DE1110308B - Magnetically operated protective tube changeover contact with transition - Google Patents

Description

Magnetically operated protective tube changeover contact with transition Die The invention described below relates to a magnetically operated Protective tube changeover contact in which the changeover takes place in such a way that, starting from the rest position of the contact, in which its rest side is electrically closed, first the electrical connection is made with the working side, after which the rest side is only made is separated. This process is commonly referred to as a transition; In other words, in the present case it is a protective tube changeover contact with Crossing.

Such a protective tube changeover contact with transition is shown in FIG. 5 of US Pat. No. 2,397,123. This contact is based on the principle common to protective tube changeover contacts, according to which a magnetizable changeover contact spring is arranged between a non-magnetizable break contact piece and a magnetizable work contact piece, with the changeover contact spring resting on the break contact piece in the rest position of the contact. When such a contact is excited, attractive forces occur between the magnetizable changeover contact spring and the likewise magnetizable work contact piece, which cause the contact point between the changeover contact spring and work contact piece to be closed.

In the known protective tube switchover contact with transition, the Transition function achieved in that on the work contact piece a resilient End part hangs, which is drawn to the changeover contact spring in the event of excitation will. For this purpose, the restoring force of this end part is dimensioned to be lower than the contact force of the changeover contact spring with which it is in the idle state rests on the break contact piece. The switchover contact spring has on its movable End of a bridge, which is magnetizable by the changeover contact spring alone Part represents. In addition to the changeover contact spring, there is a particularly rigid one Flux guide part arranged, which reaches close to the bridge. Through this Last-described structure is achieved that after closing the contact point between changeover contact spring (bridge) and end part of the working contact piece between the bridge and the river guide part sets a river, which now the bridge with pulls the end part of the working contact piece that adheres to it to the flux guide part, whereby the contact to the normally closed contact piece is interrupted and to the normally open contact piece is made alone.

This structure described above is one over against the normal Protective tube contacts, in particular protective tube changeover contacts, are fundamentally different Construction represents the special manufacturing technology because of the large number of parts Makes demands.

The invention is based on the object of a protective tube changeover contact with transition to .schaffen, which basically differs from the structure of the well-known protective tube changeover contact does not differ. This is essential for reasons of type limitation Meaning. The protective tube changeover contact according to the invention with transition is thereby characterized in that the switching contact spring consists of two tongues in the Rest position both rest on the rest contact piece and one of which is designed in this way is that it requires less excitement to operate than the other, and the tongue actuated with less excitement in the addressed state at least is approximately saturated.

This construction identified above differs from the usual simple protective tube changeover contact (without transition) merely by that the changeover contact spring consists of two tongues without in principle Something changes in the structure of the normally closed contact piece and the normally open contact piece. she makes it possible to start from the usual protective tube changeover contacts and the two to form mentioned tongues in that in the changeover contact spring - a common one Protective tube switching contact a longitudinal slot is attached.

The principle is explained below.

1 and 2 is a: protective tube changeover contact with transition shown in the resting position, namely, Fig. 1 shows the contact in side view and FIG. 2 in plan view. In the protective tube 1 are from one Side the normally closed contact piece 2 and the normally open contact piece 3 melted down. The normally closed contact piece 2 has at its end located in the glass tube 1 a part 4 made of non-magnetizable Material. The changeover contact spring is in the glass tube 1 from the other side 5 melted down in the drawn rest position on the non-magnetizable Part 4 of the normally closed contact piece 2 rests.

As can be seen from FIG. 2, the changeover contact spring has 5 a longitudinal slot 6, which the changeover contact spring 5 in two tongues 7 and 8 splits. The tongue 7 is now designed so that a smaller one to operate it Excitation is required than for the tongue B. This is achieved by the Tongue 7 with respect to the working contact piece 3 has a larger pole surface than the tongue B. These pole faces are formed by the faces 9 and 10. As can be seen is the surface 9 with which the tongue 7 faces the working contact piece 3, larger than the corresponding area 1 0 in the case of tongue B. As a result, with increasing excitation of this contact (which is usually not caused by a shown, the protective tube 1 surrounding winding is applied) the fiow in Air gap between the tongue 7 and the working contact piece 3 first set the response value reach that tongue. The tongue 7 is then attached to the working contact piece 3 consulted and gives contact with this person. This switching state is shown in FIG which shows the same contact in side view. This reduces the magnetic resistance between the tongue 7 and the working contact piece 3 so far that the tongue 7 is saturated. That constantly during this process further increasing excitement now causes this phenomenon of saturation a steadily increasing flow of the tongue 8 is pressed, which eventually the response value of this tongue is reached, so that this too is connected to the normally open contact piece 3 is used and gives contact with this person. This state of contact both tongues 7 and 8 with the working contact piece 3 is shown in FIG. shown.

It should be noted here that the increase in excitation according to a such a time function takes place that only after the end of the turnover time of the tongue 7 the response value of reed 8 is reached. This creates the transition function of contact guaranteed with certainty. As can be seen, the above takes place described process first a contact between the tongue 7 and the working contact piece 3, before the path running over the tongue 8 from the contact spring 5 to the normally closed contact piece 4 is solved. Only then is the contact between the contact spring separated 5 and the normally closed contact piece 2 by folding over the tongue B.

In the opposite process of de-energizing that described above Contact results in the following: In the addressed state of the contact, shown in Figure 4, the two tongues 7 and 8 are traversed by roughly equal rivers, as for the flows over the two tongues as a result of their support on the working contact piece 3 practically no different magnetic resistances exist in this Case are essentially only determined by the iron cross-section. Consequently magnetic forces of attraction arise for both tongues, which with regard to their difference due to the different size of the contact surfaces on the Working contact piece 3 are intended. These are the surfaces 9 and IC) (FIG. 2). According to known physical laws, with the same flow for the Tongue with a larger contact surface, i.e. tongue 7, has a lower force of attraction than for tongue B. As a result, with decreasing excitation for tongue 7 the drop excitation is reached first, whereupon it drops from the normally open contact piece 3. In the event of further de-excitation, finally, only the tongue 8 remains Waste excitation, so that this tongue also returns to its rest position. Even with this one The process described above results in a transition effect in which initially the tongue 7 is in contact with the normally closed contact piece 2, before: -nake the tongue 8 itself has released from the working contact piece 3. It should be noted here that the period between reaching the waste excitation for the tongue 7 and then for the Tongue 8 is greater than the turnover time of tongue 7, so that the transition effect is guaranteed with certainty.

As can be seen from the explanations above. is to achieve the desired transition effect is the rise or decay of the magnetic Flow in the two tongues of the changeover contact spring according to such a time function set up. that the successive pickup or dropout values of the two Tongues follow one another at a greater time interval than the turnover time of the first operated tongue lasts.

This requirement can be expediently fulfilled in that one for the rise in flux is the time constant of the excitation winding electrical circuit and for the fall of the flow the time constant of a damping circuit determined accordingly. In the first case, this essentially boils down to determine the inductance and resistance of the excitation winding appropriately. in the the latter case is a damping circuit, for example a short-circuit winding, to ensure that the river descent occurs in the required period. Since a short-circuit winding also influences the increase in the flux, one can instead, for example, a known circuit with an excitation winding in the event of disconnection, provide a short-circuiting rectifier, if one Affecting the rise of the river is undesirable. This results in the Protective tube changeover contact the possibility of this not only for the response and to let the waste process work together with transition effect, but rather the Transition effect also optionally either only for the response process or only for to provide for the waste process. For each of these latter two cases is only to ensure that nu.-in connection with the desired process with transition effect a corresponding setting of the time function of the change in flow takes place. You get thus a protective tube changeover contact, which either only when responding or only has the transition effect when falling.

Using FIGS. 1 to 4, it was described how the principle to develop one of the two tongues in such a way that that they are to their activity requires less excitement than the other, can be realized by the fact that the pole face of the two tongues is different with respect to the working contact piece great training. There are a number of other options, as follows are described.

You can give the two tongues a different contact force, i. H. a different bias, with which they give on the normally closed contact piece rest. This leads to the fact that with the excitement first the tongue with less Bias is actuated and after its saturation the actuation of the tongue with greater bias follows. In the case of de-excitation, it detaches itself from the working contact piece first of all the tongue with greater bias (assuming the same pole faces), which is followed by the fall of the tongue with less tension.

The transition effect can also be achieved by the gives both tongues a different magnetic conductivity. In this case When excited, the tongue becomes first with greater magnetic conductivity actuated and then the tongue with the lower conductivity. With the excitement the tongue with lower conductivity falls off first, followed by the tongue the greater conductivity (with the same pole face). These operations correspond in their order of actuation of a contact, in which, as above described, the two tongues have different biases. This effect results from the fact that the tongue with the greater magnetic conductivity the stronger flow and consequently stronger forces act on that tongue.

It is advantageous to combine these different routes with one another. A corresponding embodiment is obtained, for example, if you have the Switching contact spring provided with a longitudinal slot (see FIG. 2), this longitudinal slot but not in the middle, but laterally offset and additionally the the narrower tongue gives the greater tension. In this case, the narrower tongue, greater magnetic resistance and greater contact force, with which it rests on the normally closed contact piece. As a result, speaks at arousal the wider tongue first. It should be noted that with the same length Tongues for the narrower tongue results in a smaller pole surface than for the wider one Tongue. As a result, the narrower tongue has a tendency to de-excite to fall off later than the wider tongue. This tendency has an effect on the endeavor earlier drop, given by the greater magnetic reluctance and the greater Bias, against. So these two opposing tendencies are in one Combination must be taken into account accordingly or can also result in compensation can be used when contact is desired, which only has the transition effect when responding shows.

From the above it can be seen that the correct utilization of the effects described above under all operating conditions can achieve safe working contact establishment.

Claims (7)

PATENT CLAIMS: 1. Magnetically operated protective tube changeover contact with transition, characterized in that the changeover contact spring consists of two tongues exists, both of which rest on the normally closed contact piece in the rest position and of which one is designed in such a way that it requires less excitation for its actuation requires than the other, and the tongue actuated with less excitement in the addressed State is at least approximately saturated. 2. protective tube changeover contact according to claim 1, characterized in that the two tongues with different contact force rest on the normally closed contact piece. 3. protective tube changeover contact according to claim 1, characterized in that the two tongues with respect to the working contact piece have different sized pole faces. 4. protective tube changeover contact according to claim 1, characterized in that the two tongues have different magnetic conductivity, in particular have different cross-sections. 5. protective tube changeover contact, characterized by the combination of the features according to claims 2 to 4. 6. protective tube changeover contact according to one of the preceding claims, characterized in that that the two tongues are formed by a longitudinal slot in the changeover contact spring are. 7. protective tube changeover contact according to any one of the preceding claims, characterized characterized in that the time function required for the increase in the flow through determines the time constant of the electrical circuit including the excitation winding is. B. protective tube changeover contact according to one of claims 1 to 6, characterized in that that the time function required for the flow to decay through a damping circuit is determined.