DE4333120A1 - Electronic two-wire momentary-contact switch - Google Patents

Abstract

The invention relates to an electronic two-wire momentary-contact switch for traffic lights, door openers in rail or road vehicles, for machine controls and the like, comprising a voltage-controlled switching element (8) switching a load circuit (7) and having a device (10) for generating the control voltage (U1). To achieve a long closing period and to keep the energy requirement of the momentary-contact switch low, it is provided that the device (10) for generating the control voltage (U1) has a storage capacitor (15) which can be charged to the control voltage (U1) from the load circuit (7) via a diode (14) and which can be connected to a high-impedance control input (9) of the switching element (8) via a momentary mechanical contact (19). <IMAGE>

Description

The invention relates to an electronic Two-wire push button switch for traffic lights, door opener in Rail or road vehicles, for Machine controls and the like, with one voltage controlled, switching a load circuit Switching element and with a device for generation the control voltage.

Electronic key switches are known, in which a piezo element is loaded via a push button, which is a control voltage for switching the there as Switching element used MOSFET supplies. With a Piezo element can only be used for a very long time gain control voltage over short periods of time, which is why the closing time of the known key switch to about 10 to 100 msec. is limited.

There are two-wire electronic key switches, at which use a MOSFET as a load switching element whose control voltage from a circuit arrangement is gained, the constant power consumption has, which has the consequence that no high-impedance Loads are switchable. There is also the Voltage drop at the pushbutton switch when the  Load very high, which leads to strong warming large load currents.

The invention has for its object a to create electronic two-wire push button switch that for long, e.g. B. minutes, switch-on times can be interpreted and its power requirement is not switched on Condition is very low.

Starting from a two-wire push button switch at the beginning mentioned type, is the solution to this problem achieved according to the invention in that the device to generate the control voltage via a diode from the load circuit to the control voltage has a rechargeable storage capacitor which a mechanical touch contact to a high impedance Control input of the switching element can be connected.

The key switch according to the invention offers the special advantage that its facility for generation the control voltage only once after opening the Key switch for a short time to charge the Capacitor needed and that during the rest Opening time of the key switch, - apart from possible leakage currents -, no energy consumed becomes. This eliminates all heating problems, and the Key switch according to the invention is also for switching high-resistance loads can be used. By appropriate Sizing of the storage capacitor can take a long time Switch-on times can be selected because the capacitor is over unload the high-impedance control input very slowly becomes. The diode prevents the discharge of the Storage capacitor when switched on Switching element.  

In an embodiment of the invention, it can be provided that that the device for generating the control voltage from a parallel to the switching path of the Switching element switched charging circuit exists in which the diode and the storage capacitor in series are switched, and that the control voltage of one Switching point between diode and capacitor is tapped. This can advantageously in Charging circuit one in series with the diode Resistance can be provided, which the charging current of Capacitor limited, so that even during the Charging times of the storage capacitor no too Switching load influencing current flows.

Furthermore, according to the invention, it can be provided that in the containing the tactile contact Drive circuit is a resistor and that the Control voltage through a voltage limiting Component, e.g. B. a Zener diode is limited. The voltage-limiting component can directly Storage capacitor should be connected in parallel however advantageously directly between the Control input of switching element and reference potential be switched. Through these measures the Control input of the switching element before voltage peaks protected. As a switching element according to the invention a self-locking semiconductor device, e.g. B. MOSFET, Thyristor or IGBT can be used.

As far as described so far, the key switch is after the invention can only be switched on as long as the Tactile contact by hand or by a control in is held in the closed position. To also after Opening the touch contact for a longer time Period the load is switched on  To be able to keep is in development of the invention provided that between the control input of the Switching element and the reference potential Buffer capacitor is switched. When closing the This buffer capacitor is charged by touch the one after opening the touch contact determinable time the control voltage for switching of the switching element delivers. At the same time, this dampens Buffer capacitor voltage or current peaks that due to a contact bruise when touched can possibly occur.

The discharge of the storage capacitor or Buffer capacitor decays exponentially, causing too a gradual approximation of the control voltage for switching the switching element required minimum voltage value. Around Avoiding this unstable condition can further Embodiment of the invention, a monitoring circuit for the on the switching path of the switching element in switched-on state falling voltage be provided when a certain one is exceeded Voltage value an immediate blocking of the Switching element causes.

Further features of the invention are in the Subclaims specified and in connection with the following description of the figures explained in more detail.

The invention is based on two in the Drawing illustrated embodiments closer explained. The drawing shows:

Fig. 1 is a circuit diagram of a first embodiment of the key switch according to the invention and

Fig. 2 is a circuit diagram of a second embodiment of the key switch according to the invention.

Fig. 1 shows an electronic two-wire key switch 1 , which can be connected with its two connections 2 , 3 to a series connection of AC source 4 and load 5 to be switched. The load circuit 7 runs via a rectifier bridge 6 via a switching element 8 , here a MOSFET.

The control voltage U1 for the control input 9 of the switching element 8 is generated by a device 10 which consists of a charging circuit 12 connected in parallel with the switching path 11 of the switching element 8 , which has a series resistor 13 , a diode 14 and a storage capacitor 15 in series. A control circuit 17 runs from a circuit point 16 lying between the diode 14 and the storage capacitor 15 to the control input 9 of the switching element 8 . A resistor 18 and a mechanical contact 19 to be actuated are located in series in the control circuit 17 .

When the tactile contact 19 is open, the storage capacitor 15 is charged to control voltage from the load circuit 7 , and when the tactile contact 19 closes, the storage capacitor 15 provides the control voltage U1 required for switching the switching element 8 through for a certain time. During this time, the diode 14 prevents the capacitor 15 from being discharged via the load circuit 7 .

A Zener diode 20 is connected as a voltage-limiting element between the input 9 of the switching element 8 and the reference potential U0. A buffer capacitor 22 is connected between the reference potential U0 and a circuit point 21 , which lies between the touch contact 19 and the control input 9 . When the tactile contact 19 is closed, this buffer capacitor 22 is charged, which maintains the control voltage U1 at the control input 9 for a certain time even after the tactile contact 19 has been opened.

The control voltage U1 is also fed to a monitoring circuit 24 via a line 23 . The monitoring circuit 24 comprises a further switching element 25 , here a MOSFET, the switching path of which is connected in series with the resistors 26 and 27 in parallel with the switching path of the switching element 8 . A delay circuit 28 is arranged between the line 23 carrying the control voltage U1 and the reference potential U0 and has a resistor 29 and a capacitor 30 in series. The control input 31 of the switching element 25 is connected to a circuit point 32 between the resistor 29 and the capacitor 30 . The control voltage U1 generates a control voltage U2 for the switching element 25 , delayed by the charging of the capacitor 30 . When the tactile contact 19 closes, the switching element 25 is also closed, with a delay compared to the switching element 8 , a voltage being built up at the switching point 33 between the two resistors 26 and 27 , which controls a switching-off electronics 34 as the control voltage U3. The shutdown electronics 34 comprise two transistors 35 , 36 . The base of the transistor 35 is connected to the reference potential U0 via the resistor 27 and a capacitor 37 connected in parallel thereto. Similarly, the base of transistor 36 is connected to control voltage U1 via line 23 via a parallel circuit comprising resistor 38 and capacitor 39 . The base of transistor 35 is also connected to line 23 via collector-emitter path 40 of transistor 36 . The base of the transistor 36 is connected to the reference potential U0 via the collector-emitter path 41 of the transistor 35 .

When the switching element 8 is switched through, the voltage drop across the switching path 11 is initially almost zero. Accordingly, the voltage drop across the load circuit 44 of the switching element 25 , which is likewise switched through with a delay, is initially very small, so that initially only a blocking control voltage U3 is supplied to the transistor 35 . When the control voltage U1 falls, the resistance of the switching path 11 of the switching element 8 increases gradually, and the voltage drop across the switching element 8 thus increases. As a result of this larger voltage drop, the voltage drop across the load circuit 44 also increases , and the control voltage U3 at the transistor 35 increases gradually until it reaches a value sufficient for the transistor 35 to be switched on. When the transistor 35 is switched on, the transistor 36 also switches through, and the shutdown electronics 34 change to a second stable state in which the control input 9 is short-circuited to the reference potential U0 via the two transistors 36 , 35 . Thus, the switching element 8 locks suddenly. The shutdown electronics 34 then return to their first stable, blocking state.

The switching element 25 is expediently already opened by a control voltage U2 which is lower than the minimum control voltage U1 required to open the switching element 8 . In this way, creeping effects when locking the switching element 25 are also avoided.

In the exemplary embodiment according to FIG. 2, the elements which correspond to one another are provided with the same item numbers as in the exemplary embodiment according to FIG. 1. The monitoring circuit 24 according to embodiment 1 is omitted here, but could also be provided. Since a DC voltage source 4 is used, the rectifier circuit 6 is also omitted here.

In the exemplary embodiment according to FIG. 2, a high-resistance resistor 42 is connected in parallel to the capacitor 15 , which also determines the switch-on time of the switching element 8 when the switch contact 19 is closed. The resistor 42 must, however, be very high-impedance so that the current flowing continuously through it even when the tactile contact 19 is open is negligible.

The resistor 18 in the control circuit 17 is connected here between the tactile contact 19 and the control input 9 and, in conjunction with the capacitor 22 and a further capacitor 43, acts as a filter for damping effects resulting from contact bounces.

Reference list

1 push button
2 connection
3 connection
4 power source
5 load
6 rectifier bridge
7 load circuit
8 switching element
9 control input of 8
10 establishment
11 switching distance
12 charging circuit
13 series resistor
14 diode
15 storage capacitor
16 switching point
17 control circuit
18 resistance
19 tactile contact
20 zener diode
21 switching point
22 buffer capacitor
23 line
24 monitoring circuit
25 switching element
26 resistance
27 resistance
28 delay circuit
29 resistance
30 capacitor
31 control input of 25
32 switching point
33 switching point
34 Switch-off electronics
35 transistor
36 transistor
37 capacitor
38 resistance
39 capacitor
40 collector-emitter path of 36
41 collector-emitter path of 35
42 resistance
43 capacitor
44 load circuit of 25
U0 reference potential
U1 control voltage for 8
U2 control voltage for 25
U3 control voltage for 35
U4 voltage drop at 8

Claims (13)

1. Electronic two-wire push button ( 1 ), for traffic lights, door openers in rail or road vehicles, for machine controls and the like, with a voltage-controlled, a load circuit ( 7 ) switching element ( 8 ) and with a device ( 10 ) for generating the control voltage (U1), characterized in that the device ( 10 ) for generating the control voltage (U1) has a storage capacitor ( 15 ) which can be charged via a diode ( 14 ) from the load circuit ( 7 ) to the control voltage (U1) and which has a mechanical Touch contact ( 19 ) can be connected to a high-impedance control input ( 9 ) of the switching element ( 8 ). 2. Pushbutton switch according to claim 1, characterized in that the device ( 10 ) for generating the control voltage (U1) consists of a charging circuit ( 12 ) connected in parallel to the switching path ( 11 ) of the switching element ( 8 ), in which the diode ( 14 ) and the storage capacitor ( 15 ) are connected in series, and that the control voltage (U1) is tapped from a circuit point ( 16 ) between the diode ( 14 ) and the capacitor ( 15 ). 3. Key switch according to claims 1 and 2, characterized in that the charging circuit ( 12 ) for the storage capacitor ( 15 ) has a resistor ( 13 ) connected in series with the diode ( 14 ). 4. Push switch according to one or more of claims 1 to 3, characterized in that a resistor (18) in which the touch panel (19) containing driving circuit (17) and that the control voltage (U1) by a voltage-limiting component (20) is limited. 5. Key switch according to claim 4, characterized in that the voltage-limiting component ( 20 ) is connected directly between the circuit point ( 16 ) and the reference potential (U0) or between the control input ( 9 ) of the switching element ( 8 ) and the reference potential (U0). 6. Key switch according to one or more of claims 1 to 5, characterized in that as a switching element ( 8 ) is a self-locking semiconductor device, for. B. MOSFET, thyristor or IGBT is used. 7. Key switch according to one or more of claims 1 to 6, characterized in that a buffer capacitor ( 22 ) is connected between the control input ( 9 ) of the switching element ( 8 ) and the reference potential (U0). 8. key switch according to one or more of claims 1 to 7, characterized by a monitoring circuit ( 24 ) for the on the switching path ( 11 ) of the switching element ( 8 ) falling in the switched-on state voltage (U4), the ( 24 ) when a certain one is exceeded Value of the voltage (U4) causes an immediate blocking of the switching element ( 8 ). 9. Key switch according to claim 8, characterized in that the monitoring circuit ( 24 ) is switched on with a time delay by a delay circuit ( 28 ) relative to the switching element ( 8 ). 10. Key switch according to claim 9, characterized in that the monitoring circuit ( 24 ) has a further electronic switching element ( 25 ) whose load circuit ( 44 ) is connected in parallel to the switching path ( 11 ) of the switching element ( 8 ) that the delay circuit ( 28 ) is connected to the control input ( 9 ) of the switching element ( 8 ) and supplies a control voltage (U2) to the control input ( 31 ) of the switching element ( 25 ) and that from the load circuit ( 44 ) of the switching element ( 25 ) a control voltage (U3) to one Shutdown electronics ( 34 ) for the switching element ( 8 ) is supplied, which is dependent on the voltage drop (U4) on the switching element ( 8 ). 11. Key switch according to claim 10, characterized in that the cut-off electronics ( 34 ) topples from a stable state into a second stable state when a certain value of the control voltage (U3) is exceeded and in this second state the control voltage (U1) of the first switching element ( 8 ) shorts. 12. Key switch according to one or more of claims 1 to 11, characterized in that a filter circuit ( 18 , 22 , 43 ) is inserted between the key contact ( 19 ) and the control input ( 9 ) of the switching element ( 8 ) for damping electrical contact bounce effects . 13. Key switch according to one or more of claims 1 to 12, characterized in that a high-resistance resistor ( 42 ) is connected in parallel to the storage capacitor ( 15 ) in the charging circuit ( 12 ).