DE1198454B - Thermowell armature contact relay with static or static characteristics - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

Number:
File number;
Registration date:
Display day:

HOIh

German class: 21g -4/01

1198 454
J21917VIIIC / 21]
June 9, 1962
August 12, 1965

The invention relates to a protective tube armature contact relay with idle or stick characteristics through use a permanent magnet arranged in a stationary manner within the relay.

There are thermowell armature contact relays known which are equipped with a permanent magnet and depending on The strength of the magnetization of the permanent magnet will work as a rest or latching relay. With these well-known Arrangements, the protective tube contacts and the permanent magnet are arranged within the excitation coil and are enclosed by it. The contact spring ends protruding from the protective tubes are caused by running outside the field winding magnetizable reflux clamp magnetically connected. However, these known relays show their actuation has the disadvantage that the whole of the lying parallel to the protective tube contacts Flux generated by permanent magnets must be displaced when the switching state of the contacts changes, so that this results in high response currents of the relay. In addition, the response currents are at this relay is dependent on permanent magnets already set to a certain magnetization strength the distance between the permanent magnet and the contact tongues of the protective tube contacts. This makes itself especially noticeable if more than one protective tube contact is provided within the relay and as a result, several protective tube contacts are in the area of influence of a permanent magnet. Conditional The distance between the individual Protective tube contact tongues for the protective tube outer shell sway a little. However, this fluctuation within the distance must be caused by an increase in the strength of the magnetization of the permanent magnet, since the permanent magnet is independent of the distance to the individual contact tongues must in any case be so strong that it ζ. B. with a latching relay also the contact tongues of a protective tube contact located a little further away in the tightened state must hold securely or must close the protective tube armature contacts securely in the case of a rest relay. Through this result in turn for the change in the permanent magnetic field by the magnetic field of the Coil increased pull-in currents.

It is also known for protective tube armature contact relays to couple the protective tube contacts themselves through a corresponding design of the magnetic feedback on the circumference of the protective tube and to construct this coupling in such a way that the protective tube armature contacts arranged within a coil are mechanically held at the same time
Adhesive characteristics

Applicant:

International Standard Electric Corporation,

New York, N.Y. (V. St. A.)

Representative:

Dipl.-Ing. H. Ciaessen, patent attorney,

Stuttgart 1, Rotebühlstr. 70

Named as inventor:

Andre Jean Henquet,

Fernand Silerme, Boulogne-Billancourt, Seine

(France)

Claimed priority:

France of June 14, 1961 (864 957)

will. This z. B. from the German patent 964703 known type of fastening has the disadvantage that the protective tube anchor contacts only are partly held on the circumference of the protective tube, which does not result in a secure mounting.

A relay with protective tube armature contacts is also known in which the protective tube armature contacts as a common flux section of two magnetic circuits connected to one another by flux guide yokes are formed, one by a permanent magnet and the other by a polarity reversible Electromagnet is excited. However, this design has the disadvantage that the drop in the armature contacts is not guaranteed.

The invention has the task of eliminating the disadvantages of the arrangements in known protective tube armature contact relays to avoid. According to the invention this is achieved in that the permanent magnet by a highly permeable flux path magnetically separated from the other flux guide elements of both magnetic circuits is bridged.

Through this training there is the main advantage that a greater waste security for the Armature contacts is reached.

According to one embodiment of the invention, a coil is wound on the core, through which the magnetic

509 630/280

guiding the core through application accordingly short electrical impulses to the winding of the coil can be converted at will. The flux generated in the yokes by the permanent magnet is generated by applying a corresponding electrical Pulse to the winding of the coil within the yokes 8 and canceled by a corresponding Counterflow is displaced so that the protective tube armature contacts respond.

According to one embodiment of the invention, there is one Yoke half designed so that both protective tube armature contacts in the relay through sleeves a certain distance from each other and from the one resting on the yokes, these at the level of the Contact air gap bridging permanent magnet are held.

According to a further embodiment, the permanent magnet, the two protective tube contacts and the two Yoke parts by z. B. gluing firmly connected, so that for a certain magnetization strength of the permanent magnet, the specified distance between it and the two protective tube anchor contacts preserved.

According to a further embodiment of the invention, the second magnetic circuit with the Sheathing forming permanent magnets as a shield, as a reflux bar and as a through the Permanent magnet pre-magnetized in a certain direction Flow sheet used.

According to a further embodiment of the invention, the two magnetic circuits are within the Relays stacked on top of each other and magnetically and electrically separated from each other by insulating pieces and / or air gaps separated.

The invention is described with reference to a drawing. In the drawing shows

F i g. 1 is a side view of the individual parts within the relay in the position in which they will later be assembled Relays are arranged,

Fig. 2 is a perspective view of a Yoke half,

F i g. 3 is a side view of the FIG. 1 and 2 illustrated components,

Fig. 4 is a side view of the fully assembled Relay,

Fig. 5 is a view of the underside of the relay according to F i g. 4 and

6 shows a relay according to FIGS. 4 and 5 with sight on the connection ends of the arranged inside the relay Protection tube contacts.

In Fig. 1, 1 denotes a protective tube contact whose two contact tongues % and 3 are melted into a Schulz tube 4 in a known manner. The length of the protective tube contact is approximately 80 mm. In the relay according to the invention two such protective tube contacts are arranged. In the representation according to the Fig.! but only one contact can be seen.

A permanent magnet 5 is oxidized on one side of these protective tube contacts 1. This permanent magnet must have a relatively high coercive force so that its magnetic field strength remains approximately constant during the actuation of the relay. This is achieved, for example, by an alloy that contains 8 to 35% titanium, t5 to 30% cobalt, 10 to 25% nickel and approximately 5% aluminum. A magnet made from this alloy has a magnetic field strength of 800, Oersted and ^; a magnetic induction of 10,000 Gauss. The length of the magnet 5 is 25 mm and its cross section is 20 mm ² , so that this magnet has a coercive field of 2000 Oersted and a remanent. magnetiselien soot of about 2000 Maxweil. Other known alloy contains e.g. B. about 6% titanium, 12% cobalt, 15 to 30% nickel and 8 to 10% aluminum. The rest is iron. A magnet of the same size

ίο made from this alloy creates a magnetic field strength of 500 Oersted and a magnetic induction of about 7000 Gauss.

On the other side of the two protective tube contacts 1, a core 6 is arranged on the one Magnetizing winding is applied. The core 6 is made of a material that is magnetically reversible is and that is a high permeability, but one has small coercive force and its hysteresis loop runs approximately rectangular. The material of the core 6 has a high content of chromium and Coal, the silicon after a reasonable

■ Heat treatment is added. This alloy can have a magnetic field strength of 70 to 80 oersteds and a magnetic induction of 9500 gauss. The length of the core 6 is about 62 mm, the cross section is 28 mm ² , so that the core 6 has a magnetic field strength of 460 Oersted and a magnetic flux of 2600 Maxwell

..." having.

The three parts of the magnetic circuit mentioned so far are magnetically coupled by two yokes 8. A yoke 8 itself is shown in FIG. 2 shown in perspective. The design of the magnetic circuit of the relay including the two yokes 8 is shown in FIG. The yoke 8 is formed from a sheet metal whose middle part or jacket 9 encloses the core 6 protruding on each side of the coil 7 and the ends of which are rolled outward so that two sleeves 1 © result, one part of each , namely less than half, of the two protective tube contacts 1 are included. Web 11 remain between the casing 9 and the two sleeves 10. The shape of the yoke 8 itself is created by rolling or bending sheet metal made of permeable magnetic material which, for. B. has the properties of deep-drawn sheet metal. The yoke 8 is electrically isolated from the contact tongues 2 of the protective tube armature contact 1 by the protective tube 4. The sleeves 10 are drawn longer than the casing 9 in order to obtain a more favorable magnetic coupling or a more favorable magnetic transition between the sleeves 10 and the contact tongues 2 . When the two yokes 8 are plugged onto the respective ends of the core 6 protruding from the coil 7 on both sides, these two holes S each form the pole pieces of the iron circuit of the relay arrangement; they are therefore arranged at the level of the air gap between the two contact tongues 2 and 3 of the protective tube contact 1 at a certain distance from one another. As already described, the core 6 and the magnet 5 have a high coercive force and a large remanent flux, which ensures that the relay works properly. The magnet 5 is approximately at the level of the air gap between the two contact tongues 2 and 3 of the protective contact 1 and is in the assembled state of the arrangement on the

two sleeves 16 of the two yokes S, this above-mentioned impulse, is determined * This flow in the bridging, on. The magnetic yoke for the core 6 now runs parallel in the direction of the flux, sen circle is formed by the outer shielding generated by the permanent magnet - S ',

cap 12 (see Figs. 4 to 6). Due to the series connection between magnet 5 and

The shielding cap or sheathing 12 is designed so that the flux runs over the two yokes 8 so that it surrounds the order generated by the permanent magnet 5 around the yokes 8 shown in FIG. The magnetic yoke 12 caused by the applied pulse within the coil 6 of the relay is guided along the coil 7 and runs in opposite directions in the yokes 8; so that the inner in the direction of the protective tube armature contacts 1 in half of the yokes 8 through the permanent magnet 5 produced two sheathing parts 14, between which a magnetic flux is displaced. Is provided on the contact recess 15 in the middle of the contact point of the protective air gap within the protective tube 1 between the tube contact 1. The projections 16 contact tongues 2 and 3 have the effect that on the underside of the magnetic yoke the magnetic flux within the contact tongues 2 12 (FIG Direction 14 are freely cut and flows on both sides of 15 so that the contact tongues 2 and '3 of the protective recess 15 are located, the outer shape of the pipe anchor contacts are mutually attracted and the magnet 5 is adapted and lie on the ends as a result of the or the contacts close. Supports the magnet 5 on. By inserting the permanent magnetization of the contacts between these two lugs 16 is the approximation of the casing 12, since this with the iron circle, which consists of the two casing parts. their parts 16 at the ends or at the poles of the 14 and the upper part 13 surrounding the coil 7 permanent magnets 5 and thereby a certain amount of magnetic yoke is closed. Pre-excitation of the external magnetic circuit In terms of effect, the core 6 is given in this magnetic circuit (casing 12). The contact tongues 2 included. As seen from Fig. Emerges 6 ·, and 3 of the two Sehutzrohrkontakte 1 remain the yoke members 9 and 10 are closed the yoke 8 in a "5 after completion of the pick-up pulse, specific distance from the parts 14 of the magnetically set the closed state of Contact tongues surrounding 2 table yoke 12, so that the two and 3 are canceled, this is done by nested or side by side applying an ejection pulse to the coil 7, the ordered iron circles, once the one from the core 6, is opposite to the direction the tightening of the two yokes 8 and the protective tube contact 1 30 impulses. As a result, the direction of magnetization of the existing iron circle, on the other hand the iron circle, is changed again within the core and which is formed by the permanent magnet and the sheathing again in series with the magnetization line of the 12, does not cancel each other out by short permanent magnets 5 by canceling the flux , but at the corresponding displacement within the yokes 8, so that the flux generated by placing a larger air gap between these two 35 magnet 5 is provided practically over these iron circles. This magnetic series magnetic circuit is short-circuited and the residual flux (leakage flux) remaining in the air gap between the parts 14 of the sheathing contact tongues 2 and 3 of the protective tube anchoring 12 and the yokes 8 on both sides of the isocontact is not provided (FIG. 5) which at the same time is more sufficient to keep the protective tube armature contact geelectric connection lugs closed for both the protective 4 °.

tube contact ends as well as for the winding connections as soon as protective tube contacts within a relay of the coils included. The effectiveness of the magneti- has been associated with a permanent magnet see shielding along with effectiveness, so that there is a quiescent or latching relay, depending of the magnetic circuit is ensured through the opening 15 according to the magnetization strength of the permanent magnet. 45, go with the pull-in values of these relays

By superimposing the tolerances within the relay within the protective tube contact production arranged magnetic circles result for a, as z. B. if not melted in the middle Actuation of the relay two electromagnetically flat contact tongues within a protective tube that can be influenced Switching states and two by the clock the distance from the permanent magnet to the permanent magnet 5 within the relay arrangement can sometimes differ greatly and seriously influenced switching states. If one leaves the electrical to essential differences in the suit and tromagnetic influence of the relay apart from load drop values of these relays leads. This results in Tracht, the magnetic flux in the core 6 runs in a position dependency of the individual protective tube conversely Direction as the magnetic flux in step with the position of the permanent magnet, which is still gneten 5 (F i g. 1 and 3), since the magnet 5 and the 55 due to manufacturing tolerances occurring within the Core 6 can be enlarged magnetically in series structure of the relay via the two yokes 8. Around are switched. If you look at this completely to avoid this, a structural unit is made up assembled relays, this is how the sheathing of protective tube contacts and permanent magnet works 12 for this just mentioned circle as magnetic possibly still from the yokes 8, prefabricated, d. H. Shunt resistance, so that only a very small flow 60 through adhesive film or through casting resin with each other through the protective tube contact tongues 2 and 3 flows connected, so that the specified distance between and these stay open. If an electrical impulse corresponding to the permanent magnet 5 and the two protection is applied to the coil 7, then pipe anchor contacts 1 is also after or during the the direction of magnetization of the core 6 is reversed. Installation in the relay arrangement is retained. But if the pulse is too short, it can be too high or too low Relay does not respond. With longer pulse duration, drop or tightening values that flow through production through the core 6 a flow in the direction, moderate spreads in the assembly of the relay after energizing the coil 7 by the previously dingt avoided.

Claims (7)

Patent claims: 1. Protection tube armature contact relay with static or static characteristic, its armature contact set as a common flow section of two magnetic circuits connected to one another by, 5 Flußleitjoehe is formed, one by a permanent magnet and the other by a polarity reversible Electromagnet is excited, thereby .marked that the permanent magnet (5) iq by a highly permeable one magnetically separated from the other flux guide elements of both magnetic circuits Flußweg (12) is bridged. 2. Protection tube armature contact relay according to claim 1, characterized in that on the Core (6) a coil (7) is wound through which the direction of magnetization of the core (6) through Applying correspondingly short electrical impulses to the winding of the coil (7) converted as required can be. 3. protection tube armature contact relay according to claim 1 to 2, characterized in that the in the yokes (8) of the permanent magnet (5) generated by applying a corresponding flux electrical impulse to the winding of the coil (7) within the yokes (8) and through a corresponding counterflow is displaced, so that the protective tube contacts (1) respond. 4. Protection tube armature contact relay according to spoke 1 to 3, characterized in that each a yoke half (8) is designed so that both protective tube armature contacts through sleeves (10) inside the relay (1) at a certain distance from one another and from the one resting on the yokes (8), these at the level of the contact air gap the permanent magnet (5) bridging the protective tube armature contacts (1). 5. protection tube armature contact relay according to claim 1 to 4, characterized in that the Permanent magnet (S) the two armature contacts (1) and. the two yoke parts (8) through e.g. gluing to form an interchangeable unit, so that for a certain magnetization strength of the permanent magnet (S) the specified distance is maintained between this and the two protective tube anchor contacts (1). 6. protection tube armature contact relay according to claim 1 to 5, characterized in that the the second magnetic circuit with the permanent magnet (S) forming sheathing (12) as a shield, as a reflux bow (flux from coil 7) and as one through the permanent magnet (5) in one certain direction pre-magnetized flux sheet is used. 7. protection tube armature contact relay according to claim 1 to 6, characterized in that the two magnetic circuits are stored one above the other within the relay arrangement and through Insulating pieces (e.g. 17) and / or air gaps (e.g. 15) magnetically and electrically separated from one another are. Considered publications:
The Bell System Techn. Journ. 1960, pp. 1 to 30. 1 sheet of drawings 509 630/280 8.65 © Bundesdruckerei Berlin