SE430438B - Overload protection for a filmstrip projector - Google Patents

Abstract

The invention relates to an overload protection for a filmstrip projector. A commonly occurring problem with such projectors is that faults in the picture-changing process, for example that a picture sticks, mean that the picture-changing motor 10 continues to work and thereby runs the risk of overheating. The invention intends to solve this problem, this being carried out by a device 26, 28 arranged on a shaft 24 driven by the motor 10 continuing an electronic time circuit, for example an RC circuit 38, 40 synchronized with the commencement of the picture change. When the picture change has been completed, the time circuit returns to its initial state. However, if the picture change should not work normally, after a certain predetermined period of time, which exceeds the time of a normally operating picture change, the time circuit will control a transistor switch 48 which thereupon breaks the motor current by switching off a relay 18. <IMAGE>

Description

15 20 25 30 35 HO 8205554-2 transistor US. When an image exchange process is to be initiated, the operator depresses a manually actuable switch SU, whereby the relay 12 pulls. The motor 10 thereby receives current via the relay contact 1H, and when the shaft 24 has turned 100, the switch 30 switches so that the relay 12 has self-holding over its contact 20, the switch 30 and the conducting transistor H8. At the same time, the capacitor HO begins to be charged via the resistor 38. If the picture change proceeds normally, the switch 30 returns at the angular position 3500 of the shaft 24 to its shown position, whereby the self-holding of the relay 12 ceases, so that the motor current supplied via the relay contact 14 is interrupted.

The RC circuit É8, 40 is dimensioned so that the charging time of the capacitor with e.g. three seconds exceeds the time for a picture change, so the transistor H8 remains conductive during a normal picture change process. However, should the image switch not function normally without the shaft 24 getting stuck for some reason (eg due to incorrect slide and / or magazine), the switch 30 will not return to its upper position. The motor remains connected to the drive source, which causes overloading of the motor, either as a result of it being completely braked or due to slippage occurring in the power transmission between the motor and the shaft 24.

If the switch 32 is assumed to be in the position shown, the charging of the capacitor H0 continues so that its voltage finally becomes so high that the double base diode HH generates a pulse. In this case, transistor H6 becomes conductive and momentarily throttles transistor H8; whereby the holding current of the relay 12 is interrupted. The relay 12 thus switches off and interrupts the motor current. In some cases, it is not desired to carry out a complete image change, but only to cause a displayed image to be entered in the magazine without subsequent output of a new image. In this case, the operator initiates the desired process by pressing in a second manual switch S6 instead of that of the image exchange initiating switch SH.

Closing the switch.56 causes the relay 18 to turn on and obtain self-holding over its contact 22, the switch 32 and the transistor H8. At the same time, the motor is supplied with current via the relay contact 16 and the contact 1U of the relay 12. In the same manner as described above in connection with a normal image exchange process, the charging of the capacitor HO begins when the switch 30 switches to its lower position after 100 rotation of the shaft 24. After a rotation of the shaft ZU of a total of 1700, the cam means 28 will transmit the switch to its upper position, whereby the relay 18 falls so that the motor 10 stops. Via the diode 36 and the switch 32 a simultaneous discharge of the capacitor HO, «V 3 8203554-2 takes place before its voltage has become high enough to trigger the double-base diode He. Should the shaft Zu for some reason get stuck, the motor continues to operate while the switch 32 remains standing in its lower flame, which - provided that the shaft moves so much that the switch 39 has switched to its lower position - causes the capacitor HO to continue to be charged and eventually causes the double bass diode Hu to generate a pulse for throttling the transistor 48, whereby the self-holding of the relay 18 ceases and the motor current is interrupted.

From the above it appears that the motor current is always switched off automatically if the motor remains switched on for a longer time than that with a predetermined, selectable interval exceeds the time for normal image change.

Claims (5)

Claims 820555492 Overload protection for a still image projector, in which an electric motor (10) is arranged to drive image exchange means via a shaft (2H), characterized in that means (26, 28) arranged on the shaft (ZU) are arranged to cause that an electronic time circuit (38, HO) comes into operation at the beginning of the image exchange and returns to its initial state when the image exchange is completed, and the time circuit is arranged to influence a means (H8) which interrupts the motor current about the time circuit after a certain predetermined time, which exceeds the time for a normally functioning image exchange, has not returned to its initial state. Overload protection according to claim 1, characterized in that the means arranged on the shaft (ZH) comprise cam means (26, 28) or the like which are arranged to operate switches (30, 32), which in turn affect the timing circuit. 3. Overload protection according to claim 1 or 2, characterized in that the timing circuit comprises an RC circuit (38, U0), the capacitor (RO) of which is normally kept in an uncharged state via at least one switch (30). 4. ~ H. Overload protection according to Claim 3, characterized in that the RC circuit (38, H0), when charging to a predetermined level, is arranged to cut off a normally conducting transistor (48), which means that a first relay (18), which the image exchange process is switched on, falls, whereby one of the contacts of said relay (16) breaks the motor current. Overload protection according to Claim 4, characterized in that a second relay (12) is arranged to control the process together with the time circuit (38, HO) when the image is to be output but no new image is displayed for display.