DE1169559B - Logic arrangements with protective tube armature contacts controlled by magnetic fields - Google Patents

Description

Logic arrangements with protective tube armature contacts controlled by magnetic fields The invention relates to logic arrangements with protective tube armature contacts in which switching is achieved by moving permanent magnets.

It is known to use an electromagnetic protection tube armature contacts or to switch permanent magnetic field. For this purpose are one or more Protective tube armature contacts arranged within a bobbin. It is still known to firmly arrange a permanent magnet within a bobbin that so is dimensioned so that it either causes the thermowell armature contact to tighten (Rest contact) or only vörergegt (detention contact), so that he can only use the Excitation coil opens or closes.

There are also switching devices known with which protective tube armature contacts by moving or rotating a permanent magnet, or several permanent magnets be switched together.

It is also known to polarize the permanent magnets so that this Polarization in the longitudinal direction of the contact tongues to be switched is or is Use of two permanent magnets, between which a protective tube armature contact is arranged is to polarize these permanent magnets so that their opposite poles meet repel each other and make contact when moving this magnet assembly over the working air gap opens.

All of these known arrangements for switching protective tube armature contacts but have the disadvantage that with a permanent magnet arrangement or an excitation coil only one function of one or more protective tube armature contacts can be performed and therefore at least one protective tube armature contact for each permanent magnet system or each excitation coil must be assigned, whereby the spatial expenditure is large and this known Arrangements made more expensive by the large number of protective tube armature contacts to be used will.

The invention has the object of eliminating the disadvantages of the known arrangements to avoid. According to the invention this is achieved in that one protective tube armature contact several permanent magnets of the same or different intensity are assigned and each movable permanent magnet at least one actuating device, e.g. B. a button is assigned, so that the switching of a single protective tube armature contact the result of one or more specific logical links between operations represents.

The invention has the advantages that only comparatively few Thermowell anchor contacts are used and that one or more thermowell anchor contacts one or more keys or similar actuators are assigned so that it is possible that even the actuation of a protective tube contact is the result certain logical links of z. B. key presses (events).

The invention is described with reference to drawings. In the drawings shows Fig. 1 shows an illustration of the implementation of an OR function on a protective tube armature contact with two rotatable permanent magnets of the same intensity, F i g. 2 shows an illustration the implementation of an AND function on a protective tube contact with two rotatable Permanent magnets of the same, but half the intensity as in F i g..1, F i g. 3 a Representation of the implementation of a NO function with a movable and a fixed permanent magnets of the same intensity, F i g. 4 shows a representation of a logical Function with four movable permanent magnets, which are operated by four different actuators, z. B. Keys to be controlled from, F i g. 5 shows a representation of a logic function with four movable permanent magnets operated by four different actuators are controlled from, F i g. 6 is a representation of a logic function with three movable and a fixed permanent magnet, which is operated by three different actuators, z. B. Keys to be controlled from, F i g. 7 shows a representation of a logic function with three moving and one fixed permanent magnet operated by three different actuators, z. B. Keys to be controlled from, F i g. 8 is an illustration showing a combination from the in F i g. 4 and 5 represents the arrangements shown, F i g. 9 is an illustration which shows a combination of the elements shown in FIG. 6 and 7 arrangements shown represents, F i g. 10 is an illustration as in FIG. 2 shown only with sliding Permanent magnets, F i g. 11 shows an illustration off-center from the protective tube anchor contact arranged rotatable permanent magnets, F i g. 12 shows an illustration of an arrangement according to FIG. 11 with movable permanent magnets, F i g. 13 another example for the arrangement. of permanent magnets, F i g. 14 and 15 two possible assignments from permanent magnets to a protective tube contact, F i g. 16 and 17 different magnet shapes and their polarization, FIG. 18 shows a schematic diagram of an OR change function on two protective tube contacts with two movable and one fixed permanent magnet, F i g. 19 shows a schematic diagram of an AND alternation function on two protective tube armature contacts with two moving and one fixed permanent magnet.

If you execute the keys with two positions on a keypad, z. B. a rest position and a working position, so you have a simple way a storage of the information and a display of the key position. This can information can be checked, which can be obtained by pressing one of the selections of Buttons is shown. Holding and resetting individual keys accordingly or all keys pressed can then be used together or individually in a known manner be done mechanically or magnetically or electrically. It is also common for the provision by repeated keystrokes using a mechanical memory make. Because the actuating magnets for logical functions in many different Arrangements around the contact or the contacts can be arranged, it is useful to to make their assignment as freely adjustable as possible, d. That is, one leaves the individual Actuating magnets of a contact in a constructive relationship as independently as possible from each other.

The movement of permanent magnets can itself be the result of logical connections be. So is z. B. easily possible by simple mechanical transmissions that several actuators a permanent magnet or that one actuator several Moving magnets. In addition to such couplings, mechanical locks can also be used can be applied.

Only the basic arrangements of permanent magnets are shown in the figures shown on thermowell armature contacts with the associated equivalent circuit. For the sake of clarity, suitable mounts and flow guides are not shown.

F i g. 1 shows a basic illustration of the implementation of a OR function on a protective tube contact with two movable permanent magnets M1and M2. In order to provide a measure of the strength of the individual permanent magnet for the further description to have is for a permanent magnet, which has such a great field strength that he can only switch a thermowell armature contact, the relative magnetic strength marked with one. In. the in F i g. 1 has the permanent magnet arrangement M1 has a relative field strength of one, the permanent magnet M2 also a relative one Magnet strength of one. A 90 = rotation of the permanent magnet M 1 or the permanent magnet 1112 closes the thermowell anchor contact. The rotation of M1 and M2 must be with respect to the polarity take place in the same direction. Under a is one of the basic arrangements equivalent circuit specified.

In Fig. 2 shows an arrangement of an AND function, the relative The magnetic strength of the permanent belts M1 and M2 is one-half in both cases. A 90 'rotation of M1 and M2 in the same direction in terms of polarity does this Closing the protective tube anchor contact. Under b is the equivalent for this arrangement Circuit shown.

In Fig. 3 shows an arrangement for a NO function. the relative magnetic strength for the permanent magnets M1 and MO is one in both cases. A 90 turn of M1 in the direction of the arrow opens the protective tube anchor contact. Under c the equivalent circuit is given for this arrangement.

In all examples, more than two permanent magnets can be used for actuation a protective tube armature contact can be provided. It is then possible, e.g. B. the the following functional extensions.

F i g. 4 shows a basic illustration of a logical function with four movable permanent magnets controlled by four different buttons will. The relative magnetic strength of the permanent magnets M1 to M4 is in each case Trap one. Under b is the equivalent circuit corresponding to this arrangement specified.

F i g. 5 shows a basic illustration of a logical function with four movable permanent magnets controlled by four different buttons will. The relative magnetic strength of the permanent magnets M1 to M4 is in each one Trap a quarter. Under e is the equivalent circuit associated with this arrangement specified.

F i g. 6 shows a basic illustration of a logical function with three moving and one fixed permanent magnet, those of three different ones Buttons can be controlled from. The relative magnetic strength of the permanent magnets 1.11 to M3 is one third. The relative magnetic strength of the fixed permanent magnet MO is one. Under f is the equivalent circuit associated with this arrangement specified.

F i g. 7 shows a basic illustration of a logical function with three moving and one fixed permanent magnet, which is operated by three different buttons can be controlled from. The relative magnetic strength of the permanent magnets Ml to M3 and des Permanent magnet MO is one in each case. Under g is that of this arrangement corresponding equivalent circuit specified.

F i g. FIG. 8 shows a basic illustration which shows a combination of elements of the elements shown in FIG. 4 and 5 illustrates the arrangements shown. The relative magnetic strength of the permanent magnets M 1 and h12 is one and the relative magnetic strength of the permanent magnets M3 and M4 is one-half. The equivalent circuit associated with this arrangement is indicated under h.

F i g. 9 shows a basic arrangement which comprises a combination of elements of the elements shown in FIG. 6 and 7 illustrates the arrangements shown. The relative magnetic strength of the permanent magnet M 1 is one, for the permanent magnets M2 and M3 one half and the fixed permanent magnet M 0 one. The equivalent circuit associated with the arrangement is indicated under i.

F i g. 10 shows an arrangement in which, instead of that in the preceding Examples used rotating magnets, sliding magnets have been used are. With this arrangement, an AND function is shown as an example. The relative Magnet strength of the permanent magnets M 1 and M 2 in the position shown in dashed lines brought, the contact closes. Under k is the one belonging to this arrangement equivalent circuit specified.

F i g. 11 shows further arrangements which can also be combined with the arrangements given above. These arrangements result when the actuating magnets are not arranged at the level of the contact center. The permanent magnets M1 and M2 are rotatable in the arrangement shown under a and b , only their axis of rotation is perpendicular to the longitudinal direction of the protective tube armature contact in the arrangement shown in a and parallel to the longitudinal direction of the protective tube armature contact in the arrangement shown in b.

F i g. 12 shows an arrangement according to FIG. 11, where the permanent magnets M1 'and M2' are arranged verschiebbai. In their rest position, they are through a bracket 2, which is attached to the flux guide 1, short-circuited. The working position of the two permanent magnets is shown in dashed lines.

The leakage fluxes can also occur in these arrangements in known manner according to arrangements for protective tube anchor contacts as coupling points can be used in panels. The further a permanent magnet is from the working air gap removed, the greater the leakage flux it is in addition to a certain Has to raise useful flow. Is z. B. the contact tongue by a first permanent magnet of a thermowell anchor contact at its coupling point by the sum of useful and leakage flux has already been brought to the saturation limit without the useful flux being reduced When the response flux value is reached, further permanent magnets are connected to the same Contact tongue to achieve the response increasingly ineffective. But if you order in a corresponding manner on the other contact tongue to further permanent magnets, see above pressing the first of these additional permanent magnets brings the full one again Height of the flux from the permanent magnet 1 via the other contact tongue to the working air gap. With suitable dimensioning, the thermowell armature contact will respond.

F i g. 13 shows an arrangement in which the permanent magnets are distributed in this sense. By correctly dimensioning or using the leakage fluxes for the desired saturation effects, it can be achieved that several actuated permanent magnets M1 and M2 on one side of the protective tube armature contact do not yet cause a response, while simultaneous actuation of one permanent magnet on both sides, e.g. B. M1 and M1 ', that is to say over both contact tongues, result in a response. Under c is the one according to the arrangement of FIG. 13 associated equivalent circuit is given. The shielding or flux guide plates belonging to the arrangement can be designed as shown in FIG. 13 shown under a, b or c. In this way, for. B. the strength of the tributaries to the air gap for the permanent magnets can be increased by known structural design. Flux guide pieces for the stray flux (tributary flux) are often undesirable above the contact center if a permanent magnet or any magnet arrangement already described is to be additionally attached to the protective tube contact. In this case, it is useful to have tributaries through the flow guide pieces as in FIG. 13 c shown to lead outside of the position of the permanent magnets.

F i g. 14 and 15 show various suitable positions for the permanent magnets to the protective tube contact. Instead of the in FIGS. 11 to 13 shown arrangement of rotatable permanent magnets is also an arrangement of the permanent magnets according to FIG. 15 advantageous, especially if several protective tube armature contacts are affected at the same time should be.

In Fig. 16 and 17 different magnet shapes are shown. the in the previous examples shown round disc shape for a permanent magnet can also be replaced by other magnet shapes, such as B. in Fig. 16 shown. aside from that can in some cases with multi-pole permanent magnets when actuating the same one Rotation angle savings can be achieved (Fig. 17).

In Fig. 18 is an example of a multiple permanent magnet arrangement and several thermowell anchor contacts, an OR change function is shown. the The relative magnetic strength for the permanent magnets M0, M1 and M2 is one in each case. The permanent magnet MO is fixed in this arrangement. Under m it is closed an equivalent circuit belonging to this arrangement is given.

F i g. 19 shows an example of an arrangement with a plurality of magnets and several thermowell anchor contacts an AND change function. The relative strength of the magnet for the permanent magnet M 0 is one, for the permanent magnets M1 and M2 and a half. Under n shows the equivalent circuit associated with this arrangement.

Another large number of arrangements of logic switching functions can be shown if additional combinations of the examples described so far be employed.

Claims (1)

Claim: Logic arrangement for switching protection tube armature contacts by permanently arranged and / or movably arranged permanent magnets, which are actuated by actuating devices are moved, characterized in that one protective tube armature contact several permanent magnets of the same or different intensity are assigned and each movable permanent magnet at least one actuating device, e.g. B. a button is assigned, so that the switching of a single protective tube armature contact the result of one or more specific logical links between operations represents.