DE1089691B - Spring clock with electric motor and motor contacts - Google Patents

Description

Electrically windable spring watch with motor contacts The invention refers to a spring watch that can be wound up by an electric motor and Has contacts that are used to switch the motor circuit on and off. Such After the spring has run down, clocks are automatically restored by a certain amount wound by the motor after a fixed angle of rotation of the barrel closing contact is closed so that the electric motor winds the spring, and by opening the motor contact after the spring has been fully wound up. The invention is now primarily intended to meet the contact formation so that that both when switching on and when switching off the electric motor a safe Contacts are self-cleaning. The contact or switching device should thereby be relatively compact.

In the case of electrical clocks, it is particularly important to make good contact to care. Therefore, the formation of an oxide layer at the contact points should be avoided or at least the resulting oxide should be largely removed. The removal of oxides should take place automatically. To achieve this, contact devices are have been developed in which a so-called "self-cleaning" of the contacts takes place. In such devices, a contact member is usually fixed, and the mating contact member is able to move the point of contact on the contact member when contact is made. So it is known to use a leaf spring for making contact, which when switched on comes to rest on a fixed contact piece and until the end of the switch-on process slides along this. The disadvantage of this training is that the one contact member must be formed by a leaf spring, so that with the choice of material for this Contact member primarily on the suspension properties and only second Line on the electrical properties, for example electrical conductivity, Consideration can be given. It is also unfortunate that immediately with the introduction of the contact opening process, the contact pressure between the contact members is reduced will. As a result, when the spring contact is lifted off the fixed mating contact practically no friction of the contact members causing the removal of the oxide instead of. It has such a contact at most when it is switched on, but not a self-cleaning effect when switched off. Hence it can happen that When switching on again, oxidized areas of the contact elements lie on top of one another come what should be avoided.

Switching devices have also become known in which both interacting contact members are rigid. With these wanders during the switching process the one contact member on the other, such that the Points of contact are relocated. In this device is disadvantageous that the The switch-on and switch-off points are at the same contact point. is the switch-on and switch-off point is oxidized by the interruption spark, it is true a nearest point will still be bare, but the oxide will be in the direction of the switch-on transfer.

After all, it is known to plan the formation of the contacts in such a way that that a spatial separation between the switch-off and switch-on point is achieved. For this purpose, both contact parts are designed to be movable. With this facility is a contact washer is provided, which carries a contact pin and a release pin. An arcuate contact piece interacts with the contact pin. The trigger pin is used to operate a locking lever. The arcuate contact piece is on one one-armed lever under the action of a spring attached to the side of the shell the contact disk is pulled too. The contact piece lever has on its free End of a locking pin that can be inserted into a recess in the locking lever. Located If the locking pin is in the recess, then the contact piece lever and thus the arcuate one Contact piece lifted from the contact disk or the contact pin. When walking around of the contact disk, the release pin reaches a protruding in its migration area End of the locking lever and lifts it, causing the locking pin to disengage the recess of the locking lever causes. As a result, the arched one comes Contact piece on the contact pin to the system. This makes contact and switching on of the motor. This in turn causes the contact disc to be contrary to its initial one Direction of rotation is adjusted. When the contact disk is turned back, the contact pin slides along the contact piece. The contact is closed as long as the sliding one Movement between contact piece and contact pin is maintained. It is for that ensured that the contact contact after traversing a certain angular path is interrupted between the contact pin and the contact piece.

The disadvantage of this contact device is that, although an instantaneous Closing, but no momentary opening of the contacts takes place, which is known because of of the opening spark (self-induced voltage) is even more important. aside from that this device can only be used where sliding contacts can be used. However, it is unsuitable if the contact is made through contact pieces is supposed to be relative at most for the duration of the switch-on and switch-off process should move to each other, but are stationary on top of each other in the switched-on state should.

This is where the invention comes in. It enables both a momentary switching results when switching on as well as when switching off. It takes place So the contact contact and the contact separation abruptly. In addition, the Switch-on point separated from switch-off point. It is also used for self-cleaning both when switching on and off. Thereby a contact device used, in which the interacting contact pieces in the switched-on state maintain their relative position to each other.

In order to achieve the desired goal, an electric motor is assumed Wind-up spring clock with motor contacts that can be incremented by a Organ, for example a star wheel, can be actuated. The advancement of the star wheel takes place periodically by a tension spring that revolves with the running or pulled-up tension spring Carrier. The control elements of the contacts, which are designed as snap contacts, can assume at least three different positions. Such kind of contact control, also with snap contacts, but with two connected in parallel, depending on the Position of the control elements can be opened and closed alternately (middle position = Opening of both contacts) are known per se, but very space-consuming and complex construction and without sufficient solution to the task of self-cleaning both when switching on and when switching off. Such a spring watch becomes significant improved according to the invention in that when only a single switch is used forming two contact members this under the action of two preferably different strong springs are, that also of the indexing organ, z. B. the star wheel so designed control member is periodically actuated that after Alblauf one first part of the spring travel, preferably a barrel circumference, from the position of the full winding, preferably under bias on the first contact member acting spring, an intermediate member is brought into an operative position in preparation and after a second part of the spring travel, preferably a second spring barrel circumference, this intermediate member is the second contact member against the now momentary closing movement executive movement of the first contact member moved so that the contact closure a self-cleaning sliding movement of the first contact member on the second contact member takes place, while the switching and control elements are now starting with the spring winding be moved in the opposite direction so that the contacts only after full winding are currently open.

By designing the contact device in this way, a momentary switch-on and momentary switch-off achieved so that the emergence of sparks when switching is largely prevented. There is also the advantage that both when switching on and when switching off both contact members to the Contact points move differently to each other, which is the desired favorable Self-cleaning at the points of contact.

The above-mentioned known contact control with one of a barrel driver actuated star wheel, because here the star wheels, cams, etc. from the barrel Completely separate individual components are also the disadvantage in addition to the space requirement that both the assembly and, above all, in the event of repairs or to replace the ja am heavily stressed contact parts the disassembly is very complicated.

To keep the contact device relatively compact and light To be able to replace it, it is therefore advisable to use a spring watch with the motor contacts, which belong to a switch that can be operated from the star wheel via intermediate elements is, with this itself from a driver on the innerspring shaft in both directions of rotation can be continued, preferably in combination with the first according to the invention Solution, according to the invention, the switch together with the star wheel and the intermediate elements to be mounted on a common base plate so that a structural unit is created, which can be detachably connected to the barrel and after connecting to the latter whose orbital movement also executes, but from the barrel after loosening the connection can be removed and replaced if necessary.

This union of the contacts or the switch together with the intermediate elements and the star wheel to a structural unit not only allows this unit to keep relatively compact, it also allows the switch assembly to be able to manufacture separately from the actual movement. As a result, you can in one case the important aspects in the construction of electrical switches and in In the other case, the aspects that are important for watchmaking are given preference will. The entire unit can, for example, be kept so small that it is at a diameter of 26 mm only has a height of 6 mm. It also results the advantage that to unite the switching unit with the clockwork on the gear or structure of the same no change has to be made.

An expedient development of the invention arises when the A shift fork is assigned to the star wheel, which is driven by a driving pin on the star wheel can be actuated and itself has a pin which extends over an arcuate curve on one end face of a contact member designed as a double lever -zur Forming a stop which determines the amplitude of the double lever interacts.

When winding the clockwork from the motor z. B. the star wheel via the driver on the Spring core shaft with each one full Rotation of this shaft advanced by one tooth. The clockwork spring won't wound up, it rather relaxes, then the barrel revolves, whereby the Star wheel is taken along the spring circulation path. With one full turn at a time of the barrel is the star wheel due to its rolling motion compared to it stationary driver on the innerspring shaft turned back by one switching step. With the progression of the star wheel clockwise or counterclockwise the shift fork is pivoted in one direction or the other. It can be three different Take positions: the first with the spring fully wound, the second approximately against End of the first rotation of the barrel. during the expiration of the spring and the third about the end of the second rotation of the barrel when the spring is running. To The snap-action mechanism is pre-tensioned with the first switching step. At the second switching step the switching mechanism is triggered. So it occurs after every two switching steps of the star wheel either make contact or break contact.

According to another expedient development of the invention, it is also provided to store the shift fork so; that when switched on the motor contacts the unimpeded switching of the star wheel is possible by the drive pin can leave the shift fork, and the star wheel altogether a number of switching steps causing almost a full turn of the star wheel is rotatable, with one leg of the shift fork having a stop for the driver pin forms.

This training allows the barrel when the clockwork spring runs down after the second rotation of the barrel, with closed contacts, keep turning in the same direction if the motor does not work, because, for example, there is no tension. This is possible because the Continuation of the star wheel during the process of the spring of the driver pin Shift fork can leave. Returns before the clockwork spring is completely relaxed the electrical voltage is returned, then the spring core shaft is referred to by the motor of winding the spring rotated, with the star wheel at every full revolution the spring core shaft is turned back by one switching step until finally the The drive pin returns to the fork and after the clockwork spring is fully wound the Interrupting the contacts brings about.

Another advantageous development of the invention is when the counter-contact member cooperating with the double lever contact member as a one-armed Lever is formed, the opposite of the contact of the double lever member at the free end carries the mating contact. It is advisable to keep the mating contact closer to the bearing point of the one-armed lever than the contact on the double lever to its bearing point and to mount the one-armed lever resiliently in such a way that it upon impact of the contact swivel around its bearing point by a small angle and at Peel the contact back into the starting position under the action of its spring can.

The advantages achieved by the aforementioned arrangement are from the following Description of a preferred embodiment of the invention obviously apparent, which is explained with reference to the drawing, namely Fig. 1 shows a section of the switch along the line 1-1 of Fig. 2 in the direction of the arrow, the. counter is attached to the barrel of a clockwork, but the barrel itself is only partially and is shown with an interrupted winding shaft, FIG. 2 the switch in plan view in the switch-off position and when winding is complete, but with the omission of the Winding shaft and the operating finger of the switch attached to it, Fig. 3 a plan view similar to Fig.2 in the position after the barrel during of the sequence-the spring has performed one revolution, with an adjustment of the one of the two contacts of the open switch was caused, Fig. 4 also a plan view similar to FIG. 2, but after the barrel has a has completed another cycle of rotation and the switch has been closed, 5 shows a separate part of the switch, FIG. 6 shows the switch after removal of the part shown in Fig. 5 with other parts omitted, and Fig. Figure 7 is a partial cross-section of the switch mounted on a barrel cover. .

In the figures, 11 denotes the barrel cover on which with the interposition of a disk 12 made of insulating material of the invention Switch is attached so that it can be taken in a rotating motion. In the following description, a preferred way of mounting the switch explained on the barrel cover; in practice any desired type of attachment is used be possible, provided that there is an electrical between the switch and the barrel Isolation exists.

The switch contains a metallic round base plate 13, which is used for free passage of the winding shaft is pierced in the middle and its circumference has a groove 14, the switch also having a metallic one, too O-ring 15 provided with an edge groove 16 has. The two parts 13 and 15 are held parallel and at a distance from an insulating body 17, which essentially is ring-shaped and attached to both of the aforementioned parts, so that the mentioned round parts together with the associated parts an independent one Form unity.

In the groove 14, a brush 18 is supported on one pole Power source is connected, while in the groove 16 another brush 19 is supported, which is connected to one pole of an electric motor 20 while the second pole of the motor is connected to the second pole of the power source.

The winding shaft is denoted by 21, and an insulating sleeve 22 is placed on it, from which a finger 23 protrudes radially. The sleeve 22 must rotate with the winding shaft 21 and thus be appropriately attached to this shaft. A preferred way of holding the shaft 21 and the sleeve 22 tightly together for rotation is to provide some notches 24 on the outer edge of the sleeve 22 and complementary projections 25 on the inner edge of the hub 26 of the gear 27, the latter on the winding shaft 21 by means of a through pin 28 is attached. The sleeve 22 and the hub 26 are thus designed like the two parts of a claw coupling. The gear wheel 27 is connected to the electric motor 20 by means of a low-speed transmission; so that the rotation of the motor 20 causes the rotation of the gear 27, which then - when looking at FIGS. 2 to 6 - moves clockwise.

The finger 23 protruding from the sleeve 22 cooperates with a star wheel 29 which is mounted on a pivot 30 fixed on the plate 13. If the winding shaft 21 stops and the barrel with its cover 11 rotates while the spring is running, the star wheel then also rotates clockwise (see Figs. 2 to 6), by one step equal to the distance between two teeth for each Rotation of the barrel around the shaft 21. Conversely, if the shaft 21 rotates during winding and the barrel practically stops, then the star wheel 29 rotates counterclockwise, but always by one step for each relative rotation of the shaft 21 to the barrel.

In order to precisely determine the positions of the star wheel 29 in the following steps (see preferably Fig. 6), the bent end 31 of a leaf spring 32 bent around the screw 33 fastened on the plate 13 in the manner of a hairpin is against the teeth of the star wheel 29 arranged acting as a pawl, the legs 32a of which are supported against the surface 34 of the insulating body 17. From this it can be seen immediately that the installation of the spring 32 is very simple. The bent end 31 of the spring 32 protrudes partially into the space between two teeth of the star wheel 29, and it is easy to understand that during the first part of each step of the star wheel 29 occurs at a speed which depends on the speed of the relative movement between the finger 23 and the barrel is dependent, the second part of the step mentioned takes place in leaps and bounds by the action of the spring 31-32.

A pin 35 protrudes at right angles from the star wheel 29 and controls a partially fork-shaped part 36. This part 36, hereinafter referred to as “fork” for short, is pivotable about the pin 37 carried by the plate 13. The fork 36 should not have an electrically conductive function, and it can therefore consist of insulating material.

The positions assumed by the fork 36 under the control of the pin 35 will now be considered.

When the spring is fully wound, there are fork 36 and the pin 35 in the position shown in Fig. 2, in which the pin 35 of both Legs of the fork has a distance. When the star wheel 29 moves one step turns clockwise because the barrel almost one turn when the spring runs out around the winding shaft 21, the pin 35 strikes the inner arm (in Figs. 2 to 6) and forces the fork to assume the position shown in Fig. 3, whereby the fork - as explained below - adjusts one of the contacts of the switch. In a second step of the star wheel 29, the pin hits the inner one again Arm of the fork 36, this rotates into the position shown in FIG. 4 and therefore causes closing the switch. The following circuit is then closed: on Power source pole, brush 18, ring 13, carrier 60, two-armed lever 52, angled End 51 of lever 52, contact 50, angled part 40 of arm 41, arm 41, Ring 15, brush 19, motor 20, second power source pole.

-_ As soon as the current flows, the winding shaft 21 is driven, what the gradual rotation of the star wheel 29 counterclockwise with the result has the consequence that the penultimate step of the star wheel in this In the direction of the pin 35, the fork 36 does not move at all or only very little, which means During this process the contacts remain closed, while during the last step of the star wheel, the pin by pushing against the outer arm of the fork 36, this forces to go back to the position shown in FIG. 2, and thus the switch opens.

If on the other hand, z. B. due to a power failure in the network, no current flows, the star wheel 29, as can be seen from Fig. 4, its gradual movement in Continue clockwise without being hindered by the pin 35 while the switch remains closed to effect winding when the current returns. This clockwise movement of the star wheel can continue until the pin dies position shown with a dotted circle, d. H. the starting position, taken Has.

The fork 36 acts on both contacts of the switch according to the invention, one of these contacts being electrically connected to the plate 13 and the other to the ring 15.

This Ririg 15 is on the insulating body 17 by means of holes 39 of the ring 15 going screws 38 fastened, which in corresponding with threads provided bores of said insulating body 17 are screwed. The contact, which is in electrical connection with the ring 15 and denoted by 40 consists - as can be better seen from FIG. 5 - from a bent at right angles Part of a metallic arm 41, which around a pin carried by the ring 15 42 can pivot; the metallic arm 41 is in contact with the metallic one Ring 15. This arm 41 carries a pin 43 against which one end of a bent around the pin 42 and anchored to a pin 45 attached to the ring 15 Leaf spring 44 supports, the pin 45 through a bore provided in the arm 41 46 goes. The pin 45 limits the freedom of movement of the arm 41. The spring 44 thus strives to rotate the arm 41 in the direction shown by the arrow in FIG to set, but the end position of the arm in this direction is from the stop of the pin 45 with the right edge of the bore 46 (Fig. 2 and 5) is determined.

As can be seen from Fig. 2, the pin 43 also goes through the elongated hole 49 provided in a small insulating rod 47, the insulating rod is arranged pivotably about the pin 48 carried by the fork 36. In the position of the switch according to FIG. 2, the pin 43 is located approximately in the middle of the elongated hole 49. But if the fork is moved from the position shown in FIG. 2 to the position shown in FIG. 3 passes, then the pin 48 of the small rod 47 rotates together with the Fork 36 around the pin 37 of this fork, i. i.e., it approaches the line which connects the axes of the pins 37 and 43, thus pushing the small rod 47 To the right. When moving the rod 47 the first distance is on the pin 43 ineffective. But if the end of the elongated hole touches the pin 43, then -forces the rod 47 the arm 41 to move against the action of its spring 44, and in the opposite sense of the arrow in Fig. 5. This is therefore very important, because it serves to lead the contact 40 against the position it is when it is closed Switch assumes (see. Fig. 4), when pushed by the other contact 50 to there will. One must bear in mind that if the contact 40 is a completely tight fit would have, the contact 50, which during the closing movement bumps against him, could impact, vibrate and cause sparks, which inevitably should be avoided, especially if you have an electric motor connected to the mains want to use without a voltage transformer.

If the contact 40 the impact of the contact 50 in its in Fig. 2 would wait for the position shown, then this shock would take place when the called contact 50 is still moving at low speed, so that it is too bad contacts and sparking could occur.

If the arm 41 is only used to pivot between the position of FIG. 4 and from FIG. 3 would be attached, then the separation of the contacts 40 and 50 when the switch is opened, as soon as the latter moves at low speed moved so that the shutdown would not take place instantaneously as necessary is to avoid the sparks due to the extra opening current are.

If the fork 36 returns from the position according to FIG. 4 to the position according to FIG therefore stops because the contact 50 pressing on it is held in place by a spring lock, as will be explained in more detail below.

The mentioned contact 50 consists of one piece, which to a at right angles bent part 51 of one arm of a two-armed lever 52- attached which is pivotally mounted at 53. It should be noted that the pin 53 of the lever 52 is in electrical communication with the plate 13.

The end 54 of the two-armed lever 52, which is opposite to the the arm carrying the contact 50 is formed with a circular edge, that the pin 37 on which the fork 36 is mounted, the possibility of pivoting of the two-armed lever 52 is limited by its pin 53.

In addition, the two-armed lever 52 is provided with a bore 55, through which a pin 56 attached to the fork 36 passes: This is therefore very much important because in the event that the lever 52 when pivoting the fork 36 is not under the action of other resilient means, which are explained below, pivots, the same lever by the push of the pin 56 against one side or the other (depending on the pivoting direction of the fork) of the bore edge 55 for pivoting is forced. The two-armed lever 52 also has a bore 57 for receiving a small ball 58, for which two seats are provided, but of which only one, denoted by 59, can be seen in Figure 6; both seats are in that metallic carrier 60 of the pin 53 is provided, this with the plate 13 is in an electrically conductive connection. The other seat for the ball 58 is from Lever 52 covered. The ball 58 is under the action of a spring which strives is to push them into one seat or the other and hold them there.

It should be noted that according to .a. Appropriate height of the carrier 60 of the two-armed lever 52 essentially in the plane of the 40-bearing den.Kontakt Arm 41 lies: The lever 52 has another part bent at right angles 61, in which a -bore visible in FIG. 1 is provided, through which -ein Pin 62 goes around which a coil spring 63 under pressure is arranged. The opposite end of the pin 62 protruding beyond the part 61 is on a small plate 64 attached, the edge 65 having a recess against the pin 56 attached to the fork 36.

As can be seen from Fig. 1, the spring 63 is almost in contact with the Ball 58 when it is in one of its seats. When the ball 58 is out of its Seat goes out, it causes a deformation of the spring 63, and this presses the ball 58 to push them against the carrier 60 so that they are at the right moment goes into the other seat. It is necessary that the inside diameter the spring 63 is suitably greater than the strength of the pin 62 so that the The escape of the ball 58 from its seat is not prevented. Tests have shown that safe operation is achieved when the depth of the recesses for the ball 58 is at most equal to the radius of the ball.

The following is explained; as the pivoting of the fork 36 is the movement of the two-armed lever 52 and thus of the contact 50 causes.

Both in the position according to FIG. 2 and in the position according to FIG In Fig. 3, the axis of the pin 56 is to the right of the line that defines the axis the pin 37 and 53 connects so that the force of the spring 63 has a component which endeavors to rotate the lever 52 counterclockwise (see. Fig. 2 to 6). The lever 52 cannot move because it is held in place by the impact of the edge 54 with the pin 37. But if the fork 36 is out of the position according to Fig. 3 moves to the position shown in Fig. 4 as soon as the pin 56 crosses the line, which connects the axes of the pins 37 and 53, the force of the spring 63 has a Component that tries to pivot the two-armed lever clockwise; the size of the force component increases accordingly, the more the fork is the position according to FIG. 4 approaches. But because of the locking ball 58, the lever 52 only swivel when the force component has reached a higher size, d. H. the Fork 36 is in the vicinity of the position shown in FIG. 4, or when it is the same. has enough. Therefore, the pivoting of the lever 52 takes place by means of an increased Power, so suddenly. The pivoting is due to the collapse of the ball 58 limited in the other of its two seats as well as by the collision of the Edge 54 of the lever 52 with the pin 37. If the size of the force component mentioned in the above-mentioned process is not sufficient to the locking effect of the 'ball 58 to overcome. Then the pin 56 forces when hitting against the left edge of the hole 55 the lever 52 to move as shown above.

The process is similar when pulling it up. In the position according to Fig. 4, the force of the spring 63 has a component tending to the two-armed Lever to pivot clockwise, but the lever is similar to how previously stated, recorded. When the fork is in the position shown in Fig.2 moves, the size of the force component decreases to zero when the axes of pin 56 and tenons 53 and 57 are in a straight line. In the next Movement - the fork 36, the force of the spring 63 has a component; which strives is to pivot the two-armed lever 52 counterclockwise: The size the force component increases accordingly, the more the fork moves into the position 2 approaches. But the lever 52 can only pivot when the magnitude-of-force component the Locking effect of the ball 58 overcomes or when the pin 56 against the right edge the hole 55 abuts. In this case, too, the lever is pivoted 52 practically suddenly. Because of the fact that the coupling is between the rod 47 and the arm 41 is carried out by the pin 43 and the elongated hole 49, moved the arm 41 with the two-armed lever during part of its pivoting, and the contacts only open when the lever 52 is at an increased speed. So the switch opens momentarily to avoid sparking.

The two-armed lever 52 is in an electrically conductive connection with the carrier 60 not only via the pin 53, but also in that its lower surface rests on the carrier 60, which in turn is in an electrically conductive connection with the plate 13.

3 and 4, taking into account the fact that the distance of the contact 50 to the pin 53 is significantly shorter than the distance of the contact 40 to the pin 42, it can be seen that the corresponding surfaces of the contacts 20 and 50 between the times of Contact and closed end position perform a mutual sliding movement in order to keep the surfaces clean. Mutual sliding movement of the surfaces of the contacts 40 and 50 also occurs upon opening.

7 shows a preferred type of fastening of the switch on the cover of the spring housing. From this figure it can be seen that annular recesses 71 and 72 are provided on both sides of this cover, which are arranged concentrically to the axis of the spring housing and are connected via bores 73. A suitable insulating material is applied to the cover so that the recesses 71 and 72 and the bores 73 are filled with part of the insulating compound 74 and a cylindrical projection 75 is formed on the outside of the cover 11. This projection has a hole in its center for the winding shaft to pass through. This projection also has a thread 76. The central bore of the plate 13 is provided with a corresponding thread so that the switch is fastened to the cover 11 by screwing it on with the insulating washer 12 interposed. It is useful that the thread 76 has a direction opposite to the direction of rotation of the spring housing, but is not an absolute requirement, since the only unintentional force that could endeavor to unscrew the switch is that of the finger 23 against the tips of the star wheel 29 is, the extent of this effect in comparison to the friction of the insulating washer 12 against the cover 11 and against the plate 13 can be completely neglected.

To effect the first opening, the switch is in the closed position brought with the pin 35 of the star wheel 29 in the dotted circle in Fig. 4, and then let the current flow.

It is recommended to set the speed for full winding of the spring of the clockwork is at least the same, but preferably higher than the number of tips of the star wheel 29 to choose.

Claims (10)

PATENT CLAIMS: 1. Electromotive windable spring clock with motor contacts, which by a step-by-step progress = switchable organ, z. B. a star wheel, actuatable are which organ in turn by one with the expiring or raised Tension spring revolving driver is periodically indexable, with at least three different positions of the control elements for those designed as jump contacts Contacts are possible, characterized in that when using only one two contact members forming a single switch, these under the action of two, preferably different strong springs are, that also from the indexing element, z. B. the star wheel, a control member designed in this way can be actuated periodically, that after a first part of the spring travel, preferably a barrel circumference, from the fully wound position, preferably under tension on the first Contact member acting spring, an intermediate member preparatory in an operative position is brought and after a second part of the spring travel, preferably one second barrel circumference, this intermediate member against the second contact member the movement of the first contact member that now momentarily executes the closing movement moved so that when the contact closes a self-cleaning sliding movement of the first Contact member takes place on the second contact member, while the now starting Spring winding the switching and control elements are moved in the opposite direction so that that the contacts are only opened at the moment when it is fully opened. 2. Electromotive Wind-up spring clock with motor contacts that belong to a switch that is below Use of intermediate elements and a star wheel can be actuated, this advanced by a driver on the innerspring shaft in both directions of rotation can be, in particular according to claim 1, characterized in that the switch together with the star wheel and the intermediate elements one mounted on a base plate forms a structural unit which can be releasably connected to the barrel in such a way that after the connection with the latter, it executes its orbital movement with and after Loosening the connection from the barrel can be removed and, if necessary, exchanged. 3. Spring clock according to claim 1 or 2, characterized in that the star wheel (29) a shift fork (36) is assigned, which is driven by a driving pin (35) on the star wheel can be actuated and itself has a pin (37) which extends over an arcuate Curve (54) on one end face of the one designed as a double lever (52) Contact member to form a swing amplitude of the double lever (52) determining Stop interacts. 4. Spring watch according to claim 3, characterized by a such storage of the shift fork (36) that in the switched-on state of the motor contacts the unhindered advancement of the star wheel (29) is possible by the driver pin (35) leaves the shift fork (36) and a total of almost a full turn of the star wheel (29) causing the number of switching steps can be rotated, the one leg of the shift fork (36) forms a stop for the driver pin (35). . 5. Spring watch according to claim 3 or 4, characterized in that the with the double lever contact member (52) cooperating mating contact member as one-armed, under effect a spring (44) standing lever (41) is formed, the stroke of which by a stop (45,46) is limited and that at the free end opposite the contact (50) of the double lever contact member (52) carries the mating contact (40). 6. spring watch according to one of claims 3 to 5, characterized in that the contact (50) on the double lever (52) from its bearing point (53) has a smaller distance than the mating contact (40) from its bearing point (42). 7. Spring watch according to one of claims 3 to 6, characterized in that the double lever contact member (52, 50) forms part of a spring mechanism with tilt release by a transverse part (61) at the end of the double lever (52) facing away from the curve (54) ) is provided, which is penetrated freely by a pin (62) on a plate (64) which, on the side facing away from the pin, interacts with a driver pin (56) attached to the shift fork, which has a bore (55) of the double lever ( 52) freely penetrated, with a pretensioned helical spring (63) surrounding the pin (62) between the transverse part (61) and plate (64) and the arrangement is such that when the star wheel is advanced by one switching step, the plate (64) with the Pin (62) is brought into the release position and when the star wheel (29) is indexed to release, in which case the double lever (52) jumps from its one end position into its other end position. B. Spring watch based on one of the Claims 1 to 7, characterized in that the double lever (52) in the area of his Contact (50) is assigned a ball ratchet which determines its end positions. 9. spring watch according to one of claims 1 to 8, characterized in that the barrel cover a pin (75) made of insulating material with an external thread is provided, onto which the base plate (13) carrying the switch parts can be screwed. 10. Spring clock according to one of claims 3 to 9, characterized in that the driver (23) for the star wheel (29) with the interposition of an insulating sleeve (22) is attached to the spring core shaft (21), the insulating sleeve (22) at the same time forms a member of a claw coupling, the counter member of which is formed by the hub (26) of a gear (27) which is fastened to the spring core shaft (21) and can be driven by the motor (20). Considered publications: German Patent Specifications Nos. 422 304, 593 546, 557791.