DE2325553A1 - TIMER - Google Patents

Description

Time switch The present invention relates to a time switch having a or several circumferential, equipped with radially disengageable switching elements Switching disk (s).

The time switches of this type known up to now have the big one Advantage that their switching elements cannot be lost with the switching disk (s) are united into one unit. You can move radially into an inner or outer detent position Another advantage is that they are next to each other in the outer locking position lying switching elements practically form self-contained switching segments, which the operationally connected switching contact via their by moving the switching elements Hold the length in the switch-on position, preselectable in steps. The transmission of motion between the switching elements and the switching contact is simplified because the at the previously mainly common time switch designs between the switching on and off processes (first tab causes switching on, the second switching off, the third activation, etc.) is not applicable.

A special feature of the time switches with radially disengageable switching elements however, it is the action of the full contact actuation force on the circumference of the switching lever also in the radial direction of force, which mainly leads to the following two disadvantages leads: 1) The force necessary for the contact confirmation acts in a more outward direction Position of the switching elements in the radial direction and therefore fully on their Rasterization, which has been designed to be very strong in the design that has been customary since then got to. The relatively small switching elements can therefore only be operated with a high Move effort from one to the other locking position. The occurring Forces can also cause the elastic limit of the material to be exceeded used plastic and therefore to their circuit inaccuracies.

In another design, this deficiency is compensated for by axial displacement the switching elements encountered, so that the direction of the contact actuation force no longer coincides with the direction of displacement of the switching elements.

The main disadvantage of this arrangement, however, is that the switching elements in the actuating position in plan view of the switching disk bad of the switching elements are to be distinguished in the rest position. Furthermore, in this embodiment, the Switching element arrangement in connection with the switching disk so much depth to claim that two switching disks on a common axis can usually not be accommodated are.

2) Another consequence of the fully drawn shift elements acting contact actuation force is the relatively high load of the the switching disk (s) driving work.

This must, provided it is a movement with a mechanical power reserve is, for this reason, equipped with a powerful, large spring force storage device which is in direct contradiction to the endeavor for the smallest possible timer designs with the highest possible contact load capacity. There is therefore a real need after a timer equipped with radially displaceable switching elements, which with low actuation force contacts with high switching capacity and high contact pressure able to switch, and their switching elements nevertheless easily differ from one let move into the other locking position, an inventive goal that the construction of operationally reliable time switches with a small volume, high switching capacity and sufficient, mechanical power reserve facilitated.

According to the present invention this object is achieved in that a compensation spring alone or several compensation springs together to counteract Actuating force of the switching contact acting on the output torque of the drive mechanism so compensated (compensate) that as the output inhibiting on the drive mechanism The remaining force is only the difference between the force of the compensation spring (s) and the actuation force of the switching contact remains and / or that the direct power flow between the Switching contact and the drive mechanism, arranged on the circumference of the switching disk (s), Shifting elements moved radially into the outer detent position with one only in an axial position Direction unlockable locking device cooperate and that of the in outer Position shifted switching elements to be overcome residual force due to their position of the point of application has the effect of increasing the rest force.

Through a meaningful further development of the invention, the Equipping the switching disks with switching elements simplified, all of which are radial from fed in from the outside, inserted into the guide grooves and locked in place, a ring finally drawn over the circumference of the switching disk paves the way for the Switching elements limited to the outside.

Further, as a consistent perfection of the invention, one is separated Programmable day or half day deactivation of the switching contact is important, the purpose of which is to program the switching disk on any whole day or half days of the week inoperative, so that the switching contact is independent Can be preprogrammed by the indexing disc program, remains switched off for a limited period of time. The advantage over known solutions also lies in this additional device in their low power requirement, which does not put additional strain on the drive mechanism and also has the great advantage of instantaneous switching.

Using FIGS. 1-7, an exemplary embodiment of the Invention described.

Figure 1 illustrates the transfer of motion of the disengaged Switching elements on the circumference of the switching disk on the switching contact.

Figure 2 shows an enlarged switching element, Figure 3 the insertion the switching elements in the radial guide grooves of the two firmly connected Switching disk halves, as well as pulling on the stop ring after loading with switching elements.

FIG. 4 shows the enlarged partial section A-B between two guide grooves in the radial direction, Figure 5A shows a similar partial section with inserted Switching element in disengaged state. In contrast to Figure 4 is the selected one Cutting plane on both sides in the middle of the guide groove.

Figure 5S shows the unlocking of a switching element in the axial direction before being pushed into the inner locking position which is shown in FIG. 5C.

Figure 6 symbolizes the preprogrammable, the switching disk programming superior Locking of switching contact actuation on any days or half days of the Week.

FIG. 7 shows a modified embodiment of this day or half day switch-off with additional manual locking option.

The rotatably mounted switching disc 1 is via a gear reduction driven in a known manner by a clockwork (not shown) and rotates once in twenty-four hours. As can be seen from Figure 3, it consists of of two guide disks 2 and 3, which are firmly connected to one another via a hub 4 are. There are radially extending guide grooves on their flat sides facing one another 5 incorporated, which face each other in pairs and the recording and leadership the switching elements shown in Figure 2 are used.

The guide grooves 5 of the guide disk 3, which is smaller in scope, are cut at right angles by a circular groove 6 in the vicinity of the circumference (see FIG. 4). Of the The cross section of this circular groove 6 is the shape of the locking lugs 7 shown in FIG Switching elements adapted. Their U-shape gives the switching elements a high degree of elasticity in the direction of C-D. A guide web 8 each runs in the middle of their narrow sides and 9, the dimensions of which are matched to the guide grooves 5. During the back Guide bar 8 runs over the entire length, the front goes above in a hook-shaped trained approach 10 over.

Below the approach 10, the front guide web 9 is on both sides each flanked by a locking lug 7. The switching disk 1 is in the following way with Fitted switching elements: In each of the opposing pairs of guide grooves 5-5, one switching element is pushed in radially from the outside, as shown in FIG. the path through the stop of the locking lugs 7 on the circumference of the guide disk 3 is limited. This is the stop position corresponding to the outer detent position shown in Figure 5A.

To move the switching elements from the outer to the inner, in Figure 5C To be able to move the locking position shown, is an unlocking of the switching segments according to Figure 5 8 necessary. The unlocking path corresponds to the width of the U-shaped Switching elements cutout 12 and is dimensioned so that the elastic limit of the Material is not exceeded. In the switching element position shown in Figure 5B do the locking lugs 7 in connection with the circumference of the guide disk 3 no locking function more off so that the switching elements then in the radial direction, that is can be pushed inwards.

In the inner latching position shown in FIG. 5C, the locking lugs latch 7 in circular groove 6.

After the switching disk 1 has been fully equipped with switching elements Finally, a stop ring labeled 11 is placed over the guide disc 2 dared or blown up. The radial feed option of the switching elements facilitates a partially or fully automatic assembly.

The combined with the switching disk 1 and stop ring 11 to form a unit Switching elements can be switched from one to the other in the manner already described other locking position can be moved.

The characteristic of this approach is that for manual shifting the switching elements low power requirement on the one hand and theoretically on the other hand infinitely high counterforce, which the grid described in the outer detent position opposed to the actuating force of the switch contact (see arrow direction Fig.5A). The security against unintentional pushing back from the outer to the inner Locking position of the switching elements during the switching contact actuation is therefore very high.

The actuation of the switching contact is described below with reference to FIG 17 described. The pivotably mounted feeler lever 18 is controlled by the compensation spring 20 pulled against stop pin 22. The shift lever, which is also pivoted 19 connects the switching contact 17 with the push button lever 18o The actuating nipple of the Switching contact 17 exerts a right-turning moment on the switching lever 19 in height the actuating force, which is generated by resting on the left lever arm of the two-armed Sensing lever 18 is transferred to this and reversed into a counterclockwise moment The strength of the compensation spring 20 is such that the actuating force of the switch contact 17 is not only canceled, but slightly overcompensated. The compensation spring 20 therefore holds the nipple of the switching contact A in the rest position when pushed in.

The touch pad 21 of the touch lever 20 protrudes into the path of the switching elements.

The scanning plane roughly coincides with that shown in FIG. 5A and arrow labeled 14. The switching elements in the disengaged position 16 (Fig1) form an almost closed switching segment, which when rotated the shift knob 1 clockwise the Nose 21 depending on the time increases over a time limited by the length of the switching segment. This one on the left rotating moment of the feeler lever 18 follows the shift lever 19 under the action of about the switching nipple transmitted actuating force of the designed as a changeover switch Switching contact 17, which jumps abruptly into its opposite switching position. After the switch-on time preselected by the number of disengaged switching elements the feeler lever t8, the switch lever 19 and the switch contact jumps back in return to the starting position shown. The half-day switch-off device shown in FIG works with little effort. It is further characterized in that the Locking of the switching function suddenly and precisely (usually 12 o'clock midday and midnight) and also not in a "floating" switching process intervenes, but the command to lock the switching function until after switching off caches and tracks the locking, a property common to many Use cases is advantageous.

The device works as follows: The switching disk 1 carries on the back two shifting pins 23 offset by 180 degrees, which are about a switching nose 24 a lift the day shift lever 24 twice a day and under release the action of a tension spring 29 jerkily. This switching movement is over Transfer pawl 25 to the half-day star switch 27, which has 14 teeth provided - rotates by a fourteenth of its circumference per switching operation. An Indian Stationary stop pin 30 lying on the path of the pawl 25 prevents known Kind of an overturning, the pawl 26 a reverse rotation of the half-day star switch 27 at the stroke of the pawl 25. The pawl is on the day shift lever 24 25 hinged. It is designed as a two-armed angle lever and is operated by the tension spring 29 held in the engaged position.

The tension spring 29 simultaneously pulls the day shift lever 24 downwards.

A stop pin 33 limits the switching path upwards. The half-day switch star 27 has fourteen threaded holes evenly distributed on a central circular path 28 equipped, which are used to accommodate switching pins of the bskknnter design. The not shown, screwed switch pins protrude into the path of the two-armed Locking Lever 31 Your job is to use the locking lever 31 To swivel to the right over its slideway 34 as a function of time and into one position to bring, in which the corresponding switch pin a left turn of the locking lever 31 safely prevented (contact of the switching pin on locking surface 35).

In the rest position, the scanning lever 18 rests on the stop pin 22, the switching lever 19 is pivoted up and holds the nipple of the switching contact 17 in the engaged position Position so that the left end of the two-armed locking lever 31 is relieved is, which oscillates loosely between the stop pins 32 as a result. In rest position, the corresponds to the switched-off state of the switch contact 17, is therefore for the No force required to lock.

However, if the switching contact 17 is in the switch-on position shown, its effective contact actuation force on the nipple via the switching lever 19 becomes full transferred to the left lever end of the locking lever 31. The tension spring 29 would be too weak in the position shown, the locking lever 31 over the half-day switch star 27 to pivot with the screwed-in switch pin.

This movement would initially start when the switch pin stops Slideway 34 end and would only after the touch lever 18 has dropped from the last one of the disengaged switching elements 16 completed.

The tension spring 29 takes over in this assumed, not shown State the function of the lift mechanism. If this is very safe and with little Intermediate storage of the locking process, which requires effort, is not desired should be, i.e. a momentary switching effective regardless of the switch contact position is required, this can be done by means of a second, between shift lever 19 and a Fixed spring suspension pin suspended compensation spring 37 can be achieved (see Figure 7).

In this modified embodiment, the is used for overcompensation the actuation pressure of switch contact 17 required force on the two Compensation springs 20 and 37 distributed. The force of the compensation spring 37 is dimensioned so that they do not fully control the actuation pressure of the switch contact 17 cancels and the overcompensation only through the additional action of the compensation spring 20 entry.

The counterclockwise moment on locking lever 31 therefore corresponds to the difference between the actuation force of the switch contact 17 and the force the compensation spring 37. The tension spring 29 is 90 tuned that it provides the resistance one in the half-day star switch 27 screwed in switch pin able to overcome sliding surface 34 and therefore the locking lever 31 to the right can pivot, so that the lock in one go regardless of the contact position and programming of the switching disk 1 takes place.

In Figure 7, another possibility is also shown, such as the locking can also be carried out manually at a higher level than the program. Above the right A rotatable bolt 39 is arranged on the lever arm of the locking lever 31, which is held in the rest position shown by a detent spring 40. For locking this bolt 39 is rotated to the right, which engages with its tip in notch 41 and subsequently prevents any automatic switching process.

Without leaving the inventive idea, instead of the Embodiment selected as a switching contact microswitch a different type Current closing device, for example a 4ueck silver interrupter, can be used.

Also in the execution of the switching elements rasterization and guidance are Variants differing from the exemplary embodiment with the features of the present Invention possible. For example, the switching elements can be in an open at the bottom Be formed in a U-shape and one on both flat sides with guide slots provided carrier disk are guided and carried, the switching segments on their insides each have a guide bar and a locking nose on one inside must have.

Claims (16)

Claims 9 Time switch with one or more revolving, with radially disengageable Switching disk (s) equipped with switching elements, characterized in that one Compensation spring (20) alone or several compensation springs (20, 37) together the actuating force of the switching contact acting against the output torque of the drive mechanism (17) so compensated (compensate) that as the drift inhibiting on the drive mechanism Remaining force only the difference between the force of the compensation spring (s) (20,37) and the actuating force of the switching contact (17) remains and / or that the direct Power flow between the switching contact (17) and the drive mechanism lying on the circumference the switching disk (s) (1) arranged, moved radially into the outer detent position Switching elements (16) with a locking device that can only be unlocked in the axial direction (7.3) cooperate and that of the switching elements moved into the outer position (16) residual force to be overcome by their position of the point of application (arrow 14) increasing the locking force affects. 2) time switch according to claim 1, characterized in that the switching contact (17) as a result of the on the circumference of the switching disk (s) (1) in the inner locking position engaged ineffective switching elements that of the effective direction of the switching contact restoring force adopts the opposite switching position. 3) time switch according to claim 1 and 2, characterized in that the Movement of the switching disk (s) (1) as the circumference of the switching disk changes a lever system consisting of at least one scanning lever (18) on the switching contact (17) is transferred. 4) time switch according to claim 1, 2 and 3, characterized in that a microswitch of conventional design is used as the switching contact (17). 5) time switch according to claim 1, characterized in that the switch disk circumference arranged switching elements (16) have one or more locking lugs (7) and are resiliently designed so that the restoring force resulting from the spring action acts in the direction of the locking lugs (7). 6) timer according to claim 1 and 5, characterized in that the Switching elements (16) having the shape of a U open at the top 7) Time switch according to claims 1, 5 and 6, characterized in that on both outer A guide web (8, 9) is incorporated into the narrow sides of the U-shaped switching elements is. 8) time switch according to claim 1,5,6 and 7, characterized in that the switching disk (s) (1) consists of two connected to one another via a common hub (4), Circular guide disks (2,3) lying plane-parallel to one another at a distance exists (exist), on the facing plan sides of which are opposite, incorporated radially extending guide grooves (5) to accommodate the switching elements (16) are. 9) time switch according to claim 1 and 5, characterized in that the Locking lugs (7) of the switching elements in the disengaged position with the circumference of the switching disk (1) or with the circumference of a switching disk part (guide disk 3) a ratchet form. 10) Time switch according to claim 1, characterized in that a stop ring (11) the path of the switching elements (16) arranged on the circumference of the switching disk to the outside limited. 11) time switch according to claim 1,5 and 8, characterized in that the guide disc (3) facing the locking lugs (7) of the switching elements (16) Circular groove (6) for receiving the locking lugs (7) of the switching elements in the engaged Condition. 12) timer according to claim 1, characterized in that with the Movement of the switching disk (1) by means of a switching pin (23) or several Shift pins (23), as well as by means of a lever system (Tagas shift lever 24) a Spring (tension spring 29) is tensioned, the stored force of which depends on the Sehaltseheiben-Winkelweges is released abruptly for the purpose, a ratchet wheel (Half-day star switch 27) to advance one division. 13) time switch according to claim 1 and 12, characterized in that the ratchet wheel transported as a function of the angular path of the indexing disk (1) (Half-day switch star 27) Bores for receiving switch pins (threaded bores 28). 14) time switch according to claim 1,12 and 13, characterized in that which are screwed into the threaded bores (28) of the ratchet wheel (half-day star gear 27) Switch pins the way of the Switch contact (17) in the switch-on position locks via a lever system (locking lever 31). 15) time switch according to claim 1,12,13 and 14, characterized in that that the switching contact (17) is locked in such a way that its restoring force approximately in the direction of the fulcrum of the depending on the Schaltscheiban-Winkeluegas transported ratchet wheel (half-day switches 27) acts and therefore not retroactive Torque exerts on this ratchet. 16) time switch according to claim 1,12,1314 and 15, characterized in that that the force required for the actuation force of the switching contact (17) is reduced to two Compensation springs (20, 3?) Is divided, with one of the compensation springs (37) the restoring force of the Switching contact (17) almost, but not yet completely, cancels, while the second, with the scanning lever (18) cooperating compensation spring (20) the residual force to cancel the switching contact restoring force.