DE1135957B - Pulse storage device - Google Patents

Description

Pulse storage device The invention relates to a storage device, in which a signal is entered and removed again in the form of an electrical pulse can be, with a commutator, the electrical contact segments isolated from each other has, further with signal receiving and storage means, which are electrically between the contact segments and a common connection are connected, with a first and a second brush, which are adjustable in their position to each other and against the Commutator, the contact segments of which are guided past the brushes one after the other are relatively movable, with the first brush sending a signal in the form of a electrical impulse on each of the electrical contact segments and those connected to them Receiving and storage means can transmit, if. the contact segment on the first Brush is passed and the second brush that in the receiving and storage means stored signal can be found when the contact segment assigned to these means is moved past the second brush.

A known storage device includes a plurality of capacitors, the contact segments of a commutator assigned to them are connected and successively come into contact with a brush, the relative movement has a constant speed between commutator and brush and the brush can supply a characteristic charge to the corresponding capacitor, which can serve as a signal for a subsequent control device if the assigned Contact segment in contact with a second brush for a specified time thereafter comes. This time depends on the speed of the relative movement and on the angular displacement of the two brushes.

In this known device, errors can be caused by unintentional Discharges of the capacitors occur, for example through short circuits between adjacent contact segments of the commutator through conductive dirt or through Humidity.

The aim of the invention is to provide a memory device at that prevents the capacitors from accidentally discharging due to dirt or moisture or by using very wide brushes that have two conductive brushes at the same time Commutator segments can come into contact.

This goal is achieved according to the invention in that each signal reception and storage means a capacitor and an electrical resistance device contains, in the direction of current from the contact segment of the commutator to the capacitor a low electrical resistance and, in the opposite direction of the current, a high electrical resistance has and whose high initial electrical resistance is greatly reduced, when a specified electrical voltage is exceeded.

This electrical voltage is known as the "breakdown voltage". Examples of electrical resistance devices having such a characteristic are neon tubes, zener or avalanche diodes or an arrangement of rectifiers and a power source. The advantage of this modification is that the signal receiving and storage means, e.g. B. a capacitor, cannot be discharged until by a brush connected in series with the power source, an electric one Contact is established. The device can therefore be used where conductive Dust or moisture is present and where the capacitor lasts its charge Should retain time without the risk of accidental or accidental discharge.

The invention is illustrated by the drawing, which shows a schematic circuit diagram of a memory device which contains means for preventing accidental discharges. The drawing shows a storage device which contains means for preventing accidental discharge. This storage device contains a rotatable cylindrical commutator 31 with alternately successive electrically conductive segments 32 and insulating segments 33. Fixed brushes 34 and 35, which slide on the commutator surface, are attached at a distance around the circumference of the commutator 31. These brushes 34 and 35 are attached so that their position around the circumference of the commutator can be adjusted as desired. Brush 34 is used to conduct a signal in the form of an electrical pulse to commutator 31, brush 35 is used to extract and cancel the signal.

Each. electrically conductive segment 32 is connected to one terminal of a Zener diode 36. When using Zener diodes, the breakdown voltage is equal to the Zener voltage of the diode. The other terminal of the diode 36 is connected to one terminal of a capacitor 37, the other terminal of which leads to a common slip ring 38 . The capacitors 37 and diodes 36 are attached to the commutator gate that they rotate with him. A stationary brush 39 rubs against the slip ring 38. Other electrical devices, such as neon tubes or an arrangement of rectifier and power source, can be used in place of the Zener diode. Brush 34 is connected to button 40 and power source 41 , as can be seen from the drawing. Brush 35 is connected to power source 42, for example a battery, and is in series with a relay coil 43 of a relay, which corresponds to relay 11 of FIG. 1, and with brush 39, which slides on slip ring 38. Brush 39 is also connected to button 40 in the circuit and acts as a ground line.

Diode 36 is arranged so that it has a low resistance in the direction of current flow from the electrically conductive segment 32 to the capacitor 37 and has a high initial resistance in the direction of current flow from capacitor 37 to the electrically conductive segment 32. The diode 36 is chosen so that the voltage on the capacitor 37 plus the voltage of the current source 42; here the battery 42 is greater than the Zener voltage, ie the breakdown voltage of the diode, but the individual voltages of the current source 42 and the charged capacitor 37 are lower than the Zener voltage. With this arrangement, a charged capacitor is not discharged through a conductive path between segments 32 and the common slip ring 38 or other segments. Also through the load circuit, ie the relay coil 43, no current flows; when brush 35 touches a segment 32 which is connected to an uncharged capacitor 37 via the corresponding Zener diode 36.

Even if the discharge current of the capacitor via brush 5 is a relay feeds, it can also be used to control a thyratron or a similar device be used. The energy supply for the storage device does not necessarily need from a battery, but can also be from another power source to be delivered. The electrical circuit must then be adapted accordingly.

An example of application for the invention is given in the manufacture of sheet steel. In practice, the continuous sheet metal strips that come from the rollers are passed through devices to detect defects such as pores, holes and the like which have previously been found to have errors, must be removed. The device according to the invention is suitable for causing this removal. In this example, the signal input device is connected to the error detection device, which causes a signal to be fed to the brush 34 when errors occur. This signal is received and stored by one of the capacitors and subsequently picked up by brush 35. Relay 43 is thereby excited, so that a suitable operating device is caused to remove the sheet metal with the holes. The speed of rotation of the commutator is proportional to the speed at which the sheet metal strip passes through the fault detection device and through the cutting device, so that the time for the faulty strip to pass from the detection device to the cutting device corresponds to the time in which the capacitor receiving the signal .catches and stores, runs from brush 4 to brush 5.

In a further embodiment of the memory device according to Invention, the commutator is stationary, and the brushes run in compliance with their predetermined distance from each other around the circumference of the commutator. Furthermore you can instead of connecting the capacitor to the segments and the common Slip ring two commutator disks are used, with each capacitor between one segment on the first commutator disc and one segment on the second Commutator disk lies. Each commutator must then have a corresponding set of brushes that are either aligned or offset by part of the segment division.

The degree of control depends on the mechanical limits of the various brushes and commutator segments. More than one commutator can therefore be used to achieve greater resolution. The width of the brush 34 can be varied as desired in order to charge one or more capacitors according to the type of signal or to adapt to the type of application. Any number of brushes that drag on the commutator can be arranged. Any number of capacitors can be charged simultaneously using appropriate switches in the brush circuit, and each individual brush can be switched on to charge or discharge capacitors, or switched off.

The invention can therefore be applied to a reciprocating process are used to switch forward and reverse signals between any, selected by the switches Brushes to wear, and the signals can be used to determine the extent of the going back and forth Reciprocating or used to control associated equipment.

The commutator is not intended to be purely radial or cylindrical Shape may be limited as it is equally possible to use the segments and capacitors on an endless belt or similar device or an elongated one Assemble link. If the storage device is applied to a process control, so the relative movement of the brushes and the commutator corresponds to the movement of called procedural control.

Claims (3)

PATENT CLAIMS: 1. Storage device in which a signal in the form an electrical impulse can be entered and withdrawn again with a Commutator, which has electrical contact segments isolated from one another, furthermore with signal receiving and storage means electrically between the contact segments and a common connection are connected, with a first and a second Brush, which are adjustable in their position to each other and against the commutator, whose Contact segments successively past the brushes, relative are movable, the first brush sending a signal in the form of an electrical pulse on each of the contact segments and the associated receiving and storage means can be transmitted when the contact segment is guided past the first brush, and the second brush the signal stored in the receiving and storing means can infer when the contact segment assigned to these means passes it will; characterized in that each signal receiving and storage means has one Includes capacitor (37) and an electrical resistance device (36) which in the current direction from the electrical contact segment (32) to the capacitor (37) low and in reverse current direction from the capacitor to the electrical contact segment (32) has a high electrical resistance and its high initial electrical resistance is greatly reduced when a predetermined electrical voltage is exceeded will. 2. Storage device according to claim 1, characterized in that a current source (42) is in series with the common connection (38) and the second brush (35), their voltage below the breakdown voltage of the electrical resistance device (36) is, and that the sum of the voltage of a charged capacitor (37) and the voltage of the source (42) exceeds this predetermined breakdown voltage. 3. Storage device according to claim 2, characterized in that the electrical resistance device (36) contains a Zener diode. Considered publications: German Patent Nos. 683 701, 891998, 961811; German patent application D 161.88 VIIIa / 21as (published October 24, 1953); U.S. Patent No. 2,373,247.