DE887967C - Electrical jump-free, hand-operated installation switch - Google Patents

Description

Electrical jump-free, hand-operated installation switch To build electrical installation switches in such a way that there is no noise when switching arises is the easiest way to design the switch without jumping, since the The reason for the switching noise is the jump mechanism for the switching element. The one without a jump Switch also has the advantage that it is due to its low material and Labor is cheaper than the switch with jump mechanism. Besides, his is Lifespan longer. The jump switch is only available in alternating current networks usable. In DC networks occur at the switch as a result of the slow Movement of the switching element significant damage to the contacts that the Make switches unusable. When connecting power consumers with high power consumption there is even a risk of the switch burning and endangering the environment will. Up to now, installation switches without jumpers have been brought onto the market not permitted, as there is a possibility that these switches in DC systems to be installed.

The invention is based on the object of the installation switch without a jump mechanism to be trained in such a way that when connected to direct current it does not produce a Put out of service immediately. According to the invention is in the switch Current-type-dependent, capacitor-free monitoring device built in, which is activated when connected of the switch to an AC network allows the switch to operate, however when connecting the switch to a direct current network Current path in Switch interrupts. Through the switch according to the invention, the consumer winds up instructed to use it only where it can be used safely. Despite its safety device, the switch is lower in price than that cheapest switch with spring mechanism.

In the drawing are two embodiments according to the invention shown.

FIGS. 1 to 3 show one exemplary embodiment and FIGS. 4 to 6 the other embodiment. Fig. I and 4 show the switch in the off position, Fig. 2 and 5 in .der switch-on position when connected to direct current and Fiig.3 and 6 in the on position when connected to alternating current.

In the two exemplary embodiments, i is the electrical one without a jump mechanism Counter. The switch is expediently inaccessible within the dashed border closed. 2, 3 are the terminals that come out of the dashed border stand out. The terminals 2, 3 sit on the contact parts 4, 5. 6 is another Contact part, which is separated from the contact parts 4, 5 and the stationary main switching contact part represents. A contact spring 7, which is the main switching element, is attached to the contact part 5 of the switch forms. The main switchgear 7 can be operated from the outside by a Handle 8 are pressed against the Hauptschaltkontakttei16, whereby the switch is switched on. The contact parts 4 and 6 are connected to one another by a contact bridge 9 conductively connected. In the main switch contact part 6 is a spring-loaded one Auxiliary contact ok arranged in the form of a plunger. The two shown in the drawing According to the invention, switches are provided with a current-type-dependent monitoring device provided that when the switch is connected to an AC power supply, the operation of the Switch allowed, however, when the switch is connected to a direct current network Current path in the switch interrupts.

In the embodiment of FIGS. I to 3, the monitoring device is formed according to the invention by an electromagnet i i, which is the contact bridge g is arranged opposite. The contact bridge 9 is magnetic and in this case represents an armature for the electromagnet. The electromagnet is useful provided with a core made of permanent iron. The coil of the electromagnet is on with one end connected to the contact part 5 and with the other end brought up to the auxiliary contact io. The auxiliary contact io is on the main switching element , facing end provided with insulation. 12, is a latch that holds on the contact bridge 9 is used in the tightened state.

The switch; Figs. I to 3 has the following mode of operation: Fig. i shows the switch in the off position. If the handle 8 of the switch is switched on, so the main switching element 7 first strikes against the auxiliary contact io, the auxiliary contact closes a current path from the contact part 5 via the electromagnet i i, the HilEcontakt io to the contact part 6. If the switch is connected to direct current, so the magnetic flux in the magnet i i is so strong that the contact bridge is attracted, -which interrupts the current path between contacts 4 and 6 will. In the tightened state, the contact bridge 9 is opened with the aid of the pawl 12 held. As shown in FIG. 2, the switch can easily be switched on so far be that the main switching element 7 touches the main switching contact part 6. It flows but no current from terminal 2 to the terminal. However, the switch is on AC connected, so when the switch is turned on in the coil of the electromagnet i i die, self-induction effective and reduces the magnetizing current in such a way that that there is no sufficient magnetic flux to attract the contact bridge 9. So it remains the contact bridge in the position; in which the contact parts 4 and 6 connects. If the handle 8 of the switch is moved so far that the main switching element 7 touches the main switching contact part 6 (FIG. 3), a current flows from the terminal 2 to terminal 3. This current can easily be changed as desired by moving the handle 7 switched off and on.

In the embodiment of FIGS. 4 to 6, a self-induction coil 13 and a fusible wire 14, both of which are connected in friction, serve as the current-type-dependent monitoring device. The contact bridge 9 is formed by an angle which is under the action of a spring 15. The spring 15 seeks to open the bridging point between the contact parts 4 and 6. As long as the fuse wire 14 is intact, the contact bridge cannot open because the fuse wire holds the angle lever. One end of the magnetic coil is brought up to the auxiliary contact io, which this time is isolated from the main switching contact part6. The angle lever 9 to which the fuse wire 14 is attached is in conductive connection with the contact part 4.

The mode of operation of the switch shown in FIGS. is as follows: The Fig. ¢ shows the switch again in the off position. wind the handle 8 of the switch is turned on, so will. first again the monitoring device switched on by a current from the main switching element 7 via the auxiliary contact io, the coil 13, the fuse wire 14, the bell crank 9 to the contact part 4 flows. If the switch is connected to direct current, there is only 13 in the coil the ohmic resistance is effective. It occurs in the fuse wire 14 as follows: large current on that it melts through. This will; the contact bridge 9 released and can under the action of the spring 15 move away from the main switch contact part 6, so that the contact parts 4 and 6 are separated from each other. Will when you turn on the switch the main switching element 7 pressed against the Hauptschaltkontäktteil6, so can no. Current flow from terminal 2 to terminal 3 (Fig. 5). But it is different when connecting the switch to alternating current. When the monitoring device is switched on is, the self-induction is effective in the coil 13. This self-induction reduces the current flowing through the monitoring device so that the fusible conductor 14 does not melt through. So it remains the contact bridge 9 in the position in which they the contact parts d. and 6 connects. Touches the switching element when switching on 7 the main switching contact part 6, so the current from the terminal 2 to the terminal 3 flow. By operating the handle 8, this current can be switched off and on at will will.

In addition to the exemplary embodiments shown in the drawing also the construction of a switch according to the invention with the use of rectifying means or through the induction of electrochemical precipitations possible, the such have the effect that when the switch is connected to an alternating current network, the operation of the Switch is possible, however, if the switch is connected to a direct current network the current path in the switch is interrupted.

The invention thus provides an electrical switch without a jump mechanism has been created that can be used in AC systems, but in DC systems can be used immediately without causing any danger.

Claims (3)

PATENT CLAIMS: i. Electric jump-less, hand-operated Installation switch, characterized in that a current-type-dependent, Capacitorless monitoring device is built in when the switch is connected allows the switch to operate on an alternating current network, but when connected of the switch to a direct current network interrupts the current path in the switch. 2. Switch according to claim i,. characterized in that .the monitoring device of a Electromagnet (ii) is formed, which is dimensioned such that it is when connected On the other hand, a contact bridge (9) in the current path of the switch opens to direct current When connected to alternating current, the contact bridge (9) is unaffected. 3. Switch according to claim i, characterized in that the monitoring device consists of a Self-induction coil (13) and a Schm @ elz, wire (T4) connected in series exists in such a way that when connected to direct current the fuse wire melts through and a contact bridge under the action of a spring in the current path of the switch releases to open, on the other hand, when connected to alternating current, the contact bridge is unaffected leaves. d .. Switch according to claim i to 3, characterized in that the monitoring device When the switch is switched, it automatically connects to the mains before the main switching element (7) touches the main switch contact part (6). Printed publications: German Patent No. 565 54-5-