DE1909940A1 - Electromagnetic changeover relay with protected contact system - Google Patents

Description

Electromagnetic changeover relay with protected contact system The main patent application relates to polarized and non-polarized electromagnetic Changeover relays, in which the coil body and the contacts are constructed appropriately respectively.

Contact connections a separation of the contact space from the winding space and guaranteed by the environment.

The problem underlying the main patent application is To create a relay that has a high level of contact reliability is economical can be produced, has adjustable characteristics and a good degree of efficiency and thus has small dimensions.

The solution to this problem is made after the main patent application achieved that the fixed mating contacts directly at one end of the same time serving as a protective tube bobbin are attached and the contact force before the securing of the adjusting elements can be adjusted from the outside.

The invention provides an advantageous development of this relay achieved, which is achieved by compensating for temperature influences on the excitation voltage, with other setting options for contact force and contact spacing and with special economical manufacturing methods.

Fig. 11 is an embodiment with the ability to compensate for Temperature influences and very precise setting of the relay characteristics.

Fig. 12 is a section F-F 'of Fig. 11 Fig. 13 is a section G-G t of FIG. 11 FIG. 14 is an embodiment with a permanent magnetic circuit closed via a yoke.

FIG. 15 is a section K-K 'of FIG. 16.

Fig. 16 is a section H-H 'of Fig. 15 with a bobbin Koramic magneton magnetized in the direction of the double arrow.

Fig. 17 shows one half of a two-part bobbin.

Fig. 18 shows the other half of a two-part coil body.

Fig; 19 shows the method of manufacturing multiple bobbin halves with embedded pole pieces and connections.

Fig. 20 is a section through the assembled bobbin with contact arrangement located therein.

As is well known, the resistance of a relay coil is the required one Response power of around 0.39% per ° C depending on temperature. A relay that can be used in an ambient temperature range of -65 to +1250 C is used and at 100% Duty cycle has a self-heating of 60 ° C, works with the low-permissible Temperature with twice the excitation power than at the highest permissible temperature.

This inevitably changes the response and fall times in often undesirable way and also the pathogen circuit must these conditions usually. costly be adjusted. It therefore makes sense to create a magnet system that keeps the temperature dependency compensated by the relay coil. This is one by the arrangement according to the invention Ceramic magnets 26, the coercive field strength of which corresponds to the resistance of the coil 32 (Fig. 13) approximately has a corresponding temperature dependence and at least in the air gap area is matched with the magnetic circuit of the coil is achieved. The ones required here As can be seen from FIG. 13, correspondences can be easily fulfilled to the ceramic magnet 26 closes a metallic magnet 31, the field strength of which is in the temperature range changes only insignificantly from -65 to +200 ° C. For example, if the Coercive field strength of the ceramic magnet by 0.5 per Oc and that of the metallic magnet by 0.02% per OC, it is evident that by using a corresponding ratio the lengths of both magnets a suitable force compensation achieved through the influence of heat will. A certain compensation of the permanent magnetic forces acting in the air gap area can also by the dimensioning of the cross-sections Q of the made of ferromagnetic metal contact parts 27, 28 and the ferromagnetic Achieve adjusting screws 29,30 by namely this cross-section at a certain Temperature, e.g. at + 250C, is magnetically saturated. Such a measure is before especially appropriate if the temperature range to be compensated is not very large is and instead of the two magnets 26,31 only one ceramic magnet in one system 13 or two identical ceramic magnets 33a, 33b in a system according to FIG. 14 apply. Here are those made of ferromagnetic material Contact parts-35,36 connected to the end face of the bobbin 37 in a known manner. The ceramic magnets 3Sa, 33b are outside of the bobbin 37 on the outer ones Areas of the contact parts 35,36 and touch the ends of the yoke 34, at its center the contact tongue 2 is butt spot welded and its free end within the Coil body 37 lies between the contact parts 35,36 and thus both contact as well as air gap.

A simple embodiment is shown in FIGS. in which the coil body 38 is a ceramic magnet magnetized in the direction of the double arrow is. Apart from that, the description made for FIG. 14 is also analogous for Fig. 16 is applicable. The contact tongue 39 penetrates the yoke with two noses 40, 41 42, which has two tabs 43, 44, with which the lugs 40, 41 are welded or similar are firmly connected. Bending of the tabs 43,44 in one direction or the other brings about an adjustment and thus an adjustment of the contact tongue in each case opposite direction within the bobbin and especially towards the two contact parts 45,46.

For switching high-frequency currents, contacts with are as small as possible Capacity compared to the open counter contact required. In the exemplary embodiments According to FIGS. 1 to 14, the contact surfaces were also pole surfaces. The pole faces must have a certain size with regard to the magnetic efficiency, which for an electric Contact formation not necessary at all- is. To meet both requirements, optimal pole surface and small contact surface In addition to the pole face F1 formed as a contact, there is also a pole face assigned to r2, which, as an electrically insulating ceramic magnet, has practically no capacitance opposite ladders is.

17 to 20 shows a particularly economical manufacturing process shown, wherein the bobbin consists of two molded parts 54,55, in which the pole shoes 52,53 - which at the same time serve as fixed contacts 52a, 53a and also as Contact terminals 52b, 53b are formed, and the -mittelkontaktanschluss 58 and the coil terminals 59a, 59b, 59c, 59d are embedded. The molded part 54 has at least a projection 56 which forms a fit with the recess 57 of the molded part 55. The economical production method of this measure is shown in Fig. 19, namely, by continuously forming a plurality of molded parts 54a, 54b, 54c, etc., and the strip-shaped, pre-punched and bent pole pieces 52c and -der pre-punched medium contact strips 58a and those made of wire or sheet metal strips Coil connections 59e, 59f, in a manner known per se, encapsulated or

pressed in and thus in the individual molded parts 54a, 54b, 54c, etc. be embedded. The molded parts 54a, 54b, 54c are grounded by a simple cutting process separated from each other, with the length L of the coil and contact connections fixed will.

The other molded part 55 is also produced in the same way.

This manufacturing method still has the advantage that between the pole pieces 53 and the magnet chamber 60, an electrical insulating layer d1, d2 can be provided can, which consists of the same insulating material as the two molded parts 54,55.

The contact tongue is used to avoid burrs and tension 2.51 formed in the chemical-n etching process and with the nose 50 of the center contact connection 58 spot-welded or brazed before the two molded parts 54,55 become one Coil bobbins according to FIG. 20 are assembled.

After compressing the parting line between the two molded parts 54,55, the The resulting coil formers are wound and the ends of the coil wire with the coil connections 59a, 59c, with a coil winding, and additionally with the coil connections 59b, 59d, with two coil windings, soldered or spot-welded. After filing A magnet 26 magnetizes the system and moves it through its own magnetic field Bend of the nose 50 and the attached end of the contact tongue 51 existing Adjustment member adjusted or

adjusted by a suitable adjustment device before this is secured by the Abdeokkappe 62 from unwanted access. The cover cap 62 is put on after evacuation and filling of the contact chamber 61 with «protective gas and compressed before the embedding of the described in the main patent application Relay is made in cast resin.

There are many applications, bees a protective gas filling or and embedding in cast resin is not necessary, but it is still a safeguard of the adjusting member 50 or the adjusting members 50,51 is desired. This is for example useful when the switching load to be actuated generates a low arc, the expected service life is not very high and the purchase price is as low as possible is asked. The conception of the invention then allows operations such as e.g. Omit protective gas filling and embedding in casting resin.

A further development of the invention is for one-sided rest position the contact tongue 51 of the magnet 26 asymmetrically between the two pole pieces 52,53 (Fig. 20) arranged around the free end of the contact tongue 51 in the de-energized state to be brought into contact with the pole piece on which the magnet 26 rests or its separating insulating layer d1 (Fig. 18) is much smaller than that of the magnet chamber 60 and the pole piece 52 separating insulating layer d2 (FIGS. 17 and 20).

This inventive measure creates a certain memory effect achieved by namely part of the permanent magnetic Attraction of the natural spring characteristics of the contact tongue 51 is taken up, when the coil is excited, it is opposite to the direction of attraction of the permanent magnetic field acting polarity no longer needs to be overcome and thereby the efficiency a relay with one-sided contact rest position is also significantly improved.

Claims (15)

Claims Electromagnetic changeover relay with protected against environmental influences Contact system to which the movable contact consists of a lengthways through the interior of the bobbin running contact tongue consists of ferromagnetic material, according to patent application S 103 130 UIIIc / 21g, characterized in that the adjustment of the contact tongue (39) is done by bending noses (40, 41, 50). 2. Electromagnetic changeover relay -according to claim 1, characterized in that that there is a ceramic magnet (26) between the pole pieces (52,53). 3. Electromagnetic changeover relay according to claim 1 and 2, characterized characterized in that the ceramic magnet is asymmetrical with respect to the pole pieces (52,53) is arranged. 4. Electromagnetic changeover relay according to claim 1, 2 and 3, characterized characterized in that a metallic magnet (31) and between the pole pieces a ceramic magnet (26) is located. 5. Electromagnetic changeover relay according to one or more of the preceding claims characterized in that the cross-sections (Q) by a Ceramic magnet h6i 250C ambient temperature between the pole shoes are megnetically saturated. 6. Electromagnetic changeover relay according to one or more of the The preceding claims, characterized in that-between the contact parts (35,36) and the two legs of the yoke (34) are ceramic magnets (33a, 33b) and the contact parts are connected to the end face of the bobbin (37). 7. Electromagnetic Umachai relay according to one or more of the The preceding claims characterized in that the spool body is made of ceramic magnetic material 8. Electromagnetic changeover relay after one or more of the preceding claims, characterized in that in addition to the metallic pole face (F1) also consists of a ceramic magnetic material pole surface (F2) of the contact tongue (39) faces. 9. Electromagnetic changeover relay according to one or more of the The preceding claims, characterized in that the coil body serving as a protective tube from two main molded parts (54,55) - with matching approach (56) and recess (57) exists. 10. Electromagnetic switching relay according to one or more of the the preceding claims characterized in that the central contact connection (58) the coil connections (59a, 59b, 59c, 59d) and the pole shoes (52,53) in the two molded parts. (54,55) are embedded. 11. Electromagnetic changeover relay according to one or more of the preceding claims characterized in that between the magnet chamber (60) and Pole shoe (52,53) consists of an insulating layer made of the material of the molded parts (54,55) (d1, d2) exists. 12. Electromagnetic changeover relay according to one or more of the the preceding claims characterized in that the pole pieces are pre-punched and pre-bent strips (52c), the center contact terminal as a pre-punched strip (58a) and the coil connections (59e, 59f-) as strips or wires in the molded part (54), pressed or injected in a known manner and then with the desired length L of the connections are separated from each other. 13. Electromagnetic changeover relay after one or more of the The preceding claims, characterized in that the contact tongue (51)> with the nose (50) of the center contact connection (58) spot-welded or brazed is. 14. Electromagnetic changeover relay according to one or more of the The preceding claims characterized in that the parting line between the two molded parts (52,53) is compressed in a known manner after joining, so that the contact chamber (61) is completely separated from the coil space. 15. Electromagnetic changeover relay according to one or more of the The preceding claims, characterized in that the adjusting members (nose 50 and the end of the contact tongue 51) connected to it, as well as the contact chamber (61) a cover cap (62) are secured or sealed. L e r s e i t e