RU2365776C1 - Control device for electromagnetic nozzles - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: invention refers to the field of transport mechanical engineering, specifically to fuel supply system for internal-combustion engine. The device contains two electronic switches and control circuit. The first electronic switch is connected between negative power bus and nozzle. The second electronic switch is connected with negative power bus and control inputs of electronic switches are connected with control circuit. Inductance coil, the first and the second resistances, the first and the second diodes are additionally introduced into the device. The second lead of the second electronic switch is connected with inductance coil, the second lead of which is connected to positive power bus. The second lead of the second electronic switch is connected with anode of the first diode. Cathode of this diode is connected with the second lead of the nozzle, the second resistance and cathode of the second diode. Anode of the second diode is connected with the first resistance. The second lead of the first resistance is connected with positive power bus. The second lead of the second resistance is connected with negative power bus.

EFFECT: increase in operation speed of electromagnetic nozzles.

1 dwg

Description

The invention relates to the field of transport engineering, in particular to a fuel supply system for an internal combustion engine.

A fuel supply device for an internal combustion engine [1] is known, comprising a high pressure fuel line, electromagnetic nozzles and a microprocessor control circuit, which includes electronic control keys.

The disadvantages of the fuel supply device for the internal combustion engine is the low response speed of the electromagnetic nozzles.

Closest to the proposed invention is a device for controlling electromagnetic nozzles [2], containing two electronic keys, a resistance and a control circuit, the first electronic key connected between the negative power bus and the nozzle, the second electronic key connected to the negative power bus, and the control inputs of electronic keys connected to the control circuit.

The disadvantages of the known device for controlling electromagnetic nozzles is the low response speed of the electromagnetic nozzles.

The technical result is aimed at increasing the response speed of electromagnetic nozzles.

The technical result is achieved in that in a device containing two electronic keys and a control circuit, wherein the first electronic key is connected between the negative power bus and the nozzle, the second electronic key is connected to the negative power bus, and the control inputs of the electronic keys are connected to the control circuit, wherein an inductor, a first and second resistance, a first and a second diode are additionally introduced into the device, the second terminal of the second electronic key being connected to the inductor, the second terminal of which the swarm is connected to the positive power bus, the second terminal of the second electronic key is also connected to the anode of the first diode, the cathode of which is connected to the second output of the nozzle, the second resistance and the cathode of the second diode, the anode of which is connected to the first resistance; the second terminal of the first resistance is connected to the positive power bus, the second terminal of the second resistance is connected to the negative power bus.

Distinctive features of the prototype is that an inductance coil, first and second resistances, first and second diodes, as well as the presence of new connections between newly introduced and previously used components of the device are additionally introduced into the device.

The drawing shows a functional electrical diagram of the proposed device.

The electromagnetic nozzle control device comprises two electronic keys 2 and 3, a control circuit 4, the first electronic key 3 being connected between the negative power bus and the electromagnetic nozzle 1, the second electronic key 2 connected to the negative power bus, and the electronic key control inputs 2 and 3 are connected with a control circuit 4, an inductor 5, the first 8 and second 7 resistance, the first 6 and second 9 diodes, and the second output of the second electronic switch 2 is connected to the inductor 5, the second output of which is connected to the positive supply rail and the second terminal of the second electronic key 2 is connected to the anode of the first diode 6, the cathode of which is connected to the second terminal of the electromagnetic injector 1, the second resistor 7 and the cathode of the second diode 9, the anode of which is connected to the first resistor 8; the second terminal of the first resistance 8 is connected to the positive power bus, the second terminal of the second resistance 7 is connected to the negative power bus.

The control device of the electromagnetic nozzles operates as follows.

For some time t before the arrival of the pulse to turn on the electromagnetic nozzle 1 from the control circuit 4, the electronic keys 2 and 3 are closed. This time is necessary so that the inductor 5 has time to store enough energy for the subsequent operation of the electromagnetic nozzle 1. At the moment the electromagnetic nozzle 1 is triggered, a pulse closes the electronic key 2 from the control circuit 4, while the energy stored in the inductor 5, through the first diode 6 enters the second resistance 7 and the electromagnetic nozzle 1. The induction EMF is determined by the equation

E = -dF / dt,

where E is the induction emf, B;

Ф - magnetic flux, Wb.

Therefore, the slew rate of the current through the electromagnetic nozzle 1 at the time of switching is determined by the ratio

dI / dt = U / L,

where dI / dt is the slew rate of the current, A / s;

L is the inductance of the electromagnetic nozzle, G;

U is the voltage at the electromagnetic nozzle 1, V.

The voltage at the electromagnetic nozzle 1 is approximately equal to the ratio

U = I ₅ R ₇ ,

where I ₅ is the current through the inductor 5 at the time of switching, A;

R ₇ - resistance value 7, Ohm.

As the calculation shows, with known ratios of the circuit parameters, the transition process has the character of a damped sinusoid, proceeds quite quickly, and currents can take large values [3], which ensures the operation of electromagnetic nozzle 1 with an increased speed. In this case, the first resistance 8 and the second diode 9 provide the open state of the electromagnetic nozzle 1 until the end of the pulse from the control circuit 4, which closes the electronic key 3.

A comparative analysis of the claimed device with the existing technical solutions shows that the claimed device allows to increase the response speed of electromagnetic nozzles by an order of magnitude.

Information sources

1. Chizhkov Yu.P. Electric equipment of cars [Text]: textbook / Yu.P. Chizhkov, S.V. Akimov / Ed. M. Biryukov, E. Pevzner. - M.: The Publishing House "Behind the Wheel", 2005. - 336 p.

2. A.S. 1559214 USSR, IPC F02D 41/20. The control device of the electromagnetic nozzle [Text] / V.E. Kuzin (USSR). - No. 4412837/25 declared 04/21/88; publ. 04/23/90, Bull. No. 15.

3. Seebeck, G.V. The basics of circuit theory [Text]: textbook / Zeveke G.V. et al. - Ed. 5th, add. and reslave. - M .: Energoatomizdat, 1989 .-- 528 p.

Claims (1)

An electromagnetic nozzle control device comprising two electronic keys and a control circuit, the first electronic key being connected between the negative power bus and the nozzle, the second electronic key connected to the negative power bus, and the electronic key control inputs connected to the control circuit, characterized in that the device additionally introduced an inductor, a first and second resistance, a first and a second diode, the second terminal of the second electronic key connected to the inductor, the second A output of which is connected to the positive supply rail, a second terminal of the second electronic switch is connected to the anode of the first diode, the cathode of which is connected to a second terminal of the injector, the second resistor and the cathode of the second diode, the anode of which is connected to a first resistance; the second terminal of the first resistance is connected to the positive power bus, the second terminal of the second resistance is connected to the negative power bus.

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