DE4036376A1 - Temp.-dependent starting control for fuel pump of diesel engine - has temp. switch to control coil excitation and operate injection pump - Google Patents

Abstract

The fuelling control of a compression ignition engine is provided during start-up by displacement of a control rod (13) dependent on temp. The rod is displaced (15) by moving a pivoted lever (12) coupled to the core (10) of an e.m. actuator (1). The actuator coil is connected into a circuit that has either a PTC device or a bimetallic switch that can be used to provide excitation at a specific temp. to commence fuelling. ADVANTAGE - Automatic control of fuel injection pump without wear.

Description

The invention relates to a device for temperature pending start control for an injection pump a self-igniting internal combustion engine according to the Oberbe handle of claim 1.

From DE-OS 26 19 055 is a speed controller for one Injection pump known with a rule limit the injection pump rod to full load movable stop is equipped. This full load on blow during the starting process of the internal combustion engine machine from an electrically excitable coil with an in the coil arranged core, the interposed a temperature-dependent control element with the stop connected, attracted against the force of a spring. There with becomes an additional start quantity during the starting process Approved.

This arrangement has the disadvantage that the temperature dependent setting of the starting excess quantity with a an inclined surface locking slide he follows that over the full connected to the control rod load stop slides along. The control rod is with the Full load stop connected and the locking slide with a sloping surface for temperature-dependent start multi-volume control, since the spool only on the front  glow or start process of the internal combustion engine excitable is switched on. Because of this arrangement mechanical wear at the locking point slide / full load stop given. It also works temperature-dependent start-up control Expansion element with a time delay and is sensitive to damage. Furthermore, the Ver Setting characteristic of the expansion element does not set bar.

The invention has for its object a device for starting multi-volume control on an injection pump to provide a self-igniting internal combustion engine, that works temperature-dependent and wear-free.

This object is achieved in that the coil with a temperature-dependent element and with a DC chip voltage source is electrically connected, so that the current through the coil of the temperature dependent element is controlled.

This arrangement has the advantage that the control of the Starting additional quantity for the self-igniting internal combustion engine is temperature-dependent and works without wear. In addition, the control rod does not require any additional Components such as B. a full load stop. By ver The use of the temperature-dependent element may vary Characteristic of the element, the adjustment characteristic and so on can be set with the start oversize control. The Start control can be dependent on the Coolant, oil, or cylinder head temperature or depending on other suitable temperatures.  

In one embodiment, the coil is with temperature dependent element in series with the DC voltage source interconnected, which ver ver is wrestled.

In a development of the invention, this is temperature-dependent Element designed as a PTC thermistor. That cold lie ter is connected in series with the coil. Because the stream through the coil inversely proportional to the series resistance is that of the resistance of the PTC thermistor and the Coil exists, the current and thus the magneti decrease the coil's force with increasing temperature. The result is that with increasing temperature the Starting excess is withdrawn because the core in the Coil that acts on the control rod from the spring the spool is pushed out. Because the one in the circuit flowing current is proportional to the resistance of the PTC thermistor. Since this is a function of temperature, the flowing current thus also represents a function of the Temperature represents. But since the magnetic force by the flowing current is set, this is ultimately also dependent on the temperature. Additional advantages of the PTC thermistor consists in the fact that the without time Delay works and insensitive to damage is. It is also possible to construct the PTC thermistor to integrate in the coil.

In a development of the invention, this is temperature-dependent Element designed as a bimetal switch. To this end the current through the coil with the bimetal switch depending on a temperature of the internal combustion engine ne, e.g. the oil temperature, switched on or off. Also here it is advantageous that the bimetal switch only with  a small time delay works and the Adjustment characteristic of the bimetal switch by the Use of different materials can be influenced can.

In a development of the invention, this is temperature-dependent Element designed as a thermistor (NTC) and via an In verter circuit connected to the coil. The usage a thermistor has the advantage that due to the characteristic line of the thermistor of the control area (temperature rich) is very large and with the NTC components offered there is a greater choice. An one fold inverter circuit consists essentially of one Series resistor and a transistor. For this purpose the thermistor with the series resistor as a voltage divider switched, the output voltage of the voltage part is tapped on the thermistor and the base of the Transistor is supplied. The collector of the Transistor over the coil with a pole of voltage source interconnected while the emitter of the transistor is connected to the other pole of the voltage source which the thermistor is also attached to. As protection is parallel a free-wheeling diode is provided for the coil, which the induc active voltage peaks extinguishes (short-circuits). With this circuit, the collector current is a function the base voltage of the transistor. At the same time it is Base voltage of the transistor also a function of the Wi the state of the thermistor. Because the resistance of the hot things ters a function of temperature, it follows that the collector current of the transistor also a function represents the temperature. Because the magnetic force of the Coil, which is required for the control of the starting quantity, is a function of the collector current of the transistor , it follows that the magnetic force of the  Coil is a function of temperature. So that is Start-up control via the inverter circuit for the self-igniting internal combustion engine with a hot leader possible.

Further embodiments of the invention are the drawings refer to.

Show it:

Fig. 1 shows an inventive device with a PTC thermistor,

Fig. 2 shows an inventive device with a bimetal switch,

Fig. 3 shows a device according to the invention with a hot conductor,

Fig. 4 is an inverter circuit,

FIG. 5a is an embodiment of the device with a compression spring in full-load position,

Fig. 5b is an embodiment of the device with a compression spring in an overload position,

FIG. 6a shows a design of the apparatus with a tension spring in full-load position,

Fig. 6b shows a design of the apparatus with a tension spring in an overload position,

Fig. 7a shows an embodiment of the device in which the center of the coil is mounted in a coaxial direction to the control rod, in a full load position,

Fig. 7b an embodiment of the device in which the means of the coil is brought to the control rod is in an overload position.

Fig. 8a is an embodiment of the device with an angle lever no-load position,

Fig. 8b an embodiment of the device with an angle lever in the overload position.

Fig. 1 shows an inventive apparatus with a thermistor. An electrically excitable coil denoted by 1 is electrically connected in series with a DC voltage source 3 via a PTC thermistor 2 (PTC). This interconnection results in the advantages mentioned in the description for the control of large quantities. In addition, the characteristic of the PTC thermistor can be set and changed by adding a series resistor (in parallel or in series with the PTC thermistor). For test bench - and other purposes - the series resistor can also be designed variably (potentiometer).

Fig. 2 shows an inventive device with a bimetal switch. The electrically excitable coil 1 is electrically connected via a bimetallic switch 4 to the direct voltage source 3 . Here, as in FIG. 1, the advantages mentioned in the description result. The contact of the bimetal switch 4 is designed as an opener.

Fig. 3 shows an inventive apparatus with a thermistor. In this device according to the invention, an inverter circuit 6 is connected on one side to the DC voltage source 3 , while on the other side of the inverter circuit 6 the electrically excitable coil 1 and a thermistor 5 (NTC) are connected. Through the use of the inverter circuit 6 , it is possible to use the thermistor 5 for controlling the starting quantity of the self-igniting internal combustion engine.

Fig. 4 shows for this purpose an exemplary configuration of the inverter circuit 6. The thermistor 5 forms a voltage divider with a series resistor 7 , which is connected on the input side to the DC voltage source 3 . The output voltage of the voltage divider is tapped at the thermistor 5 and fed to the base of a transistor 8 . In the collector circuit of the transistor 8 , which is connected to one pole of the voltage source 3 , there is the electrically excitable coil 1 , while the emitter of the transistor is connected to the other pole of the DC voltage source 3 . A freewheeling diode 27 is connected in parallel with the coil 1 and extinguishes the inductively caused voltage peaks. The anode of the freewheeling diode 27 is connected to the collector of the transistor 8 . Depending on the type of thermistor 5 used , the setting characteristic of the starting additional quantity can be optimally adapted to each type of internal combustion engine. A further setting option is to replace the series resistor 7 with another series resistor or to design it as an adjustable series resistor (potentiometer). In addition, the parallel or series connection of another Wi resistor to the series resistor 7 is conceivable. At this point it should be mentioned that other inverter circuits (for example implemented using an operational amplifier) can also be used.

FIG. 5 shows an embodiment of the device with a compression spring, a full-load position of a control rod 13 being shown in FIG. 5a and an overload position of the control rod 13 being shown in FIG. 5b. Fig. 5a shows the electrically excitable coil 1 , which is U-shaped and has lungs 9 . In the middle of the two legs of the coil 1 there is a core 10, wherein between the core 10 and the transverse leg of the coil 1 is a compression spring. 11 The core 10 acts on a control rod 13 via a lever 12 . For this purpose, the core 10 and the lever 12 are connected to one another via pivot points 14 and are adjustable by the coil 1 . A compression spring 26 is for further movement of the control rod 13 beat on this and is supported against a fixed end. An arrow denoted by 15 indicates the direction of movement of the re gel rod 13 . In Fig. 5a the control rod 13 is located in full load position a. To reduce example, the speed or the amount of fuel injected or generally to adjust the control rod 13 between the full load position and a zero load position, the control rod 13 is movable by a speed controller, not shown, in the minus direction. For setting a starting quantity, the coil 1 is, for example, fourth-acti from one of the devices shown in Fig. 1 to Fig. 4, so that the core 10 against the force of the compression spring 11 in the direction shown 5b is moved in Fig.. Since the lever 12 rotates about the pivot points 14 so that the control rod 13 moves in a plus direction denoted by 15 , thereby releasing a starting quantity. After reaching a certain temperature of the internal combustion engine, which is detected by the PTC thermistor 2 , the Bime tall switch 4 or the thermistor 5 , the starting excess is withdrawn in such a way that the current through the coil 1 is controlled so that the magnetic force of the Coil subsides and the core 10 is moved by the compression spring 11 such that the lever 12 and there with the control rod 13 again the full load position. The control rod 13 is moved by the compression spring 26 in the full load direction. It should be taken into account that in the full-load position, the forces acting on the lever 12 from the control rod 13 are compensated by the compression spring 11 and the compression spring 26 , so that the full-load stop is formed by the balance of forces of the compression springs 11 and 26 becomes. In addition, the balance of forces can be supported by an adjustable residual current through the coil 1 . In a position below the full load position (for example between full load and zero load), the control rod 13 is no longer in connection with the lever 12 , since this, held by the compression spring 11 and / or the magnetic force of the coil 1 , is shown in the Full load position remains.

Figs. 6a and 6b show an embodiment of the Vorrich tung with a tension spring. Fig. 6a shows the control rod 13 in a full load position, while in Fig. 6b the re gel rod 13 is in an overload position. The core 10 acts on the lever 12 , which is supported at the pivot points 14 , on the control rod 13 . After activating the coil 1 (current flow controlled by the windings 9, from one of the devices shown in Fig. 1 to Fig. 4), the core 10 of the coil 1 against the force of a tension spring 16 which is hinged at a fixed end, moved in the direction of the starting surplus. The control rod 13 is pivotally mounted on pivot arms 17 , so that Rei loss losses when adjusting the control rod 13 in one of the directions of movement 15 are minimized. For this purpose, the lever 12 is provided with a stop plate 19 , the stop plate 19 being connected to the lever 12 via a pivot point 18 . This ensures that when the lever 12 rotates around the pivot points 14, the end of the control rod 13 is always on the stop plate 19 , whereby wear and friction are kept low. It should also be taken into account here that the control forces acting on the lever 12 via the control rod 13 are at least compensated for by the force of the tension spring 16 or the magnetic force of the coil 1 in the full load position. The pivot point 18 is advantageously designed as a roller in order to compensate for the relative movement of the moving parts. The kinematics because of the lever 12 and the pivot arms 17 should have the same lengths or the same angular positions. If this is not the case, the pivot point 18 can be designed as a coupling piece with two joints, for example.

Fig. 7 shows an embodiment of the device in which the center of the coil 1 is attached in the coaxial direction to the control rod 13 . Depending on the design of the internal combustion engine and its components, it is part of before to bring the coil 1 in extension of the control rod 13 . The core 10 located between the legs of the coil 1 is magnetically attracted against the force of the compression spring 11 as a function of an internal combustion engine temperature by the windings 9 , or is pressed out of the coil 1 . In this way, a movement of the control rod 13 takes place in one of the directions denoted by 15 . Fig. 7a shows a full-load position of the control rod 13 , a movement of the control rod 13 in the minus direction, which is caused by a controller, not shown, a reduction in speed or a decrease in the amount of fuel injected, that is, for example, a setting between full load and No load, causes. Fig. 7b shows an overload position of the control rod 13. The setting of the starting additional quantity takes place in such a way that the core 10 is attracted by the magnetic force of the coil 1 against the force of the compression spring 11 . A mechanical stop of the control rod 13 , which limits the maximum starting additional quantity, is given by the end of the U-shaped leg of the coil 1 . A one-time setting of the maximum starting additional quantity stop can take place through the constructive choice of the length of the U-shaped legs of the coil 1 , the length of the core 10 or through the use of different types of compression springs 11 . The maximum starting additional quantity and / or the full load position can also be set once by moving the coil 1 in one of the directions of movement 15 . Thus, the maximum additional starting quantity and / or the full-load stop for each internal combustion engine type can be optimally adjusted by mechanically carrying out the measures mentioned above or by changing the electrical components (PTC thermistor, thermistor, bimetal switch or inverter circuit) and be adjusted.

The full load stop is given in this embodiment of the direction by the position of the core 10 in the coil 1 . It can be influenced by the spring force of the compression spring 11 and / or by the magnetic force of the coil 1 , which is adjustable via the current through the windings 9 .

Fig. 8a shows an embodiment of the apparatus with an angle lever no-load position. To set the starting additional quantity of the control rod 13 , an angle lever 20 is attached between the two legs of the coil 1 , where the compression spring 11 is applied to the angle lever 20 . The end of the angle lever 20 facing away from the coil represents a zero-load stop of the control rod 13 , where it must not only be a zero-load stop, but also a partial-load position is possible. The compression spring 26 is attached to the control rod 13 .

By a control device, not shown, and the compression spring 26 , movement of the control rod 13 in the direction of movement 15 is possible up to a position in which the control rod 13 arrives at a resilient control rod stop 21 . The full-load stop is formed by the balance of forces of the compression springs 24 and 26 . The fe dernde control rod stop 21 has a stationary outer sleeve 22 which takes a movable inner sleeve 23 on. The inner sleeve 23 receives a compression spring 24 which is supported against the outer sleeve 22 .

Fig. 8b shows an embodiment of the apparatus with an angle lever in an overload position. For setting the starting quantity (overload) is activated, the coil 1 of one of the devices shown in Fig. 1 to Fig. 4 depending on temperature, so that through the windings 9, a current flows and a magnetic force acts on the angle lever 20 a. From this magnetic force, the angle lever 20 is attracted against the force of the compression spring 11 , so that the angle lever 20 moves from the zero load position shown in FIG. 8a into the overload position shown in this figure. This displacement of the control rod 13 in the plus direction of movement 25 compresses the compression spring 24 of the resilient control rod stop 21 . This increases the control rod travel compared to the full load position, so that an additional starting quantity is released. After a certain temperature of the internal combustion engine has been reached, the angle lever 20 moves into its no-load position and the speed control can take place via the controller device, not shown.

Claims (8)

1. Device for temperature-dependent start more quantity control for injection pumps of a self-igniting internal combustion engine with an electrically excitable coil ( 1 ) having a core ( 10 ) acting on a control rod ( 13 ) of the injection pumps, the core ( 10 ) from the coil ( 1 ) can be tightened against the force of a spring to release a starting additional quantity, characterized in that the coil ( 1 ) is electrically connected to a temperature-dependent element and to a DC voltage source ( 3 ). 2. Device for temperature-dependent Startmehrmen gene control according to claim 1, characterized in that the coil ( 1 ) is electrically connected to a temperature-dependent element in series with a direct voltage source ( 3 ). 3. Device for temperature-dependent Startmehrmen gene control according to claim 1 or 2, characterized in that the temperature-dependent element is designed as a PTC thermistor ( 2 ). 4. Device for temperature-dependent Startmehrmen gene control according to claim 1 or 2, characterized in that the temperature-dependent el ment is designed as a bimetal switch ( 4 ). 5. A device for temperature-dependent Startmehrmen gene control according to claim 1, characterized in that the temperature-dependent el ment is designed as a thermistor ( 5 ) and is connected via an in ver circuit ( 6 ) with the electrically excitable coil ( 1 ). 6. Device for temperature-dependent Startmehrmen gene control according to one of the preceding claims, characterized in that the core ( 10 ) is operatively connected to a rotatably mounted lever ( 12 ). 7. Device for temperature-dependent start multiple gene control according to one of the preceding claims, characterized in that the core ( 10 ) is axially operatively connected to the control rod ( 13 ). 8. Device for temperature-dependent Startmehrmen gene control according to one of the preceding claims, characterized in that the core ( 10 ) is designed as an angle lever ( 20 ).