DE909218C - Timing device - Google Patents

Description

The invention relates to timing devices for the precisely timed supply of an inductance by means of a timing condenser; sators.

The use of a timing capacitor to achieve a predetermined delay for the activation of a relay is known. The invention is based on the object of an inductance, which can carry considerable electrical energies, usually for a very short period of time to be supplied with power and to switch it off without sparking at the end of the time interval, without at DC feed destruction can occur as a result of arcing at the relay contacts.

This is achieved by the fact that, according to the invention, in a normally open feed circuit lying inductance is connected to voltage at the same time as the timing capacitor and on At the end of the time interval is short-circuited by switching means, which preferably at least ao contain an amplifier tube and which depends on the state of charge of the timing capacitor being controlled. The change in the state of charge of the timing capacitor is expedient a time constant that can preferably be preset using a potentiometer.

In the drawing, the invention is explained using two exemplary embodiments; it shows

Fig. Ι a schematic representation of a time control device according to the invention, Fig. 2, a further embodiment. In the circuit diagram of Fig. Ι io means one Inductance fed by a current source for a precisely measured period of time target. This inductance may be due to the winding of a solenoid or other inductive Switching element are formed, an alternating current feed line 11 with a Hand switch 12 supplies the mains connection part 13, which supplies the working voltages for the timing device to be described in more detail. The rectifier part 13 has a transformer 14 for heating the electron tubes used, he also has a transformer and rectifier arrangement, by which various DC voltages are obtained. In the illustrated embodiment are two transformers 15, 16, the rectifiers 17, 18, 19, the capacitors 20, 21, 22, 23, the resistors 24, 25, 26 and the stabilizers 27, 28 are interconnected in the manner indicated. This arrangement supplies positive voltages, e.g. 150 volts, on the outer conductors 29, 30 with respect to the grounded conductor 31; it also provides a negative voltage, e.g. 105 volts, on the outer conductor 32 opposite earth. Because the special training of the rectifier part is not the subject of the invention, it should only be noted that in general the conductor 29 direct current is more substantial Size leads to the feeding of the inductance 10 forming the load, but this is not good is smoothed and kept constant, while the conductor 30 is relatively weak, but good filtered and held constant current leads to the control tube 53, as described later will.

In addition to the DC voltages, the power supply 13 by means of the conductors 33, 34 is a Control AC voltage supplied, which reaches the control relay 35 and the overload relay 36. That Relay 35 has a working winding 37 and three sets of contacts 38, 39, 40. The relay 36 has one Trip coil 41 to open the contacts 42 and a switch-on coil 43 to close these contacts. The closing coil 43 is via the conductor 33,

34 and a switch 44 connected. The working winding 37 of the relay 35 is on the ladder 33, 34 and the start switch 45 and the contacts 42 of the relay 36 are connected. Contacts 40

of the relay 35 are in a holding circuit 46 which is shunted to the start switch 45.

The trip coil 41 of the relay 36 is in one

Circuit from conductor 29 via contacts 38 of relay 35, via conductor 47, resistor 48 leads to one end of the inductance 10, the other end of which leads to the grounded conductor 49. The conductor 30 is via the contacts 39 of the relay

35 led to the conductor 47 ^α . The resistors 50, 51, 52 are in series between the conductors 47 ° and 32. The electron tube 53, for example a triode, has a grounded cathode, while its grid is via the resistor 54 on the movable tap of the resistor 51 and its anode via the winding 55 of the relay 56 is led to the conductor 47 ″. The time regulating capacitor 57 is located between the grid and cathode of the tube 53. The relay 56 is used to connect a short circuit for the inductance 10 by means of its contacts 58.

After closing the switch 12, the device only works so that the rectifier part 13 supplies the above-mentioned voltages and the capacitor 57 via the voltage divider resistors 52, 51, 54 is charged to a voltage of -105 volts. However, the device is only working correct if the reset switch 44 and the start switch 45 are depressed for an instant will. First, switch 44 is momentarily depressed to clear the contacts 42 of relay 36 to close; then the switch 45 is briefly depressed, causing the relay 35 receives power via the closed contacts of the relay 36. The relay 35 then holds itself via its contacts 40. The relay 35 closes the circuit for the inductance when it responds 10 and applies the anode voltage to the tube 53. However, the grid of the tube 53 has as a result of the negative voltage across the capacitor 57, a voltage below the reverse voltage negative bias so that the tube remains non-conductive.

After closing the relay 35, however, the capacitor 57 discharges through the resistor 54 one determined by the leakage resistors 50, 51, 52 Tension. As soon as this voltage exceeds the reverse voltage of the grid of the tube 53, the tube becomes conductive and then supplies the relay 56 which shorts the inductor 10 turns on. As a result, the current across the resistor 48 suddenly increases, so that the from Rectifier part 13 through the coil 41 of the relay 36 flowing current whose contacts 42 opens and thereby switches off the relay 35. The opening of the Relay contacts 38, 39 interrupts the main circuit and takes the anode voltage from the Tube 53. The device remains idle until the relay 36 is switched on again by switch 44 and the start switch 45 is closed again.

As has been shown, the duration of the current flow in the inductance 10 is due to the charging time of the capacitor 57 is precisely determined and is controlled by the tube 53. In addition, the Inductor shorted out before the circuit is opened so that no arcing occurs on the contacts can occur.

In the preferred embodiment of the invention according to Fig. 2, a double tube is used as the control member used or two individual tubes, as described below. The inductance is again denoted by 10, and its short circuit is controlled by the relay 56, in the same way as in the embodiment according to Fig. 1. The rectifier part 13 is indicated in block form and has the output voltage conductors 29, 30, 31, 32, and 34.

In this case, the AC control voltage supplied via conductors 33 and 34 is used for Control the relays 59 and 60. The winding 61 of the relay 60 is connected to the conductors 33, 34 over the normally open start switch 62. The contacts 63 of the same relay are in a holding circuit 64, which is shunted to the start switch 62 and which has a stop switch 65. The winding 66 of the relay 59 is across the normally open contacts 67 of the relay 60 also on ladders 33, 34.

The voltage tap 29 is to the ungrounded end of the inductor 10 via the normally open contacts 68 of the relay 59 and the

¹ S resistor 69 led. The voltage tap 30 is led once via the normally open contacts 71 of the relay 59, the conductor 72 and the winding of the relay 56 to the right anode of the double triode 70; In addition, the left anode of the tube 70 is connected to the tap 30 via the resistor 73.

As will be described in detail later, the supply of current to the inductance 10, which is provided for a specific time interval, is carried out by charging the timing capacitor 74, which is located between the right grid of the tube 70 and earth. This capacitor is fed via the resistor 75 from a potentiometer arrangement comprising the series resistors 76 and 77 , which is located between the conductors 72 and 78, the conductor 78 being connected to the conductor 32. The left grid of the tube 70 is connected to earth via the resistor 80. The right anode of the tube is connected to the left grid of the tube via capacitor 81. The left anode is connected to the right grid via capacitor 82. The voltage tap 32 is led via the normally closed contacts 83 of the relay 59 and the resistor 84 to the plate of the capacitor 74 which is not grounded.

The operation of the device is after closing the switch 12 so that the rectifier part supplies the intended voltages, but the device will not operate until the start switch 62 is actuated became. In the inoperative state of the device, i.e. before pressing the start switch 62, is the left triode part of the tube 70 due to the left anode via tap 30 and resistor 73 lying positive voltage conductive. As a result, the voltage drop across the resistor will hold 79 the cathodes of the tubes at the intended negative potential; z. B. -10 volts. to During this time the right triode part of the tube is non-conductive.

The momentary closure of the start switch 62 feeds the relay 60, which thereby closes its hold circuit 64. The closure of the contacts 67 causes relay 59 to respond, which opens the contacts 83 and its contacts 68 and 71 closes. By closing the contacts 68, the inductance 10 is switched on and, at the same time, by closing the contacts 71, the anode voltage is applied to the right triode part of the tube 70. The opening of the contacts 83 enables the time control capacitor to be charged to a voltage which is determined by the tap on the potentiometer 76, the size of the charge being determined by the value of the resistor 75. As soon as a voltage arises across the capacitor 74, the grid of the right triode part of the tube 70 receives such a potential that the tube becomes conductive and a considerable voltage drop is caused by the current flow at the right anode. This voltage drop is transmitted via the capacitor 81 to the grid of the left-hand triode part, as a result of which its anode current falls while the anode potential rises. This increase in the anode voltage is transmitted via the capacitor 82 to the grid of the right triode part and there causes a further increase in the anode current and a voltage drop at the right anode, which in turn is transferred to the grid of the left tube part. During this process, there is a steep increase in current in the winding of the relay 56. This rise in current is very sudden as soon as the capacitor 74 has been charged to the critical grid voltage on the right-hand triode part. A major advantage of this control process is that errors due to slight fluctuations in the response point of relay 56 are avoided, which would manifest themselves as timing errors if only a normal increase in current occurred.

When relay 56 responds, the inductance 10 short-circuited and thereby made this switching element completely de-energized. As a result of the short circuit of the inductance 10, the relay 60 drops when the stop switch 65 is opened away. This in turn drops the relay 59, and the device is again in ineffective condition. The switch 65 can be operated in any suitable manner, for example when using a solenoid, automatically by moving it using suitable ones Actuating means.

The connection closed by the contacts 83 of the relay 59 has the task of again a positive charge on capacitor 74 to the normal output voltage through a circuit to achieve with a very small time constant, so that the size of the time interval between actuations cannot influence the accuracy of the time measurement.

As can be seen from the description, enable both switching arrangements shown by means of the timing capacitor one time precisely measured current flow in an inductance, with the voltage across the capacitor for Connection of a normally ineffective short circuit to the inductive load is used will. Furthermore, each of the switching arrangements is controlled by means of an electron tube causes. In the circuit of Fig. 2, a double tube is used for this, as described in FIG Way works. Of course you can

Instead of the double triode used for simplification, two single tubes can also be used. In a special version of the circuit according to Fig. 2, the type for tube 70 was SN 7 / USA used, also the following capacitances and resistances:

resistance 69- 75 100 Ohm - So watt resistance 73 - 000 Ohm - I. watt resistance 75 - 250 I. Megohm - ■ I. watt resistance 76 - 150 000 ohm resistance 77 - 50 OOO Ohm - I. watt resistance 79 - 000 0hm - I. watt resistance 80 - I. I. Megohm - watt resistance S ₄ - OOO Ohm - 2 watt capacitor 74 - O, 3 microfarads capacitor 81 - 500 Micro-microfarads capacitor 82 - 500 Micro-microfarads

These values can of course vary depending on the particular application of the invention to be changed.

The invention can be used in all cases in which one is accurate in terms of time rated supply of an inductive load is required. So z. B. the invention use to control drop hammers.

It should be noted that the invention does not apply to the described and illustrated embodiment is intended to be limited.

Claims (5)

PATENT CLAIMS: i. Time control device for the precisely timed supply of an inductance by means of a timing capacitor, characterized in that in a normally open Supply circuit lying inductance (10) at the same time with the timing capacitor (57 or 74) is applied and at the end of the time interval by switching means (53 or 70, 56) is short-circuited, which preferably has at least one amplifier tube (53 or 70) and which are controlled as a function of the state of charge of the timing capacitor will. 2. Apparatus according to claim 1, characterized in that the change in the state of charge of the time control capacitor (5.7 or 74) has a presettable (potentiometer 51 or j6) time constant. 3. Apparatus according to claim 1 and 2, characterized in that the circuit for Supply of the switching means (53 or 70, 56) for short-circuiting the inductance (10) and the charging of the time regulating capacitor (57 or 74) via switching means (35, 36 or 59, 60) is closed after arousal, preferably by a push-button switch, itself hold themselves (contacts 40 or 63) and after switching on the short circuit, primarily by an overcurrent winding (41). 4. Apparatus according to claim 3, characterized in that the switching means (59, 60) for Closure of the feed circuit by one of the inductance (10) after applying the Switching process triggered by a short circuit can be switched off. 5. Apparatus according to claim 1, characterized in that that a double triode is provided as the tube (70), the grid and anodes of which are mutually connected (81, 82), where only one triode system is normally conductive, while that is normally non-conductive triode system in the grid circle of the time control capacitor (74) and in the Anode circuit is a relay (56) for short-circuiting the inductance (10). Referred publications:
German patent specification No. 516692. 1 sheet of drawings © 5919 4.54