DE2257725C2 - Timer for an operating device having a drive motor and an electrical energy source for the drive motor - Google Patents

Description

derstand and denoted by 23 and 24 of the base of the transistor 16 upstream resistors.

When the in F i g. 1, the switch S \ of the device JI is turned off, and by operating the switch 18, its movable contact is placed at the contact point e. The capacitors 10 and 11 are charged by the battery E via the drive motor M, the resistor 19 and the diode 12. Since the resistor 19 is designed so that its value in this operating state is sufficiently greater than the impedance of the drive motor Misl, the drive motor M is not put into operation. When the movable contact of the switch 18 is next switched to the contact point /, the first capacitor 11 is charged in the opposite direction by the electrical charge of the second capacitor 10. The length of time during which the capacitor 11 is charged in the opposite direction can be adjusted by changing the resistance value of the resistor 15 '. If the capacitor is charged higher than the base-emitter voltage of the transistor 13 serving as a discharge switch device, the transistor 13 is switched on. As a result, the electrical charge of the second capacitor 10 is discharged via the resistor 14 serving as a discharge resistor, and the transistors 16 and 17 are switched on by the voltage across the resistor 14. As a result, a drive current flows from the battery E through the transistor 17 7 to the drive motor M and rotates it. After a period of time given by the resistor 14 has passed, the discharge of the second capacitor 10 is ended. Then the transistors 16 and 17 are switched non-conductive, and the drive motor M is switched off again and comes to a standstill. 2 shows a circuit diagram of a further embodiment of the timer according to the invention, b and fc 'are socket-shaped end connections for the external connection which is to be connected to the remote control connection of the device to be controlled, for example a camera, etc., to which the timer is to be connected. A switch S% serves as a start switch for the timer. At the time when the timer 1 is put into operation, it is immediately switched from contact D to contact E and back again to contact D. C ₅ is a capacitor (? ₅ is a transistor serving as a discharge switch device, to whose collector the discharge resistors /? Io and Ru are connected in series and to whose base the resistor Rn . Qt, is a transistor which, together with a transistor Q ₇ and resistors R \ _2. Ru, Ru and R \ _{b form} a Schmitt circuit. Rv to Ä20 are resistors. D ₅ is a Zener diode, and Dj and D < are diodes for preventing reverse currents. C _b is a a capacitor for a circuit with Zeitkonsiante. Qe and Qi are b as a motor switch means serving transistors in a Darlington circuit. with · is referred to a light emitting diode.

To start up the device to be controlled, for example a camera, after connecting the external connection b, b ′ to the remote control connection a, a ′ of the device 1, the switch Si is first turned over to the contact E , for example by pressing a button. The capacitor Cs is charged by the battery serving as an energy source in the device H of the camera via the resistor /? I9 and the diode D ₁ . To dk'or time, the capacitor Q is not charged because the current flowing through the diodes Di and D. ₄ On the other hand, since the photographic device II is kept by the value of the resistor R ^ at a value which is lower than the value of the actuation current of the consumer, ie the motor, the device II is not put into operation. The capacitor Cs is through the Zener -Diode D ₅ always charged to a constant electrical potential, even if the voltage of the battery F in the device 11 changes when, for. B. the battery is exhausted

ίο is and supplies a lower voltage.

When the switch S _{5 is} no longer pressed and is thrown to contact D , a charging current flows through the resistors R ^ and R'u to the capacitor Cb, and the charging process is started. The charging process is ended after a period of time corresponding to the Zdt constant, which is given by the product of the capacitance of the capacitor Q and the size of the resistances R \ t and R'm ^; : t. The transistor Q ₇ is controlled by the initial voltage of the resistor R'w generated by the charging current of the capacitor Cb until the charging of the capacitor Q is finished. As a result, the electrical potential of the base of the transistor Qt decreases, whereby the transistor Qt becomes non-conductive. Since no base current flows through the transistor Q ₅ , the transistor <? ₅ non-conductive, and the accumulated electric charge on the capacitor C ₅ is not discharged. On the other hand, when the charging of the capacitor Q, is finished and the transistor Q ₇ becomes non-conductive, the transistor Qf , becomes conductive and the base current of the transistor Q _{5 flows} - In this way the transistor Q ₅ becomes conductive, and the electrical Charge of the capacitor Cs is discharged. As a result, the base current of the transistor Qn flows, and the transistor Qj becomes conductive, whereby the light-emitting diode D ₅ , which was previously switched on, is switched off. Since the transistor Qj becomes conductive, the drive current in the device II flies and the drive motor M is driven, thereby performing, for example, prescribed driving of a shutter and a film. Since the conductive state of the transistor Qt is maintained for a time period corresponding to the time constant which is given by the accumulated electric charge of the capacitor C ₅ flowing through the resistors Rw and Rn , the driving of the drive motor M is continued. After the capacitor C _{5 has been} discharged, the transistors Qg and Q) become non-conductive, as a result of which the drive motor M comes to a standstill.

After the switch S _{5 has returned} from the depressed position and after one of the time constants given by the capacitor Q and the resistors Rm and R'm has elapsed , the Kams: u operates for a further period of time, which is the _{same as that of the capacitor C 5} and the resistances /? io and R [\ correspond to the given time constant. The drive circuit then stops working. The first-mentioned time period can be made variable by the adjustable design of the capacitor Q and the resistor R \ g and the second-mentioned time period can be made variable by the adjustable design of the capacitor C ₅ and the resistor R, o .

1 sheet of drawings

Claims (1)

Claim: Timer for a drive motor (M) and an electrical energy source (E) for the drive motor (AiJ having operating device, with a delay timer circuit, which can be _{put into operation by actuating a switch (18, S 5} ) to set the timer function and after Film take-up reel continuously and the film gripper intermittently drives in front of the film exposure window, there is no wiper rest position corresponding end position. The present invention is therefore based on the object to be as inexpensive as possible to make available a suitable timer that can be used without a the reaching of a predetermined state of charge io such limit switch gets by with a first capacitor (U; C ₆ ) the conductive switching This task is at a generic time encoder solved by the features of claim 1. Dt: timer according to the invention additionally assigns the delay timer circuit an operating time a motor switch device (16, 17; Qg. triggers, characterized in that the timer (1) has an external connection (b, b ') , with which he can connect to a remote control (a, a) 15 transducer sound, which determines the duration of the motor switch-on, the drive motor (M) and the electrical device after the switch-on delay has elapsed. According to the invention (b. b ') and the switch (18; 5s) - by briefly sounding the timer, and by actuating it - from the electrical energy - manages 20 very few components and both kogiequelle (e) chargeable second capacitor (10; stensparend and compact produced is also C ₅₎ is provided, in which a discharge resistor, the timer does not need its own power (14; AE10, R \ i) to be provided for the second capacitor (10; C ₅ ) source, but can rather be inserted with the contained discharge circuit a discharge circuit in the drive motor feeding energy source supplied direction (13; <? ₅ ), which when reached 25, although the timer is a state of charge of the first control predetermined by the camera, a structure that can be attached to the outside of the camera. A capacitor (11; C ₆ ) is switched on and the further advantage of the timer according to the invention is that the motor switching device is switched on in that both the tripping delay function (16, 17; Qs. G) is triggered and the motor switching as well as the molor running time limitation function teinrichtung (16,17; Qt, O ₉ ) when reaching a 30 by briefly pressing a single switch in motion predetermined discharge state of the second capacitor (10; C ₅ ) non-conductive g - ^ is switched. The invention relates to a timer according to the preamble of the patent claim. In the magazine "Electronic Engineering", April 1967, p. 232, a generic timer is described, which is for an interval control circuit Motor vehicle windshield wiper motor is used and is illustrated in FIG. 10. In this known interval control circuit is the switch-on line point of the Wiper motor retarding delay timer circuit is provided which includes a capacitor Ci and resistors Ri and R2. After the Switch-on delay time the windshield wipers are replaceable. The timer according to the invention is thus of simple construction. It can be further developed so that the timer process can be carried out in such a way that either one of repeated operations or an operation and a break can be selected. Through the Invention is a Einheil created for Connection to various types of electrical equipment is suitable. 4C The invention is explained in more detail below with reference to preferred exemplary embodiments and the drawing explained. In this shows 1 shows a sound image of a timer according to the invention and F i g. 2 is a circuit diagram of a further timer according to the invention. In Fig. 1 show 1 a timer circuit of a timer unit and II the circuit diagram of a drive motor and an electrical energy source £ ent- motor is supplied with drive current by firing the thyristor SCRi so that it rotates. As soon as the 50 holding photographic device. The outside wiper seir.e the end position corresponding to the rest position connection b, b 'of the timer I is via lead wires or sleeves connected by a remote control connection a, a ' to the device H of the camera which is to be controlled here. The drive motor M contained in the device II is used to drive a film, shutter, etc. A bat is used as the electrical energy source for the camera has left, a limit switch Sj is closed. As a result, the delay timer circuit is short-circuited so that the capacitor Ci can discharge through the resistor R ₃ , the base-emitter path VT, and the resistor Ri. After the limit switch Sj has been opened again when the windshield wiper end position is reached, the windshield wiper motor can be switched on again after the capacitor Ci has been recharged to the charging voltage corresponding to the switch-on delay. A similar interval circuit is described in the magazine Funkschau 1968, issue 12, p. 376. With these known timers, only the switch-on delay teric. The drive circuit in the camera is connected to a shutter release button. The drive motor M isi can be put into operation by closing a switch S ₁ which is used to switch on the camera, whereby the photographing process begins. This lasts as long as the switch Si is closed. In the timer I shown in Fig. 1 are with are electronically controlled, while for disconnection b5 the reference numerals 10 and 11 capacitors, mn 12 If the windshield wiper motor is used, the end stop hinge must be operated. Hei a camera whose switched on Molor the EneraiMueil * (E.) containing photographic a diode, with 13 a transistor, with 14,15,15 'resistance 16 and 17' Is Mutorschallcrcinrichlimg serving transistors, with 18 a switch, with 19 a Wi-