CS266571B2 - Self-regulating glowing device connection - Google Patents

Abstract

Engagement of self-regulating glow the device is used to heat the combustion space of internal combustion engines, in particular Diesel engines and is formed by the control glow plugs and glow plugs, glow plugs they are designed as thermocouples and have a double function: heating the internal combustion engine and sensing temperature. Comparator Control Unit astable multivibrator, amplifier, power amplifiers, electronic power switch, overcurrent protection circuit and circuit to stabilize voltage, it provides uninterrupted power to the glow plugs candles with positive impulses from astable multivibrator and when comparing temperature in the combustion chamber through the fed gas candles, the working conditions being on; using reference voltages.

Description

The subject of the invention is the connection of an autoregulatory glow device for internal combustion engines, in particular for diesel engines. These engines use incandescent devices to achieve thermal conditions for igniting the fuel, the incandescent device preheats the combustion chamber during engine start and then until the engine reaches a predetermined operating condition, the circuit according to the invention automatically regulating the glow plug temperature to a certain extent and for some time. '

It is known to connect an autoregulatory glow device, where after switching on the device the spark plugs are heated to a preset temperature and at this temperature they are then maintained by means of a pulse supply until the alternator voltage reaches a preset value. Pulse power is necessary because the glow plugs need a lower voltage than the battery or alternator. The required temperature of the glow plugs is preset by the value of the analog voltage level and is fed to one input of the comparator. An analog voltage level is applied to the second input of the comparator, which is proportional to the actual value of the temperature of the glow plugs and which is given by a sensor screwed into the engine block. The output of the comparator is generated by input signals and works in the device by pulse supplying the glow plugs. The sensor itself consists of several parts. These are resistors and resistors with a positive temperature coefficient, which are connected in the subassembly of the whole device so as to simulate the temperature of glow plugs as follows: if the spark plugs are powered, part of resistors and resistors with positive temperature coefficient are also supplied, which results that the voltage level at the sensor output rises. As soon as the voltage level from the sensor exceeds the required level on the comparator, the power supply is interrupted, the temperature of the glow plugs starts to decrease, at the same time the voltage on the sensor drops and as soon as it falls below the required level, the power supply is switched on again and this is repeated cyclically. The device switches off as soon as the alternator voltage reaches a preset level, ie as soon as the engine starts running on its own.

Another similar device is known, but it works on a different principle. When the device is turned on, the power to the glow plugs and the oscillator circuit turn on, oscillating at a higher or lower frequency depending on the battery voltage. After about 7 seconds, which corresponds to a certain number of pulses counted by the counter, the power supply is interrupted, that is, the spark plugs have reached the prescribed temperature. To maintain the temperature reached, the glow plug power supply is then pulsed on, so that the oscillator gives longer or shorter voltage pulses depending on the battery voltage, which it supplies via the glow plug amplifier and relay. The length of the pulses is chosen so that the temperature of the glow plugs is maintained at the desired value. However, this electrical circuit is very complicated in determining the temperature of the glow plugs.

The object of the present invention is to provide a circuit which makes it possible to achieve the temperature of the glow plugs or the combustion chamber required to ignite the fuel in a shorter time than with known heating devices, the glow plugs being protected against burning without additional sensors. However, the temperature of the glow plugs should be independent of the supply voltage and the glow plugs should heat the combustion chamber even after the engine has started, until it reaches the minimum operating conditions. '

The circuit of the self-regulating glow device according to the invention consists of a control unit and glow plugs which are designed to operate as a thermocouple when not supplied with electricity, the thermoelectric voltage serving the unit periodically determines the supply of electrical energy to the glow plugs according to the magnitude of the thermoelectric voltage as the input value, thus ensuring that the spark plugs glow in a certain temperature range lower than the overburden temperature until the engine reaches the minimum operating conditions. as part of the connection to the autoregulatory glow device according to the invention, it is designed for a lower voltage than the whole connection in such a way that when it is not supplied with electricity, its glow element works as a thermocouple, the positive pole being either on the electrode or on the electrode. sleeve and is made known and can be single- or bipolar. Given the above

CS 266 571 B2 properties can be used to control or measure the engine temperature during continuous operation or indirectly to control the combustion efficiency of the fuel in the combustion chamber.

The invention will be explained in more detail on the basis of an exemplary embodiment and FIG. 1, which shows the connection of an autoregulatory heating device, and FIG. 2, which shows a working diagram of the connection according to the invention. The connection of the self-regulating glow device according to FIG. 1 consists of a control unit B and glow plugs A. FIG. 2 shows the connection function of the self-regulating glow device. The temperature profile of the glow plug and the operation of the power switch are shown, wherein in position 1 the power switch is closed and in position 0 it is switched off. The relationships in the operating diagram of the power switch mean: This is the time in which the spark plug temperature reaches the set value, Tb is the time for which the power switch is closed or experimentally set, Tc is the interruption time when the glow plug temperature drops to the set value.

The control unit consists of the following elements: voltage comparators 1, 2 ', astable multivibrator 6, amplifier 6, power amplifier 6, electronic power switch 6, overcurrent protection 6, voltage stabilization circuit 10 and associated resistors and capacitors forming reference voltages, the purpose of which will be explained in the description of the circuit function according to the invention.

When the contact of switch S, which may be formed by a known motor starter switch or other single-pole switch-switch, is closed, the battery voltage AK is applied to the voltage stabilization circuit 10. Thus, the entire control unit B receives voltage and all reference Uref 1, Uref 2, Uref 3 are set to a predetermined value. A certain voltage is generated at the output of the comparator 2, which is fed to the input of the astable multivibrator £. This voltage blocks the function of the astable multivibrator 6 by displaying a voltage at its output which activates the power amplifier 6, which then closes the power switch S, which connects the glow plugs A via the overcurrent protection 9 to the battery AK. At the same time, the voltage at the output of the comparator 2 is applied to the power amplifier 2, so that the control lamp Z at its output lights up. '

The glow plugs A are supplied as long as the voltage on capacitor C2, which is connected via resistor R2 and switch S to battery AK, reaches Uref 2. Voltage Uref 2 is connected to input b, but the voltage on capacitor C2 is connected to input a At this point, the comparator 2 changes the voltage level at its output so that it no longer affects the operation of the astable multivibrator £, which disconnects the power switch 8 via the power amplifier 6, with the result that the glow plugs A are also disconnected and the control lamp goes out. Z. This is also a sign that the engine is ready to start.

When the glow plugs A are supplied, the output voltage of the amplifier £ affects the input of the comparator 2 in that the output of the comparator 2 does not affect the function of the multivibrator £ via the input c of the astable multivibrator 6. When the power supply to the glow plugs A is interrupted (U _c2 = Uref 2), a thermoelectric voltage is generated at the input of the amplifier 5, which generates the glow plugs A, because they work as thermocouples after the power supply is interrupted. This thermoelectric voltage, about 30 mV, is amplified in the amplifier 5 and fed to the input a of the comparator 2 · ^{in the} comparator 2 ^the thermoelectric voltage from the input a is compared with the input voltage b, which is the set reference voltage Uref 1. proportional to the temperature of the glow plug required to ignite the fuel. When the power supply to the glow plugs A is disconnected, an amplified thermoelectric voltage is generated at the input and comparator 2, proportional to the instantaneous temperature of the glow plugs, which is higher than Uref 1. This results in a voltage at the output of comparator 2 the function of the astable multivibrator £. If the amplified thermoelectric voltage at the input and comparator 2 drops ^{to the} value Uref 1, the output of comparator 2 assumes this voltage level and the astable multivibrator £ opens via input c. This exerts positive pulses on the power amplifier 6, which controls the power switch 8. The length of the positive pulses of the astable multivibrator 6 is chosen so that usually only one pulse is needed to increase the temperature of the glow plugs A, which is lower than the firing temperature; however, it also exceeds the amplified thermoelectric voltage Uref 1. At the time of the negative pulse at the output

CS 266 571 B2 astable multivibrator and ^repeats the previously described comparison operation with enhanced thermoelectric voltage Uref 1, resulting in that the output of the comparator and a voltage level which is the result of comparing the input. If the glow plugs A do not reach the specified temperature after a positive pulse, the amplified thermoelectric voltage is lower than Uref 1 and the output of the comparator _ in comparison! does not affect the operation of the astable multivibrator 4, so that the glow plugs are further supplied with one or more successive pulses and as a result the temperature of the glow plugs A and thus the amplified thermoelectric voltage rises to the level determined by Uref 1.

It follows from the description that the glow plugs A reach the temperature required to ignite the fuel when the switch S is turned on, after which this temperature will be maintained by the pulse supply of the glow plugs. This may, of course, take longer, but this process will stop, as will be described below, if the engine reaches its minimum operating condition.

When the switch S is closed, the voltage level at the output of the comparator 2 is such that it does not affect its function via the input b of the astable multivibrator 6. At the same time, capacitor C3 is charged via resistor R3 up to the value Uref 3, the amount of which depends on the ambient temperature of the motor or on the motor temperature, which depends on the setting of the temperature sensor, for example resistor R5 with a negative temperature coefficient. The voltage Uref 3 is applied to the input b and the voltage to C3 to the input and of the comparator 3ΐ · When the condition U ^ = Uref 3 is met, such a voltage level appears at the output of comparator 2, which prevents its operation power supply of glow plugs A.

If there is a fault in the glow plug power supply circuit, which results in an increase in current above the normally allowed value, the overcurrent protection circuit is activated which via the output and immediately charges capacitor C3 to such a value that the condition U1 = Uref 3 is met and thus the power supply to the glow plugs is interrupted as previously described. The astable multivibrator 4 is designed in such a way that its inputs a, b, c behave as a function of OR, i.e. the presence of a certain voltage level at any input a or b or c causes a change of state at the output.

The glow plugs A are drawn in parallel in FIG. 1, more or fewer glow plugs can also be used according to the number of cylinders in the engine, or they can be arranged in series in a two-pole design.

The connection of the self-regulating glow device according to the invention requires significantly less time to reach the required temperature for igniting the fuel, about two seconds compared to known connections where this time is about seven seconds, the temperature of the glow plugs manifests itself when the starter is switched on, the glow plugs are switched on after the engine has started until it reaches the minimum operating conditions, no external sensors simulating the temperature are needed to control the spark plug temperature and the connection is relatively inexpensive due to the advantages offered.

Claims (1)

Connection of an autoregulatory glow device consisting of a control unit B and glow plugs A, characterized in that the glow plugs (A) designed as thermocouples are connected via an electronic power switch (8) and an overcurrent protection circuit (9) to that battery terminal (AK). ), which is connected via a switch (S), a voltage stabilization circuit (10), via a series circuit of resistors (RI, R4) and a negative coefficient resistor (R5), via a series circuit from a resistor (R3) and a capacitor (C3). ) to ground, and via resistor (R2) and capacitor (C2) to ground, the contact point of resistor (R2) and capacitor (C2) being connected to input (a) but terminal (Uref 2) to input (b) of comparator (2), and wherein its output is connected to the input of the power amplifier (7) and to the input (a) of the stable multivibrator (4) and the output of the power amplifier (7) is connected via a control lamp (Z) to ground, while the contact point of the resistor (R3) and a capacitor (C3) is connected to input (a), but a terminal (Uref 3) to input (b) of comparator (3), the output of the comparator (3) is connected to the input (b) of the astable multivibrator (4), the glow plugs (A) are connected via an amplifier (5) to the input (a), but the terminal (Uref 1) to the input (b) of the comparator (1) ), the output of the comparator (1) is connected to the input (c) of the astable multivibrator (4) via a power amplifier (6) to the electronic power amplifier (8) and the output (a) of the overcurrent protection circuit (9) to the input (a) of the comparator ( 3).