of a non-permanent magnetic material be.

FIG. 5 shows a device for magnetizing the permanently magnetic coil body according to FIG. 3 shown. Inside the body, under the magnetization poles 13 and 14, there is the magnetization winding, those with the connecting lines 15

an electrically conductive 65 is connected between the contacts. These lines are connected to a Kon connection consists. capacitor discharge device connected. The coil is energized in such a way that a high current flowing during the capacitor discharge magnetic field, but about current, the coil body is connected to the magnet

sierungspolen 13 and 14 facing parts magnetized. By turning the magnetizing body by 90 ° each desired partial area are magnetized with the predetermined polarity.

In Fig. 6, a protective tube contact is shown, the glass body 3 with a tubular Permanent magnet body 16 is surrounded, which has no coil end flanges. This tubular The permanent magnet body consists of a rubber-like, flexible material with an embedded, powdery material Permanent magnet material of low permeability. As a result of the rubber-elastic properties of the permanent magnet body, it adheres directly to the one surrounding the contacts 1 and 2 Protective tube without the need for special fasteners. It was recognized here that a particularly sensitive protective tube contact relay is obtained when you have this tubular permanent magnet body is provided with pole pieces 17 and 18, as shown in FIG is. The permanent magnet body 16 can be made in one piece, as shown in the lower part of the figure is, as well as of two parts, as can be seen from the upper part of the figure. The river Oder the permanent magnet bodies are preferably magnetized radially.

Immediately on the permanent magnet body, which is provided with pole shoes, is, as in the other exemplary embodiments, the excitation coil 5 is wound. In addition, this protective tube contact has a magnetic return path, which with the help of the Back yoke body 19 is formed.

Claims (8)

PATENT CLAIMS: 35 1. Polarized protective tube contact relay with tubular permanent magnet enclosing the contact, characterized in that the radially or axially magnetized ^ permanent magnet is simultaneously designed as a coil body (4) and serves as a carrier for the excitation winding (5). 2. Polarized protective tube contact relay according to claim 1, characterized in that the Coil body (4) from a mixture, formed from a powdery, permanently magnetic Material and a solidifying binder, preferably a thermoplastic plastic, consists. 3. Polarized protective tube contact relay according to claim 1 and 2, characterized in that Several protective tube contacts are arranged within the permanent magnetic coil former (4), of which, if necessary, each magnetized on at least a quarter of its circumference Material is surrounded. 4. Polarized protective tube contact relay according to claim 1 to 3, characterized in that one or more inner sides of the permanent magnet coil body facing the protective tube contacts are magnetized in the opposite direction so that at a certain Direction of the coil current in the same relay one or more contacts remain closed, while the others open. 5. Polarized protective tube contact relay according to claim 1 to 4, characterized in that the protective tube contacts can be rotated within the surrounding permanent magnet coil body are arranged. 6. Polarized protective tube contact relay with tubular permanent magnet enclosing the contact, characterized in that the radially or axially magnetized permanent magnet (16) from a known, flexible, rubber-like material with powdery embedded therein Permanent magnet material of low permeability at a high coercive field strength exists and immediately on which the contacts enclosing protective tube (3) is firmly adhered. 7. Polarized protective tube contact relay according to claim 6, characterized in that the flexible permanent magnet (16) is tubular. 8. Polarized protective tube contact relay according to claim 6 and 7, characterized in that the one- or two-part elastic permanent magnet (16) via pole shoes (17, 18) a magnetically soft, enclosing a space for accommodating the excitation winding Back yoke body (19) is connected. Considered publications:
German Auslegeschrift No. 1 051 411;
German utility model No. 1 774 923. 1 sheet of drawings © 209 638/302 8.