DE1806896A1 - Relay circuit with electromagnetic double winding relay - Google Patents

Description

Lawyer file no. 17 826

POLITECHNIKA POZNAirSKA, Po snafi / Poland.

^w Eelals circuit with electromagnetic double winding relay. "

The invention "relates to a relay circuit with electromagnetic Double winding relays, which have a uniform type of normally closed contacts. The windings of the The coils of these relays are wound in the same direction or in opposite directions. The excitation of each of the partial windings for itself allows the respective relay to respond. The control circuits,

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each composed of normally closed contacts, mechanical input elements and closed cones of the indirect and output relays, or only one or two of these devices, are connected in series with the input terminals of the partial windings. The input terminals of the second partial windings are connected directly to the power source. The output terminals of the two partial windings are interconnected and connected to a power source either directly or via normally closed contacts of the control circuit. Double winding relays with co-wound parts «windings must be connected to a direct current source at its plus, minus and zero pole. However, may relay the part windings are wound in opposite directions, to the plus and minus or plus "and zero or negative and zero-terminal of a DC power source or auQii _t vMxm1aat when the relay type is allowed to be connected to an AC power source.

The known relay circuits are made up of electromagnetic relays with one or more windings of the Coils and built with rest «and work contacts. the Windings of the relay with several individual windings can be wound in the same direction or in opposite directions and can thereby have dissimilar or similar magnetic fluxes generated by the windings. These circuits have

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mostly an uneven distribution of the contacts in a relay, which necessarily leads to the application of different Relay types in a circuit leads.

A large number of different relay types in a relay circuit makes the circuit confusing and makes it difficult to use it cheaply and in the case of switchable Contacts, the problem of structural unreliability of the hazard can arise.

From the technological point of view, the controller is and control of the relays with normally closed and normally open contacts Complicated and expensive, in contrast to relays that only have normally closed contacts.

According to the invention, a circuit is to be created which does not have any of the disadvantages of the known relay circuits. j

This is achieved by using a relay circuit according to Invention only one type of electromagnetic double » winding relay with normally closed contacts is used *

Several exemplary embodiments according to the invention are explained below with reference to the accompanying drawing.

1 shows the operating conditions of a sequence circuit in the form of the known Karnaugh * »matrix;

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Fig. 2 shows the Karnaugh matrix which eliminates static structural unreliability (Hazard);

FIG. 3 shows a schematic representation of a known relay circuit according to the Karnaugh matrix shown in FIG. 2;

4 and 5 show basic schemes of relay circuits according to the invention, including double-winding relays Have break contacts "

6 and 7 show alternative designs to the designs in FIGS. 4 and 5.

In FIGS. 4, 5, 6 and 7, the input terminals of the first partial winding of the electromagnetic double-winding relay are denoted by F1 and the output terminals by K1, and in the case of the second partial winding, the input terminals are marked with F2 and the output terminals with K2.

The following is an example of the differences between the known relay positions and those according to the Invention explained.

It is assumed that a sequence relay hold is characterized by the Karnaugh matriculation according to FIG. 1.

One represented by the Karnaugh matrix of FIG. 1

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without parentheses minimal. Working function of the relay circuit has the shape

W - f (a, w, q) ■ ä w ν a q Q * f (a, w, q) * ä w ν a q

The work function represented by (1) has a static structural unreliability (Hazard) and can in this form with the help of the known relay circuits (

cannot be technically implemented.

The static structural unreliability may be due to introduction can be eliminated by one-sub-matrices of FIG.

The work function of relay holding, without structural Unreliability according to the Karnaugh matrix shown in Fig. 2 has the form

W »f (a, w, q) * awvaqvwq * awvq (avw) ^

Q- f (a _t w. , Q. ■) ■ »a -WV aq ν wq ■» aq ν w (a ν q)

_{FIg 0} 3 shows the technical implementation of a relay circuit having the work function (2).

A well-known work function (2) realizing and in Fig, 3 shown real circuit has ten contacts, namely seven normally closed contacts and three normally open contacts · That

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Input element A has two rest "and two working contacts" The output element ir ': W has three normally closed contacts and the output element Q has two normally closed contacts and one Working contact.

The relay circuit according to the invention is technically realized taking into account the minimum shape of the work function shown in the formula (1). In this case, double negation is deleted from the expressions of (1) and then the individual negations are replaced by given symbols with the addition of plus one (+1). For example, ä «a -f 1, where plus (+) that Summing module - called two. After this transformation 'the'. ^; Work function (1) results for element W t

- 7th

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ORtGlNAL

■■ '"'" ■■ ■ '■■■! "UP

- 7 - ■

W = f (a, w, q) * * aw: vaq = aw. * Aör «- -

- / Ca + Dw + Λ J / "" a (q + 1) + Λ J + 1

+ 1) * (az-, +1) +1 = Zp ^z 4 + 1

where: Z ₁ = a. + 1; z ~ = Z ₁ W + 1; ζ, = g -fe Λ \ z ^ = az ^ + 1.

at: W - ■ f (a, w, q) «/ ~ (a + 1) w + 1_7 / ~ a (q + 1) + 1_7 +

(z. + 1) · (a, "+ 1) + 1« z _o z. _r + 1

at: ζ. + (a + 1) w; Zp = Z ₁₁ + I; ζ, = a (q + 1); z ^ = ζ, +. 1.

The work function (1) for elements Q. assumes the following form:

Q = - f (a, Vc ₁ q) »= ä w. Τ aq = ä W aq = / ~ (& + Ό w + Ί _β 7

• (aq + 1) + 1 «- Z ₂ Z ₅ +1 (5)

at: ζ _ς »aq +. 1

A relay circuit according to the formulas (3) and ^ 5) is shown in Fig. For double-winding relays with windings in the same direction, and in Fig. 5 for double-winding relays with windings wound in opposite directions *

m 8

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In circuits according to FIGS. 4 and 5, contacts with the same symbols could be isolated in individual control lines. For example, in the circuit diagram in FIG. 4, contacts a and z are not shown separately in separate control lines. In contrast, the same contacts a and Z _{2 are shown separately} in the circuit diagram according to FIG. 6 in separate control lines.

A relay circuit which fulfills formulas (4) and (5) is shown in FIG. ₀ 7, for example for double-winding relays with co-winding. In the circuit diagram of Fig. 7, the contacts a and z ^ are separated in separate Steuerlei turigen.

The relay circuits shown in FIGS. 4, 5, 6 and 7 according to the invention are completely different from the known relay circuits. Mainly own relay circuits according to the invention always only break contacts. The introduction of the normally closed contacts in the relay circuits is with the help of the typical double winding relay elements realized.

The relay elements in the relay circuits always have an even distribution of the contacts to the individual ones Elements. In the example relay circuit according to the invention of FIG. 6, it is sufficient to relay elements with a Use normally closed contact, with the exception of the output elements W

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and Q, which with their contacts not shown in FIG enable the external circuits to be switched on.

These circuits "affect the production of the corresponding Types of elements, namely of relay elements with normally closed contacts. This in turn influences the construction the relay. For example, in the case of the tube relay elements which omits make contacts, the construction of the windings can be a triangular or round shape than for the Copper consumption assume optimal form.

The relay circuits according to the invention are advantageously used in assembly on printed circuit boards, in particular the circuit according to FIG. ₉ 6.

Relay circuits according to the invention can be particularly advantageous in the automation technology of telemechanics and in any control relay circuits can be used. The individual relay circuits can be of the type depending on the nature of their uses, differ. If the relay circuit according to the invention is, for example, an electrical If the drive is to control, which has a thermal overload protection, it is to switch off the damaged one Drive necessary, only the control circuit with the given output relay through the normally closed contact of the thermal relay

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to close, or the normally open contact of the thermal Switch on the relay in the Nullarsi of the output relay. It it is also irrelevant which partial winding has the control circuit and which the short-circuited circuit.

Patent claims s

- 11 -

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Claims (1)

Patent "to. Spray: 1ο relay circuit with electromagnetic double wioklungsrelais, in which the two windings of the relay coils are wound in the same direction or in opposite directions, with the excitement of everyone! Deilwioklung for himself the relay can respond, characterized in that in each case with the input terminals (P1) of one of the partial windings Normally closed contacts of the input elements, indirect elements and Output elements, or only normally closed contacts of an element or two of the elements having control circuits are connected in series, and that the input terminals (P2) of the second partial windings each directly to one Power source are connected, or that this connection is interchangeable with the one specified for (P1) 2ο relay circuit according to claim 1, characterized in that that the output terminals (K1) and (K2) of the Teilwioklungen interconnected and connected to the power source either directly or through the contact control circuit are. 909826/0957 -Al ' L. blank