DE3101411C2 - Circuit arrangement for an electrical driving device - Google Patents

Abstract

The invention relates to an electronic circuit for an electric driving device for staples, nails or the like. It is designed so that the manual switch lies in the circle of the driving magnet and is de-energized.

Description

31 Ol

is produced, so that only a single one by the driving device Impact is carried out and a further impact can only be made after the opened pushbutton switch again is operated.

The first locking stage also ensures that the pushbutton switch is de-energized. This is from of some importance, since a current of considerable strength flows through the magnetic coil when it is under voltage is laid.

One embodiment of the invention provides that the first locking stage is constantly connected to the change stage connected thyristor connected in parallel to the control stage, its control circuit as well is constantly connected to the AC voltage source, and the control circuit is short-circuited via a transistor whose base is connected to the voltage-free contact when the pushbutton switch is open Pushbutton switch, the thyristor of the locking stage is switched through and therefore switches the control stage short. A switch-on pulse cannot be generated. This has the same effect as a lounger when the pushbutton switch is open, a short circuit occurs, while that in known circuit arrangements is generated of a switch-on pulse

In a further embodiment of the invention it is provided that the second locking stage is a series connection from a diode and a thyristor, which when the push-button switch is closed with the control stage connected in parallel is a voltage drop across a resistor when the pushbutton switch is closed generated, which is connected to the control electrode of the thyristor via a diode and a resistor, in parallel a capacitor is connected to the thyristor, the capacity of which is dimensioned so that the current of the during a negative half-cycle across the capacitor discharging the thyristor, the holding current of the thyristor does not fall below. The thyristor of the second locking stage is delayed after the generation of the Switch-on pulse in the control stage in order to then switch the control stage back on again. Of the capacitor connected in parallel ensures that the thyristor of the second control stage also during the opposite half-wave remains switched through, so that it is ensured that even when the pushbutton switch is closed only a single driving impact is generated.

An embodiment of the invention is shown below explained in more detail with reference to drawings.

F i g. 1 shows a block diagram of the circuit arrangement according to the invention.

2 shows a somewhat more detailed circuit arrangement with the feature of the invention.

Before proceeding to the details shown in the drawings will be discussed in more detail, it should be noted that each of the features shown and described for itself or in connection with features of the claims is of essential importance to the invention.

In Fig. 1 denotes 10 a magnetic coil of a conventional electrical driving device, otherwise not shown. The magnetic coil 10 is connected in series with an AC voltage source 13 via a circuit breaker 11 and a pushbutton switch 12. The circuit breaker 11 is controlled by a control stage 14 which is connected to the circuit breaker 11 via a time delay stage 15. A first locking stage 16 is connected to the control stage 14 and connected to the contact of the tactile switch 12 which is de-energized when the tactile switch 12 is open. A second locking stage 17 is also connected to the control stage 14 and is subjected to the voltage drop that is generated via a resistor R when a current flows through the coil 16.

The circuit arrangement according to FIG. 1 works as follows If the pushbutton switch 12 is open, the locking function ensures 16 for the fact that an ON pulse for the. Circuit breaker 11 is not generated. Through the connection of the first locking device 16 with the dead contact when the pushbutton switch 12 is open sets the locking stage 16 when the push button switch 12 is open closed, the second locking stage 16 is also subjected to voltage and unlocks the control stage 14, so that it opens the circuit breaker 11 The control stage 14 is unlocked in such a way that that only with a full, the closing of the push button switch .1.2 following positive half-wave, a control pulse is generated so that a full half-wave is applied to the circuit breaker 11 and thus to the magnetic coil 10 will.

The current flow through the resistor R generates a voltage drop which acts on the second locking stage 17 and also locks the control stage 14 is. Further switch-on pulses are therefore no longer generated, even if the pushbutton switch 12 remains closed.

In Fig. 2 the pushbutton switch is also designated by 12. The magnet coil bears the reference number 10. The magnet coil 10 is connected to a power thyristor TH 3 in series with the AC voltage source L i / N. The pushbutton switch 12 and a fuse FX are also located in this series connection. The control electrode of the thyristor TH 3 is connected to an output electrode of an unjunction transistor T2, the emitter electrode of which is located at a point between a parallel connection of two resistors P 1 and R 13 and a capacitor CA. A resistor R 10 is connected in series with the aforementioned resistor-parallel circuit. The circuit components described are continuously connected to the pole L 1 of the AC voltage source via a resistor RS and a diode 4. The other output electrode of the unjunction transistor T2 is located above a resistor R 11 at a point between the diode D 4 and the dsm resistor R 10. A thyristor TH 2 is located between a point between the resistor R 8 and the diode 4 and the other pole N of the AC voltage source .

The control electrode lies between a resistor R 9 and a capacitor C3 connected in series with it, which series connection is in series with a resistor R 7, which is also connected to the pole L 1 of the AC voltage source. Parallel to the series connection of resistor R 9 and capacitor C 3 is the emitter-collector path of a transistor Tl, the base of which is connected via a resistor R 6 to the dead contact 2 of the push button switch 12 when the push button switch 12 is open. A series circuit of a diode D 2, a resistor R 5 and a capacitor C 2 connects the contact 2 of the push button switch 12 to the pole Λ / the AC voltage source.

A point between resistor R 5 and capacitor C2 is connected to pole Λ / of the voltage source via a resistor R 1 and a thyristor THi. A resistor R 4 is connected in series with the power thyristor TH 3. The series circuit of a resistor R 3 and a resistor R 4 is parallel to the resistor R 4

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Diode D 3. This series circuit is connected to the control electrode of the thyristor TH 2. A capacitor CX and a resistor R i are parallel to the control electrode 7 ″ Wi . Finally, a capacitor CD is connected in parallel to the poles L 1 and / V of the alternating energy source.

The sound arrangement shown in Fig. 2 works as follows.

The thyristor 7 "! W 2 is triggered somewhat delayed at every positive half-cycle because of the capacitor C3 , around 6 V. Accordingly, the voltage at the diode D 4 rises to around 6 V, but falls after that Ignition of the thyristor TH 2 to about 1.4 V. At this voltage, the ignition or trigger circuit cannot ignite the thyristor Ti-IZ.

If the pushbutton switch \ 2 is closed, the control current for the control electrode of the thyristor TH 2 is short-circuited via the transistor Ti , the base of which is now connected to the voltage source. If the thyristor TH2 was already ignited when the pushbutton switch 12 was closed, an ignition pulse is not emitted, since TH 2 remains conductive until the next zero crossing.

If, however, the pushbutton switch 12 is closed before the zero crossing or during the negative half-wave, the control circuit for the thyristor TH 2 is short-circuited via the resistor RG and the transistor Π, so that the voltage at D 4 increases until the ignition pulse is given and the thyristor TH 3 is ignited can be. After the thyristor TH 3 has been triggered, the current flows through the coil 30, which generates a voltage drop of approximately 3.5 V at R 4. The thyristor THX is ignited via the diode Di and the resistor R 3 via the voltage drop at /? 4, but with a time delay caused by the capacitor C1. During the closed pushbutton Ί2 the capacitor Cl is charged with a positive half-cycle. During the positive half-cycle, a current also flows through the diode D 2, the resistor R 5, the resistor R 1 and the thyristor TH2 and through the resistor / 8, the diode D 3 and the thyristor TH 1. During the negative. Half-wave the capacitor C2 discharges through the resistor R 1. The capacitor C2 is dimensioned in such a way that the holding current of the thyristor TH 1 is not undershot. This means that as long as the push button switch 12 is closed, the thyristor TH t remains triggered and prevents a new ignition pulse from being generated via the diode D 3 and thyristor TH 5. If the pushbutton switch 12 is opened again, the thyristor THi extinguishes after the Unterachreiien cies Kakestromes, ie after discharge of the capacitor C2. Now, after the pushbutton switch 12 has been closed, a new positive half-wave can be applied to the magnetic coil 10.

For this! Sheet drawings

60

65

Claims (3)

31 Ol 411 1 2 possible to provide the full service for driving NM patent claims: gladly, brackets or the like. The impact force is generated by the solenoid 1. Circuit arrangement for an electrical one, in which the driving ram is part of a Driving device for driving nails, staples 5 ferromagnetic plunger is moved (DE-PS or the like, with one over a power 14 78 899). A return spring ensures the reset switch of the alternating voltage magnetic coil of the driving ram in the rest position when a coil connected to the alternating voltage source has been switched off senen control stage which, when a key is pressed, is also known to control the solenoid switch to make a switch-on pulse for the power io Ie with the help of a power thyristor switch is only generated when after closing (DE-OS 22 38 440). The power thyristor is in series of the pushbutton switch there is a full half-wave, so that the magnetic coil is connected to AC voltage. With help characterized in that the tactile switch is a pulse circuit via a further thyrial ter (12) with the circuit breaker (11) and the master connected the control electrode of the power thyristor. solenoid coil (10) is connected in series, controls the control stage 15 and ignites it when the pushbutton switch is (14) is constantly operated with the AC voltage source (13). is connected, one connected to the control stage (14). In the known circuit arrangements, the dene efste locking stage (16) the generation control circuit for the power thyristor constantly on the a switch-on pulse suppressed as long as the AC voltage source. There is therefore a risk that Pushbutton switch is open, and one with the control unit 20 due to a short circuit or similar faults an on Fe (14) connected second locking stage (17) generated switching pulse and actuated the driving ram the generation of a switch-on pulse is suppressed, although the pushbutton switch has not been pressed. A after a first switch-on pulse has been generated such a failure affects the safety is. substantial and can both the operator and 2. Circuit arrangement according to claim 1, that 2s damage objects. A further danger is characterized in that the first locking is that after the working stroke with further actuation stage (16) a constantly connected second or multiple blows source to the alternating voltage system pushbutton switch occurs parallel to the control stage Thyristor (TH 2) switched by the operator, whose control threads, which the driving device may also be constantly circling, have already been removed from the working position with the AC voltage. Since the source is connected and the control circuit is short-circuited via a transistor (Tl), which is normally fastened from magazines and whose base will shoot, failures lead to so-called fail-safe failures when the pushbutton switch (12) is open, i.e. the bullet-like emergence of a voltage-free contact (2 ) is connected to fastening means. 3. Circuit arrangement according to claim 1 or 2, 35 The invention is therefore based on the object, characterized in that the second locking circuit arrangement for switching on an electrilungsstufe a series circuit of a diode and see driving device to improve that a thyristor (THl) Contains that when the pushbutton switch is closed, when the pushbutton switch is not actuated, failures are avoided with the large pushbutton switch (12) with the control stage parallel ßer safety and only a single switch is switched which is generated when the pushbutton switch 40 is closed. (12) load current flowing at a resistor (R 4) This object is solved by the invention, produces a voltage drop across a diode that the push-button switch with the power switch and (D 1) and a resistor (R 3) to the Steuerelek- Solenoid coil is connected in series, the control stage is placed trode of the thyristor (TH l), and is constantly connected in parallel with the AC voltage source, a capacitor (C2) connected to the thyristor (TH 1) is connected to the first locked The capacitance is dimensioned so that the generation of a switch-on pulse under the current of the pushes itself during a half-wave over the as long as the pushbutton switch is open, and a thyristor (THX) discharging capacitor discharges the second locking holding current of the thyristor connected to the control stage (TH X ) does not fall below the generation of a switch-on pulse below 50 presses after a first switch-on pulse has been generated has been. In the circuit arrangement according to the invention is the pushbutton with which a blow of the driving tool is triggered, together with the power Circuit arrangement for an electrical drive-in switch and the coil in series. As long as the tactile switch for driving in nails, staples or the like remains open, the control stage will constantly smell with an alternating over a circuit breaker and can therefore not generate a switch-on pulse, a magnet coil connected to the alternating voltage. Short circuits or other Incorrect switching can control stage connected to the low voltage, which in the case of beta does not result in actuation of the circuit breaker If a pushbutton switch is used, a switch-on impulse is generated for the 60, because when the pushbutton switch is open, the span circuit breaker is only generated if there is no input after the Closing the pushbutton switch a full half-wave after the pushbutton switch has been actuated. So now one stands. full half-wave to generate the impact force. A switch-on pulse is given below the following half-wave, for example the positive one suppressed as long as the pushbutton switch is open and only half-wave by opening the circuit breaker to the released when applied after closing the touch switch solenoid. The second level of locking ters a full half-wave is pending. In this way it ensures that only a single switch-on pulse