DE809680C - Switch for electric light - Google Patents

Description

Electric light switches Electric light switches are usually built in such a way that the light goes out immediately when it is switched off. That immediate extinction has a disadvantage in many cases, as the way to next light switch, e.g. when leaving the room after extinguishing the Desk lamp or the like, must be done in the dark or that only the next light switch must be turned on before the former is turned off.

This disadvantage could be avoided if the light continued to glow after the switch was switched off, for example 20 or 30 seconds. There are known switches which aim to perform a similar process, for example the automatic stairwell lighting. However, these show a fundamental difference in that with them the lighting duration lasts from the time of switching on and not, as required, from the time of switching off for a certain definable time.

The above-described disadvantage is eliminated by the switch according to the invention the common light switch is remedied by having it, be it on mechanical or electrically, through an afterglow device in the switch, the light contact after switching off the switch is kept closed until it after a predetermined afterglow period of the light is opened automatically.

The switch-off delay required for the afterglow period can can be achieved in different ways, for example by having one when switching off of the light switch effective small pendulum or air brake between the switching elements is installed. A significant simplification is through the use of the electric current achieved by switching the switch, be it at Switching on or off, plus a closing thermal switch is switched on, the heating coil of which is switched off after the light switch has been switched off the contact-making thermal sensor, for example a bimetallic strip, is heated and the interruption of the luminous flux and the heating current according to the afterglow period initiates.

It has now been shown that it is not necessary to use the heating current to give a separate circuit for the thermal switch, but that the luminous flux can even be used as a heating current, as that required for the heating winding Resistance practically no loss of luminosity for the switched on bulb brings. The heating coil of the thermal switch has a particular advantage here a small, adjustable rule% # riderstand connected in parallel with the one on the light switch the afterglow period can be adjusted from the outside as required. This is at the same time given the adjustment to the wattage of the incandescent lamp.

A particularly simple, practical one that is easy to install in the light switch Execution of the thermal switch is that the same from a directly provided with the heating coil and the pear metal strips carrying a contact as well as a toggle contact spring carrying the other contact, the Thermal switch is arranged in the light switch so that when the light switch is operated a switching element of the same the toggle contact spring from the bent open position the contacts pushes through in the bent final position of the contacts. After this Switching off the light switch warms it up through the heating coil of the bimetallic strip flowing luminous flux the bimetallic strip and bends it against the toggle contact spring until the latter turns back into the open position.

The afterglow time of the light switch is now dependent on the room temperature, which can fluctuate between high degrees of cold or heat depending on the season, as the bimetal strip is heated from room temperature to the opening of the contacts and thus at a low room temperature takes more time than with higher. This temperature dependency can be countered by readjusting the control resistor. However, it can also be compensated for by suitably designing the thermal switch. A beshders simple design consists in the fact that the thermal switch has two parallel bimetallic strips, rigidly connected at one end and rotatably mounted as well as bending in the same direction when heated, whereby only the one carrying the contact has the heating winding. The free end of the other bimetal strip is slidably mounted on the retaining bracket of the thermostat. When the room temperature changes, both bimetallic strips bend uniformly and remain parallel, so that the contact of the strip provided with the heating coil maintains its position in relation to the contact of the toggle contact spring, as long as the bimetallic strip does not receive any additional heating from the heating coil.

The drawing shows an example of an embodiment of the switch according to the invention, with electrical switch-off delay with reference to a commercially available push button switch mold, wherein Fig. I is an elevational view, Fig. 2 shows a horizontal section through the optical switch omitting the normal shift link parts, and FIG. 3, the Side view of a room temperature compensating thermal switch with two bimetal strips.

In the housing i is located on the switch base 2, the pushbuttons 3 and 4 supporting bridge 5 , which actuates the toggle switch member 6 around the pivot point 7 in the on and off positions left and right, with the power supply contacts 8 and 9 by the Toggle switch member 6 are closed. Below the toggle switch member 6 is in the base 2, loaded by the screws io. The thermal switch is attached, consisting of the bracket ii, the bimetallic strip 14 provided with the insulated heating coil 12 and the contact 13 , and the toggle contact spring 15. The bimetal strip 14 is insulated and built into the thermal switch, with one end of the heating coil 12 on it is metallically connected to the bimetal strip 14. The other, free end of the heating coil 12 is connected to the power terminal 9 and the contact 16 bearing Kippkontaktfeder 1 5 is electrically connected to the power terminal. 8 The resistor 18, which can be regulated by means of the small toggle 17 which can be operated from the outside, is attached to the switch base 2 parallel to the heating winding 12 of the bimetallic strip 14.

The embodiment of the thermoswitch shown in Fig. 3 , which switches off the influence of the room temperature, again shows the bracket ii with the bimetallic strip 14 carrying the heating coil 12 and the tilting contact spring 15. The bimetallic strip 14 is isolated via the intermediate piece 20 with a rotatable about the small axis of rotation ig second bimetallic strip 21 rigidly connected, the free end of the bimetallic strip 21 being guided in the catch 22 located on the retaining bracket ii.

In the drawing, in FIG. 2, the conductive connections between the power supply contacts 8 and 9, the heating winding 12 and the regulating resistor 17 are indicated with strong dots.

When the light switch is switched on by means of the push button 3 , the flipping toggle switch 6 pushes the toggle contact spring 15 downward, the contact 16 of the toggle contact spring 15 being pressed onto the contact 13 of the bimetallic strip 14. As long as the light switch is switched on, the luminous flux goes through the power supply contacts 8 and 9 and the toggle switch element 6. From the moment the switch is switched off by means of push button 4, the luminous flux remains from the power supply contact 9 via the heating coil 12, the bimetallic strip 14, the toggle contact spring 15 to the power supply contact 8 closed, with the regulating resistor 18, taking over part of the luminous flux, lying parallel to the heating winding. The luminous flux component passing through the heating coil 12 heats the bimetallic strip 14, the free end of which carries the contact 13 thereby bends upwards and pushes the toggle contact spring upwards with the contact 13 via the contact 16 until it moves into the position shown in dashed lines through the top and finally interrupts the lighting circuit.

The mode of operation of the room temperature compensating thermal switch according to Fig. 3 is f01-gende: The two parallel bimetal strips 14 and 21, which act in the same direction, are rigidly connected at one end but are rotatably mounted in the bracket ii with the axis ig, bend when the Room temperature in the same way and remain completely parallel. Since the free end of the bimetallic strip 21 is guided on the bracket ii in the detent 22, the position of the contact 13 located on the bimetallic strip 14 remains the same and thus also the distance between the latter and the contact 16 of the toggle contact spring 15. Only when the light switch is switched off Additional heating of the bimetallic strip 14 by the luminous flux component flowing through the heating winding 12 generates the bending of the bimetallic strip 14 required to switch off the thermal switch can be used accordingly. In the case of multiple switches, as they are often used for group switching of incandescent lamps, the afterglow device is assigned to the circuit that was last switched off.

Claims (2)

PATENT CLAIMS: i. Switch for electric light, characterized in that a mechanically or electrically operated afterglow device is attached to a switching element of the light switch, which after switching off the light switch maintains the luminous flux for a certain, expediently adjustable time. 2. Switch for electric light according to claim i, characterized in that the afterglow device consists of a thermal switch connected in parallel to the switching element of the light switch, which, switched on by the switching operation of the light switch, connects the power supply contacts in an electrically conductive manner until the after switching off the Light switch through the thermal switch, the luminous flux still flowing, interrupts the circuit of the thermal switch and thus the luminous flux itself. 3. Switch for electric light according to claim i and 2, characterized in that the thermal switch consists of a heating coil provided with a contact bearing bimetallic strip and the other contact bearing toggle contact spring and that the thermal switch is arranged in the light switch so that when switching of the latter, the toggle contact spring is pushed through by one of its switching elements from the contact opening position into the contact closing position and that after switching off the light switch, the luminous flux then flowing through the heating coil of the bimetal strip heats the bimetallic strip and bends it against the toggle contact spring until it turns into the contact opening position. 4. Switch for electric light according to claim i to 3, characterized in that the heating winding of the bimetallic strip is connected in parallel with an externally adjustable control resistor. 5. Switch for electric light according to claim i to 4, characterized in that the thermal switch has two parallel, rigidly connected at one end, rotatably mounted in the bracket of the thermal switch, acting in the same direction bimetal strips, one of which has the contact and the heating coil carries and the other is guided at the free end in a latch located on the bracket of the Thenno switch.