CS229841B1 - Connexion of automatic switching of computer peripheral units - Google Patents

Description

These drawbacks are eliminated by the circuitry for automatically turning on and off the peripheral of the computer according to the invention, which consists in that the interface card is connected by the first input to the computer and the first output through the peripheral to the semiconductor switch. , to the second input of the three-input product gate, to the input of the pulse extender, to the first input of the two-input product gate, and to the switch whose first output is connected to the second input2 interface of the interface card. an inverter circuit, the output of which is connected to a second input of a two-input synergic gate connected by an output to the input of a monostable flip-flop, wherein the inputs of the second delay circuit and the inverter are connected together to an applying a pulse and through a first delay circuit to a second input of a two-input summation gate whose output is coupled via an optoelectronic jumper and a neutral switch to a semiconductor switch whose second input together with a second neutral switch input are connected to a computer and a power outlet; it is connected to the second input of the optoelectronic coupler.

The advantage of the circuitry according to the invention is the automatic switching on of the peripherals of the computer, and only for the time during which the peripheral is used immediately. The invention is particularly advantageous in economics where computing systems are used for a long or continuous period of time, since implementation saves energy, extends peripheral life and delays between repairs. Maintenance costs are reduced, operation is easier; last but not least, under229841

29 8 41 significantly reduces noise, improving the working environment. It is also beneficial that the peripheral can be disconnected even during the operation of the computing system, so that in the event of any failure it is not necessary to shut down the entire system. The implementation of the invention does not require intervention in the peripherals, only some peripherals, for example, adjust the printer sc so that it is brought into the connected state after the mains voltage is switched on.

In order to clarify the nature of the invention, the circuit according to the invention is schematically shown in the accompanying drawing, wherein FIG. 1 is a block diagram of the circuit and FIG.

The circuitry for automatically turning on and off the peripheral of the computer in Fig. 1 is a two-input product gate 4, the first input 41 of which is connected to an interface card 2, which is connected to the computer 1 output. the input 32 of the three-input product gate 3, with the first input 131 of the two-input sum gate 13, with the input of the pulse extension 10 and the switch 8, which is connected one output to the output 34 of the three input product gate 3 and the interface card 2 and the other output to the optoelectronic coupler 14 The output of the pulse extension 10 is coupled to the input of the second delay circuit 6, the input of the first delay circuit 12, and the input of the inverter 7, the output of which is connected to the second input 42 of the dual input gate 4, output 43 of which is connected to the monostable flip-flop 5. Outlet The monostable flip-flop 5 is connected to the first input 31 of the three-input gate 3, whose third input 33 is connected, to the output of the second delay circuit 6. The interface card 2 is further connected to the periphery 9. The second input. 132 of the dual input gate 13 is coupled to the output of the first delay circuit 12, and its output 133 is coupled to an optoelectronic coupler 14, the output of which is coupled to a null switch 16 coupled to a semiconductor power switch 15 connected to a peripheral 9. Computer, null switch 16 and semiconductor ^; the power switch 15 is connected via its input to a mains socket, to 11.

The function of automatic switching on and off of the computer peripheral is evident from the time diagrams shown schematically in Fig. 2. Before beginning any communication with the peripheral, the computer sends a so-called "C" bit, which creates the interface card 2. 13 is applied to the optoelectronic coupler 14 and causes the zero switch 16 to switch on and off only when the line voltage passes through zero, which is essential to eliminate the disturbing effects of current and voltage peaks generated by the inductive load represented by the periphery 9. At the moment of the arrival of the "C" bit on the first input 41 of the two-input gate 4, 42 is on its second input. 1 for as long as the "C" bit has tripped the monostable flip-flop 10, which is wired as the pulse extension and before it passes through the inverter 7. After this time, a log appears at the second input 42 of the dual-input gate 4. Therefore, a short pulse occurs at the output 43 of the two-input product gate 4, which throws in a monostable flip-flop 5 that generates a pulse TI that blocks na1 of the three-input product gate 3 so that the "C" bit does not get through the interface card The time ΔΤ1 can be set to stabilize the supply voltage for the electronics of peripheral 9 after it is connected to the mains voltage. At the moment of the arrival of the "C" bit on the second input 32 of the three-input product gate 3, this gate is blocked by the third input 33, which is in log. 0 for the time T3, which is the time during which the first log 31 appears. 0. After ΔΤ3 since the arrival of the first “C” bit, the third input 33 receives a log. 1 from the pulse extension 10 through the second delay circuit 6. During this time ΔΤ1 since the arrival of the first "C" bit, the three-input product gate 3 surrounds itself and controls the pulses can pass through the interface card 2 on the peripheral 9. longer than ΔΤ2, the three-input product gate.3 is disabled by log. 0, supplied from pulse extender 10. This log. 0, via the first delay circuit 12, it reaches the second input 132 of the two-input suction gate 13 and causes the peripheral 9 to be disconnected from the mains voltage. The time ΔΤ2 can be set so as not to immediately switch off the periphery 9 during short periods of operation. Switch 8 is used to disable automatic switching. The optoelectronic coupler 14 serves to galvanically isolate the network part from the signal part.

The wiring to automatically turn the computer peripheral on and off can be advantageously used especially for peripherals such as punch tape or label reader, puncher, electronic typewriter, telex, printers and magnetic tape units, and wherever computer peripherals are permanently used.

Claims (1)

Subject Circuit for automatic switching on and off of a computer peripheral, characterized in that the interface card (2) is connected by a first input to the computer (1) and a first output via the peripheral (9) to the semiconductor switch (15) while the second output is connected to a first input (41) of a two-input product gate (4j), a second input (32) of a three-input product gate (3), an input of a pulse extension (10), a first input (131) of a two-input total gate (13) and a switch (8) whose first output is connected to the second input of the interface card (2) and simultaneously to the output (34) of the three-input product gate (3), the third input (33) of which is connected via a second delay circuit (6) to the inverter (7). the output is connected to the second input (42) of the two-input product gate (4) connected by the output (43) to the input of the monostable flip-flop (5), the inputs of the second delay circuit The inverter (7) and the inverter (7) are connected together to the pulse extension (10) and via a first delay circuit (12) to a second input (132) of a two-input summation gate (13) whose output (133) is connected via an optoelectronic connection. a member (14) and a neutral switch (16) to a semiconductor power switch (15), the second input of which together with the second neutral switch input (16) are connected to a computer (1) and a mains socket (11); ) is connected to the second input of the optoelectronic coupler (14).