DE4020294A1 - Electrical switch for computer or HI=FI system - provides time delays between outputs by clock-driven shift register - Google Patents

Abstract

The electrical switching system is used to provide sequential on and off switching of a number of outputs that are used to operate different equipment modules, such as may be found in a computer or high-fi system. The unit is operated by a single switch (1) and the different outputs are generated with delays set by a potentiometer (7). The main connection unit has sockets (5) for connection to the modules. Internally the unit has a shift register to provide the sequential values. This is driven by an adjustable frequency clock signal. ADVANTAGE - Avoids overload by sequential switching of coupled loads.

Description

The invention relates to an electrical switch, of multiple outputs by operating a single switch can turn on.

With certain electrical devices, it is often the case that you have to switch on all parts individually when switching on, especially with computer or hi-fi equipment. At a Hi-Fi equipment you may need the amplifier, the tape and turn on the turntable one by one. With many (free compiled) computer systems are the different Power switch for monitor (s), printer, plotter, Graphics tablet, modem, etc. very "scattered" and often too arranged difficult to access.

Place all devices on a common power strip and with a main switch should turn on at the same time but should be avoided if possible for the following reasons:

• 1) When the various devices are switched on at the same time become their power supplies or their power transformers at the same time connected to the power grid and cause due to an extreme inrush current that often already it is sufficient to trigger the existing automatic circuit breaker.
• 2) When switching off at the same time, suddenly a right relatively large inductive load (the transformers) from Network separated, with the result that a very high inductive shutdown voltage arises and the individual Devices are at risk from voltage peaks.
• 3) Especially with computer systems, the one below the other of the devices connected by data lines for safety on and off in a certain order tet, the actual computer usually the last device connected to the mains and the last one Device should also be disconnected from the mains.

The object of the present invention is to overcome these disadvantages to avoid and the switch-on preparations for operation to simplify or automate the system.

This problem is solved in that the switch of the Er finding multiple outputs when switching a single scarf ters one by one, with one Time delay between switching on each one Outputs.

Since there are similar problems when switching off, be stands with a preferred embodiment of the present Invention the possibility of the outputs as well (one after the others) with a time delay.

A particularly preferred embodiment of the invention be sits an adjuster with which you enter the time delay poses. In computer systems, it makes sense to set the time delays to adapt to the individual devices because the Hard drives often have different warm-up times. So you can experience the fastest and most reliable Find time delay.

In a further preferred embodiment of the invention the whole switch is installed in a multiple socket, whereby the adjuster is easily accessible from the outside.

Especially with the shift register of the version described tion form of the invention ensures that only one Output can be switched on or off at once, so that the outputs / devices are not only in a certain row order can be switched on and off, but also against Current surges and voltage peaks are protected.

Further preferred features of the invention are:

• i) the time delay is between 0.1 and 10 Seconds, between 0.1 and 5 seconds, more preferably between  0.5 and 2 seconds.
• ii) the number of outputs is between 2-10 before Zugter between 3-6.
• iii) the system is protected against overvoltage.

An embodiment of the invention will become apparent from the following Figures described in detail. It shows:

Figure 1 shows the circuit diagram of the switch.

Fig. 2 is a multiple socket containing the switch of the inven tion.

The electronics can be divided into 4 individual function groups will:

• 1) the control electronics in the upper part of the circuit diagram
• 2) the power section (in the middle of the circuit diagram assigns) with the power relays and the associated Transistor switching stages.
• 3) The remote control with the display and the controls elements (on the lower left edge of the circuit diagram) and in the end
• 4) the power supply (at the bottom right of the circuit diagram).

The control electronics consist of two integrated circuits of the C-MOS family - namely the shift register 4015 (IC 1 ) and 4 NAND gates in IC 2 of the CMOS type 4093 (Schmitt trigger). These circuits are switched as follows:
With the gate IC 2 b, an oscillator was built that oscillates constantly with a clock frequency of about 0.3 to 1 Hz. The frequency is adjustable with the externally accessible adjuster P 1 according to Belie that then the time delay changes. The outer limits of the time delay can be set by changing the values P1s, R2s and / or C2s. The generated clock frequency now controls the clock inputs of the two cascaded shift registers contained in IC 1 (pin 1 and pin 9 of IC 1 ). The data information of the register is set from the remote control with the main operation switch, reaches pin 7 of IC 1 and causes the "OFF" or "ON" at the outputs of the register (Q 1 to Q 7 ). Information "for the power levels (" ON "corresponds logically to" High ").

So the capacities (Q 1 and Q 6 ) are controlled one after the other depending on the switch position of the main switch and cause the power relays (A to F) via the transistors T 1 to T 6 to pick up or drop off. The 6 power levels are identical in function and design and apply the mains voltage to the consumers (RLI to RL VI) or to the outputs of the socket strip via contacts a to f of the corresponding relays.

The outputs of the shift register control the display LEDs in the remote control (LED 1 to LED 6 ) simultaneously with the power stage transistors in such a way that a lit LED also speaks to a connected consumer.

At LED 3 , LED 4 and LED 5 there are switches in the remote control with which it is possible (by applying "low potential" to the base resistors R 15 , R 16 and R 17 ) the power levels Q 3 , Q 4 and pre-program Q 5 or switch it off or on again (by opening this programming switch) after the switch-on sequence has ended.

With this arrangement described so far, the scarf would be with the exception of a special additional function able to.

However, there should be a special display those who have an ongoing "ON or OFF switching phase" with a blinking green LED is indicated. During the two This LED should not be in the idle state of the device (ON or OFF)  to shine.

For this purpose, the first and last output of the shift register IC 1 must be examined for level equality. Only when these outputs are unequal is the sequence in the "on or off phase" and the green LED in the remote control (LED 7 ) is made to flash via a clock generator IC 2 d and an inverter IC 2 a.

The indicated analysis for level equality could be na The easiest way, of course, is with an EXCLUSIVE-OR-GATE reali be settled. However, this was due to space and cost reasons (additional IC) discarded.

The clock generator works in principle exactly like the one already described above, (with the gate IC 2 b) with the difference that at the two inputs (pin 12 and 13) can be stopped with LOW potential.

The "high" detection of the shift register outputs Q 1 and Q 6 is simply accomplished with the NAND gate IC 2 c (pin 8 and 9). After defining a NAND gate, a "low signal" is only generated at the output of IC 2 c if both inputs are controlled with "high". The "low signal" at the IC 2 c / pin 10 would then stop the clock oscillator IC 2 d at pin 12 in this case.

The "low" detection of the shift register outputs Q 1 and Q 6 was realized with the aid of a diode resistor construction. The "auxiliary OR function" works as follows:
Only if "low potential" is present at both outputs Q 1 and Q 6 , is no voltage transmitted to the auxiliary resistor via diodes D 1 or D 2 , so that "low potential" is also maintained at this resistor.

This "low potential" now stops in the "OFF state" of the device via the diode D 3, the clock generator IC 2 d at pin 13. However, as soon as one of the shift register outputs Q 1 or Q 6 a "high signal"", this signal is transmitted to the auxiliary resistor R 3 via one of the diodes D 1 or D 2 and no longer influences the operation of the clock generator via the diode D 3 (in the blocking direction).

The small built-in power pack was specially designed for the needs of the circuit:
The encapsulated printed circuit board transformer generates an open circuit voltage of approx. 20 V (DC) via a bridge rectifier and a filter capacitor of 1000 microfarads.

Due to the current load on all switched on Relay coils break this open circuit voltage at the bridge level converters from approx. 20 V (DC) to approx. 13.5 V (DC) together.

In order to rule out possible overloading of the relay coils during operation, the protective resistor R 26 was connected between the power pack and the "relay load".

This resistance reduces the operating voltage of the relays to an acceptable value of 11.5 V (DC).

The supply voltage of the logic had to be kept constant with a stabilizer, because with changing supply voltage the loading time of the time constant for the clock generator IC 2 b would change too much. This would have resulted in an unreasonable fluctuation in the sequence switching times.

The capacitor C 3 is used only for additional screening of the operating voltage and for possible suppression.

Is located parallel to the primary circuit of the mains transformer another varistor with a limit voltage of 250 V (AC) for  Protection of the system against overvoltages.

In Fig. 2 a multiple socket 6 can be seen which contains the switch 1 of the invention. The switch switches the mains voltage 8 at sockets 5 on and / or off. The manual main switch 3 is located in the remote control 2 , which also has lights 4 , which show whether sockets 5 are on or off. Lamp 9 flashes during the "on or off phase". The time delay can be set using adjuster 7 (potentiometer P 1 ).

Claims (12)

1. A method of switching on several outputs without the outputs, and / or the devices connected to the outputs, being influenced by current surges, characterized in that, when a single switch is actuated, all outputs are switched on one by one, with a specific one Switch time delay between each on. 2. The method according to claim 1, characterized, that when the single switch is operated all outputs are switched off one by one, with a certain time delay between each off switch. 3. The method according to claim 1 or 2, characterized, that the time delay is adjustable. 4. The method according to claims 1 to 3, characterized, that the time delay is between 0.1 and 10 seconds lies. 5. The method according to claims 1 to 4, characterized, that the time delay is between 0.1 and 5 seconds lies. 6. The method according to claims 1 to 5, characterized, that the time delay between 0.5 and 2 seconds lies.   7. The method according to claims 1 to 6, characterized, that the number of outputs is between 2 and 10. 8. The method according to claims 1 to 7, characterized, that the number of outputs is between 3 and 6. 9. A switch with multiple outputs, characterized in that Outputs one when the only switch is turned on be turned on one by one with a certain time delay between each on switch. 10. A switch according to claim 9, characterized in that when the only switch is turned off, the outputs one be turned off one by one with a certain time delay between each off switch. 11. A switch according to claim 10, characterized in that the switch has an adjuster, with which the time delay can be set. 12. A switch according to claim 9, characterized, that the switch is installed in a multiple socket and the outputs each the mains voltage on one of the Sockets connects.