DE4037782C2 - Time switch with switching mechanism - Google Patents

Description

The invention relates to a timer Switch mechanism with the features according to the preamble of Main claim.

A switching mechanism is used in such time switches this type to a spring-loaded switching element z. B. a so-called microswitch according to a program automatically switch on or off or independently of Program the switch to "On" or "Off".

For setting the program is for switching mechanisms of this type a circular movement operated by a clockwork Program disk provided, on the circumference of a tactile nose of a feeler lever rests radially or parallel to the axis. As far as this tactile nose in sectors of the disk circumference that identify the "off" position remains Switch turned off. In the sectors where in itself known way by moving switching elements "On" position is programmed, the nose is raised  and the associated pivoting movement of the feeler lever does this via a lever system coupled to it Press in the spring-loaded switching element. If at Turn on the nose of the feeler lever in the "on" sectors is raised, so is the spring force of the switching mechanism in the switch and the spring force possibly present Return springs to overcome what by a corresponding rated torque of the drive of the program disk is effected. That the pivoting movement of the feeler lever in converting a pressure on the switching element of the switch Lever system is combined with a changeover mechanism that it enables the switch to be operated by hand regardless of the program to set to "On" or "Off".

Time switches of the type described above or similar are known several times (DE-GM 90 06 927.2, DE-GM 88 02 081.9, DE-OS 35 21 091, DE-PS 33 40 373). Especially with the Solution according to DE-OS 35 21 091, which has a timer with the Features of the preamble of the main claim of describes this application, springs are necessary, thus the connection between the probe lever and the program disc remains frictional.

The task poses this state of the art of the present invention as follows: The one for the Switch off in the program and for changing over by hand required lever mechanism should be in view of a economic manufacturing and assembly made easier in such a way that it is in the "hand-off" position or "Hand-on" position no increase in torque on the Program disk needs compared to the programmed Circuit, with return springs for non-positive Avoid connection of shift lever and program disc should be.

This task is accomplished by a timer with a  Switch mechanism with the features of the main claim solved. The subclaims have preferred constructive Training of the individual elements or alternative Embodiments of the content.

With such a switching mechanism, all can Sampling, switching and changing necessary elements, So feeler lever, shift lever and changeover button, on one PCB are stored. This way the whole Switching mechanism to a functional, production-like and assembly unit. Compared to the above DE-PS 35 21 091 gives the advantage that switching mechanism according to the invention with only 2 fixed Bearing points. Thanks to the non-positive connection of feeler lever and shift lever is used in the present Invention no return spring necessary. Of the Switch mechanism uses the restoring force of the spring-loaded switching element.  

In the position required for the program switching Tactile lever presses the spring-loaded switching element z. B. of Microswitch, which protrudes in the "off" position, against the head of the shift lever, the nose of the feeler lever in Range of the circumference of the program disc lies. At the Accumulation of a switch-on sector of the program disc the nose is lifted and the gear lever presses it spring-loaded switching element.

In the "hand-on" position or "hand-off" position is the Nose lifted so far that it is through the switching sectors of the Program disc is no longer affected, so that the The program disk is not driven for increased torques must be dimensioned. The spring loaded Switching element in the "hand-on" position has no influence on the program disc. For setting the program disk of the time switch to the current time it is both clockwise and counterclockwise Turnable clockwise without the drive or the Switching mechanism is damaged. The items like The feeler lever, shift lever and adjusting knob can be used as Produce plastic molded parts economically. For the Articulated connection between feeler lever and shift lever can instead of a hinge pin that goes into an articulated sleeve intervenes, also according to the further embodiment of the Invention a film hinge can be provided, the Possibility opens the two levers in one operation to manufacture. Shift lever and lever are therefore at this variant through the film hinge to one one-piece lever system connected, which is the assembly much simplified.

The following are exemplary embodiments of the invention described with reference to the drawings.

Fig. 1 shows in principle a switching mechanism according to the invention in the "automatic" position with the phase switched off;

Fig. 2 is the "automatic" position with the phase switched on;

Fig. 3 shows the switching mechanism in the "hand-off"position;

Fig. 4 shows the switching mechanism in the "hand-on"position;

Figs. 5 and 6 show details of the lever system in each case in two views;

Fig. 7 shows the knob in side view and top view;

Fig. 8 shows a top view of the circuit board;

FIGS. 9 and 10 show a sensing lever and a shift lever pivotally connected by a film hinge in two views and installed according to Picture 1 and 2.

By means of a switching mechanism according to the invention, an electrical switch 1 (eg microswitch) with a spring-loaded plunger-like switching element 2 is to be switched according to a predetermined program or alternatively set manually to an “off” position or to an “on” position will. To set the switching program, a circular program disk 10 is provided which rotates about its axis of rotation 11 , driven by a clockwork (not shown). Sectors 13 with a larger radius, which determine the "on" position of the switch, can be set at will on the circumference of these program disks, as is known per se, by sliding sliding elements, while the inner sectors, as indicated by 12 , set "off" Set the "position of switch 1 .

In addition to the program disk 10 , a feeler lever 20 is pivotally mounted on a circuit board 50 about a fixed bearing journal 51 . The feeler lever is arranged so that a nose 24 formed on the end of the lever scans the program set on the program disk. As the program disk 10 rotates, the feeler lever 20 is raised by running into the "on" sector, the feeler lever 20 pivoting. This pivoting movement is transmitted via a two-armed switching lever 30 to the head of the switching element 2 of the switch, which is pressed in, as shown in FIG. 2. If a free sector "off" 12 again reaches nose 24 when the program disk is rotated, then the levers move back into the "off" position according to FIG. 1, caused by the spring force of a spring in the microswitch.

The shift lever 30 has two arms. It can be pivoted about a pin 44 in its central region. The pin is received by an elongated hole 33 in the shift lever, which extends approximately along the central axis thereof. At one end, the shift lever is articulated to the feeler lever 20 in the area of the nose 24 . At the other end of the switching lever 30 , a head is formed, which presses against the spring-loaded switching element 2 of the switch.

In addition to the shift lever 30 in the region of the elongated hole 33 , an adjusting knob 40 is rotatably mounted about its axis 41 as a changeover device. The mentioned pin 44 , about which the shift lever 30 is pivotable, is located on a radial arm 43 of the control knob. When setting for a programmed circuit, the arm 43 of the adjusting knob is set transversely to the shift lever 30 , the pin 44 being located approximately in the middle of the elongated hole 33 . In this position, the shift lever is held by the pressure of the spring-loaded switching element 2 in the position shown in FIG. 1, in which, in this embodiment, the nose 24 of the feeler lever is close to the smaller disk circumference, and in which the pivot pins 51 , 25 and 44 lie approximately in a straight line. When the nose runs onto the "on" switching sector 13 , the switching lever 30 executes the pivoting movement shown in FIG. 2.

However, if a "hand-off" position without program switching is desired, then the adjusting knob is brought into the position according to FIG. 3, where the short radial arm 43 of the adjusting knob points towards the switch and the pin 44 attached to the arm has the corresponding end position in Elongated hole has reached. In this position, which is determined by a latching, the shift lever is held in such a way that the nose 24 of the feeler lever is lifted off so that the outer sectors of the program disc no longer have any influence on it, the head 36 of the shift lever not affecting that spring-loaded switching element 2 acts, ie either does not touch the switching element or only slightly sits on the switching element.

The position "on" which is independent of the program is shown in FIG. 4. The adjusting knob 40 is rotated so that the arm 43 points towards the program disk, the pin 44 is in the corresponding end position of the elongated hole, the shift lever is held in place, the nose 24 is outside the functional area of the program disk and the shift lever is pivoted so that the head 36 exerts pressure on the spring-loaded switching element 2 so that the switch is turned on.

In Fig. 5 details can be seen of the sensing lever 20, which is a plastic molded part, with a bearing bush 21, a transverse arm 23 to which the nose 24 is formed, and also with an integrally formed hinge pin 25.

Details of the shift lever 30 are shown in FIG. 6. Here too, an articulated sleeve 32 is provided, from which an arm extends, in which the elongated hole 33 is formed. From there extends an arm 34 with a cross arm 35 to which the head 36 is attached, which exerts pressure on the switching element.

The adjusting knob 40 , shown in FIG. 7, has a web or slot 42 on its end face for handling. At the opposite end of the adjusting knob, the axis 41 is formed, as is the radial arm 43 with the pin 44 , which engages in the elongated hole 33 . A resilient tongue 45 is also integrally formed on the adjusting knob in an arrangement parallel to the axis, which, in cooperation with corresponding recesses in the circuit board 50, causes the adjusting knob to latch in the three positions described.

The entire lever system is mounted on a circuit board 50 (see FIG. 8), a bearing journal 51 , which serves as a bearing for the feeler lever 20 , being formed on this circuit board. Likewise, a bore 52 is formed on the board for receiving the axis 41 of the control knob. A recess 53 is formed concentrically to receive the tongue 45 of the adjusting knob. At the edge of this recess, three recesses are formed, into which the tongue 45 engages in order to fix the three settings of the adjusting knob.

FIGS. 9 and 10 show a one-piece sensing lever 60 having a transverse arm 61 on which the nose 62 is formed, and a switching lever 63. The two lever parts are articulated by means of a film hinge 64 .

Claims (3)

1. Time switch with switching mechanism with a program disk, a scanning lever, a switching lever coupled to it for actuating the spring-loaded switching element of a switch and with a changeover device for optional setting by hand to "program", "off" or "on", a push button ( 20 ) is mounted pivotally in an approximately tangential arrangement for the program disc (10) and the sensing lever (30), a switch lever (30) is associated, which is pivotable about in its middle region about a pin (44) as a two-armed lever, one arm of The switching lever is in operative connection with the feeler lever and the other arm ( 34 ) rests at its free end on the spring-loaded switching element ( 2 ) of the switch ( 1 ),
The control lever ( 30 ) is assigned an actuator ( 40 ) which can be set in a locked program position, in which the control lever is freely movable for the programmed switching movements and the actuator ( 40 ) can be set in a locked "off" position, in which the arm ( 34 ) of the shift lever does not act on the spring-loaded switching element ( 2 ) and the adjusting knob ( 40 ) can be set into a locked "on" position in which the arm ( 34 ) of the shift lever engages the spring-loaded switching element ( 2 ) depresses the switch and holds it in the "on" position, characterized in that the feeler lever ( 20 ) and shift lever ( 30 ) are articulated in the area of the nose ( 24 ) of the feeler lever and the arm ( 34 ) of the shift lever has a head at the end ( 36 ), which acts on the spring-loaded switching element ( 2 ) of the switch, that the actuator is an adjusting knob ( 40 ) which rotates in the central region of the switching lever ( 30 ) next to the same ar is mounted on a circuit board and has a radial arm ( 43 ) on which the pin ( 44 ) is formed, about which the shift lever can be pivoted, the pin ( 44 ) being in a central position in the locked program position, in which the nose ( 24 ) of the feeler lever ( 20 ) lies in the area of the circumference of the program disk and the head ( 36 ) of the shift lever rests on the spring-loaded shift element ( 2 ),
the pin ( 44 ) in the locked "off" position is in its switch-side end position, the nose ( 24 ) is lifted off the program disk and the head ( 36 ) of the switching lever does not act on the spring-loaded switching element ( 2 )
and the pin in the locked "on" position assumes the opposite end position, in which the nose ( 24 ) is lifted off the program disk and the head ( 36 ) of the switching lever, the spring-loaded switching element ( 2 ) of the switch in the "on" position. Holds position. 2. Time switch according to claim 1, characterized in that on the circuit board ( 50 ) a concentric to the adjusting button recess ( 53 ) in the form of a sector for receiving the resilient locking element ( 45 ) of the adjusting button is formed, recesses being formed on the edge of the recess , in which the locking element engages. 3. Time switch according to one of claims 1 to 2, characterized by a one-piece feeler lever ( 60 ) consisting of a cross arm ( 61 ) on which the nose ( 62 ) is formed, and a shift lever ( 63 ) which is articulated by a film hinge ( 64 ) are connected.