EP0880732A1

EP0880732A1 - Method and device for examining and/or adjusting valves

Info

Publication number: EP0880732A1
Application number: EP97909134A
Authority: EP
Inventors: Eberhard SCHÖFFEL; Josef Seidel
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 1996-11-25
Filing date: 1997-09-17
Publication date: 1998-12-02
Anticipated expiration: 2017-09-17
Also published as: KR19990081928A; JP4083230B2; KR100504414B1; WO1998024014A1; CN1208476A; DE19648689A1; US6311553B1; JP2000504389A; EP0880732B1; RU2189488C2; DE59701133D1; ES2143853T3; CN1147766C

Abstract

The present invention pertains to a method and a device for examining and/or adjusting valves, especially injector valves in an internal combustion engine. The valve is activated by means of an agreed control signal in order for a signal (QK) characterizing the fuel flow to be determined. The activating element is a gas. A first quantity (QPN) characterizing the gas flow and/or a second quantity (IAN, IAB) is determined.

Description

Method and device for testing and / or adjusting valves

State of the art

The invention relates to a method and a device for adjusting and / or testing valves according to the preamble of the independent claim.

There are methods for setting and / or testing valves, in particular injection valves for

Internal combustion engines known. To adjust the dynamic flow of injectors, the hydraulic flow rate is measured and adjusted in production.

When setting the dynamic flow of

Valves are charged with a highly precise hydraulic medium, which is referred to as white spirit in the following. Defined control and measurement of the flow rate detects the actual flow rate and the valve is set in such a way that a defined flow rate is set when the control is defined. The white spirit has a constant density and viscosity as well as a high purity. For these reasons, this white spirit is very expensive. In addition, the evaporation of the white spirit creates a considerable burden on the environment and the workshop staff. The use of other media for testing is problematic, since they have a different hydraulic behavior compared to the fuel.

Object of the invention

The invention has for its object to reduce the cost and environmental impact in a method for testing and adjusting valves. This object is achieved by the features characterized in the independent claim.

Advantages of the invention

In the procedure according to the invention, a gaseous medium is applied to the valve. In this case, a first variable which characterizes the flow of the gaseous medium and / or at least a second variable is recorded. This procedure enables a considerable reduction in costs and a reduction in the burden on the environment and the workshop personnel.

It is particularly advantageous if the current value at which the valve opens and / or the current value at which the valve closes is recorded as the second variable.

Advantageous and expedient refinements and developments of the invention are characterized in the subclaims. drawing

The invention is explained below with reference to the embodiments shown in the drawing. FIG. 1 shows a roughly schematic representation of the invention

Device and Figures 2 and 3 flow diagrams for explaining the method according to the invention.

In Figure 1, the device according to the invention is shown roughly schematically. A solenoid valve 100 is shown in a simplified representation. This solenoid valve has a valve seat 105 and a valve chamber 110. Fuel enters the valve chamber 110 in normal operation via an inlet 115. A spring is identified by 120 and a valve needle by 125. A coil 130 is provided for moving the valve needle. Means 135 for adjusting the spring force and means 140 for adjusting the stroke of the solenoid valve needle 125 are also provided. The outlet of the valve communicates with a pressure generator 145 via a flow meter 140.

The coil 130 is supplied with a supply voltage U via a switching means 150. The second connection of the coil 130 is connected to ground via a current measuring means 155.

A control unit 160 is also provided. This control unit 160 acts on the switching means 150 with signals and processes the output signals of the flow meter 140 and the current measuring means 155 and, in a preferred exemplary embodiment, also acts on the setting means 140 and 135 with corresponding quantities.

In the de-energized state, the spring 120 presses the valve needle 125 into the valve seat 105 When de-energized, the valve breaks the connection between the inlet 115 and the outlet. By energizing the coil 130, a magnetic force is applied which acts against the spring force or the mechanical force. This force causes the valve needle 125 from

Valve seat 105 lifts off. The distance between valve seat 105 and valve needle 125 is referred to as stroke H.

The procedure according to the invention is not limited to this type of valve. It can also be used with other controlled valves in which a specific volume is released by means of a control signal. Thus, the procedure can also be used for valves which are held in their open state by a spring and which release the flow in their de-energized state.

If a defined voltage is applied to the solenoid valve, that is to say with a control signal of a fixed length, the solenoid valve must release the flow with a certain stroke H. The volume that flows through the valve during actuation depends on several factors. On the one hand, this is the speed at which the solenoid valve opens, i.e. the speed at which the stroke increases from zero to the maximum value. This variable determines the dynamic flow of the solenoid valve. This essentially depends on the spring 120. This speed can be set with the setting means 135. The dynamic flow can be set by means of the setting means 135.

Furthermore, the stroke that occurs after a certain time with a certain control current is different for different injection valves. thats why an adjusting device 140 is provided with which the stroke in the static state can be set to a predeterminable value. For this purpose, the solenoid valve is constantly energized, the static flow is measured and the adjusting device 140 is set so that a specific, desired static flow is established.

This adjustment work is usually carried out with fuel, in particular with a high-precision hydraulic medium. Heptane is preferably used for this. The use of this hydrocarbon is problematic for several reasons.

According to the invention, it was recognized that the dynamic flow can also be carried out using compressed air.

The behavior of valves in dynamic control is essentially determined by the length of the control pulse (control pulse duration) compared to the pulse period, the static flow and the time course of the difference between the mechanical and magnetic forces.

The control pulse duration corresponds to the time in which the valve coil is energized. The pulse period corresponds to the sum of the time in which the valve is energized and not energized. Static flow is the amount that the fully open valve flows through for a certain period of time. The dynamic flow is the amount that the valve flows through during a certain period of time when it is driven with a certain duty cycle. The duty cycle is the ratio between the control pulse duration and the pulse period. The values of the dynamic and the static flow are usually different for fuel and gaseous substances.

According to the invention, it was recognized that the temporal variation of the force difference between the magnetic force and the mechanical force together with the dynamic flow of fuel can be detected by measuring the pneumatic, dynamic flow QPN.

Pneumatic dynamic flow QPN is the amount of gas that flows through the valve at a given duty cycle.

The differences between the individual solenoid valves, which are based in particular on the differences in the magnetic circuit, are detected according to the invention by measuring the static attraction and waste flow.

The three parameters of pneumatic, dynamic flow QPN, starting current IAN and waste current IAB can be measured in a simple manner. Based on these quantities, which are measured with a gaseous medium, the dynamic flow of fuel QK will be inferred. For this purpose, the flow of fuel is measured with a few valves, especially in the pre-series. The three parameters of pneumatic, dynamic flow QPN, starting current IAN and waste current IAB are then recorded and corresponding conversion factors are determined.

The elimination of the hydraulic medium is advantageous when determining the dynamic flow of fuel, since the readily available and extremely environmentally friendly atmospheric air is used as the gaseous medium to measure the flow. The slow and expensive hydraulic quantity measurement is made faster and cheaper pneumatic flow measurement replaced. The measurement of the static pull-in and waste current is determined by a simple measuring and display procedure.

The parameters pull-in current IAN, waste current IAB and the pneumatic-dynamic flow QPN have a strong one

Depending on the fuel flow and can be determined very easily and quickly in series production.

The device shown in FIG. 1 is suitable for this. The pressure generator 145 generates a predeterminable pressure which is applied to the outlet of the solenoid valve. The flow measuring means 140 is arranged between the pressure generator and the outlet of the valve. A measuring orifice is preferably used as the pressure measuring means 140. The measurement is therefore carried out by applying a pneumatic pressure to the valve in the direction opposite to the normal flow direction, which preferably takes on values of approximately 600 millibars.

In order to measure a first variable, which indicates the pneumatic-dynamic flow and which characterizes the flow of the gaseous medium, the coil 130 is acted upon with a predetermined duty cycle. For example, the coil is energized for 3 milliseconds, the period, that is to say the distance between the start of two energizations, being 6 milliseconds. The control frequency is 166.7 Hz in this example.

With this type of control, the solenoid valve opens and closes at this frequency. With this dynamic control, the magnetic force has a significant influence on the pneumatic, dynamic flow. With a quick opening there is a large, with a slow opening, due to a large spring force, a small flow rate. Furthermore, a second variable is recorded, which is referred to as the starting current IAN and / or as the waste current IAB. For this purpose, the voltage U applied to the coil 130 is continuously increased. At the same time, the

Coil current detected with the current measuring means 155. The opening of the injection valve is recognized when the flow suddenly increases. This is recognized by a pressure drop in the area of the pressure generator 145 or the flow measuring means 140. The pressure drop is around 25 mbar.

The voltage is then reduced and the point in time at which the valve closes again is determined. The current value at which the solenoid valve opens is called

Starting current IAN and at which the solenoid valve closes, referred to as waste current IAB.

This measurement can be carried out automatically by the control unit 160, manually or semi-automatically. For example, it can be provided that the measurement and setting of the valve is carried out automatically by the control unit 160. However, it is also possible for the control unit 160 to carry out the measurements and for the setting to be carried out manually. It is even possible to work without a control unit. This means that the valve is supplied with a suitable signal generator with control signals and the measurement and the settings are carried out manually.

According to the invention it was recognized that there is a fixed relationship between the dynamic flow rate for fuel QK and the pneumatic dynamic flow rate QPN, the starting current IAN and the waste flow IAB. The following formula applies to this relationship: QK = A - B * IAN - C * IAB + D * QPN

Sizes A, B, C and D are constants that have to be determined for a few examples of injection valves of the same type. For this purpose, the dynamic flow QK for fuel and the quantities starting current IAN, waste flow and the pneumatic, dynamic flow QPN with compressed air are measured with the same control signals for a few valves of the same type. The conversion factors A, B, C and D can be determined on the basis of these measured values. Sizes A, B and C are of a similar order of magnitude and size D is much smaller.

FIG. 2 shows the procedure according to the invention for adjusting the valve on the basis of a flow chart. In a first step 200, the valve is installed in the measuring device and a defined control signal is applied to it. It can be installed against or in the normal flow direction of the valve. The step current IAN is measured in step 210 and the waste current IAB is measured in step 220. The measurement of these first two quantities is shown in more detail in FIG. 3.

In the subsequent step 230, the solenoid valve is subjected to a fixed duty cycle. Then, in step 240, the measurement of a first variable, which is referred to as the pneumatic-dynamic flow rate QPN, takes place by means of the flow meter 140.

Then in step 245, based on these three parameters, the dynamic flow rate for fuel QK corresponding to these variables is determined using the formula given above. The query 250 checks whether this value QK of deviates from an expected setpoint QKS. For this purpose, it is checked, for example, whether the difference between the dynamic flow rate for fuel QK and the expected target value QKS is less than a threshold value S. If this is the case, the injection valve is correctly set and the testing and setting process ends in step 270.

If the value QK thus calculated for the fuel flow deviates from the expected value QKS, the solenoid valve is adjusted in step 260. For this purpose, the setting means 135 and / or 140 is influenced in a suitable manner. Steps 210 to 250 are then processed again.

In a particularly advantageous embodiment, the target values for the quantities QPN, IAN and IAB are determined in advance for some valves. In this case, the calculation in step 245 can be omitted. In step 250, the values QPN, IAN and / or IAB are then compared with the corresponding expected values. In this embodiment, the valve is compared if there is a deviation between the first variable and a predefinable target value for the first variable and / or if there is a deviation between the second variable and a predefinable target value for the second variable

One pneumatic and two electrical variables are used to adjust the hydraulic properties of the valve. These sizes are easy and quick to measure. On the basis of these measured quantities, a hydraulic quantity is determined and the balancing means are set so that the hydraulic quantity corresponds to an expected target value. Before the measurement, the factors A, B, C and D must be determined by measuring with fuel and with air with a small number of valves. The majority of the valves are then only checked and adjusted with air.

To measure the electrical quantities, for example, the procedure shown in FIG. 3 as a flow chart is followed. In a first step 300, a voltage value U0 is specified. This voltage value is selected so that no or only a very small current flows at which the solenoid valve certainly does not open. The pneumatic flow QPN0 is then detected in step 305.

Then in step 310, the voltage value U is increased by a predetermined value ΔU. The new value QPN1 for the pneumatic flow is then measured in step 350.

The difference ΔQPN between the old and the new value for the pneumatic flow is then determined in step 320. The subsequent query 325 checks whether this value is greater than a threshold value. If this is not the case, that means the pressure has not dropped and the

Solenoid valve needle has not yet lifted, the old value QPN0 is replaced by the new value QPN1 in step 330 and the voltage value is increased again in step 310.

If query 325 recognizes that the pressure has dropped or the flow rate has increased, the valve needle 125 has lifted and the starting current IAN has been reached. In step 35, the current measuring means 155 therefore measures the current I and as

Tightening current IAN saved. To detect the starting current, the current value is increased in a ramp shape with a constant slope of, for example, 0.001 milliamperes per millisecond. Reaching the pull-in current is monitored by the pneumatic Flow rate QPN determined. The same procedure is followed for the waste stream IAB. In step 340, the voltage U is reduced by a predeterminable value ΔU. In step 345 the new value QPN1 for the flow is measured and in step 350 it is compared with the old value QPN zero.

If query 355 recognizes from the difference ΔQPN by comparison with a threshold value SW that the flow rate has not decreased, that is to say the valve needle has not yet moved, step 360 takes place in which the old value is overwritten by the new value and then in step 340 the voltage is further reduced. If query 355 detects a drop in the flow rate, the current current value I is recorded in step 365 and stored as a drop current IAB.

The values for the control duration of 5 milliseconds and for the period duration of 10 milliseconds are selected only as examples. These values are chosen to be as small as possible, since in this case there is a better correlation between the hydraulic and pneumatic flows. The conversion of the parameters IAN, IAB and QPN via the correlation into hydraulic flow takes place automatically in the control unit 160, so that it is to be set

Target values directly fuel values can be used.

Instead of air, other gaseous substances can also be used.

Claims

Expectations

1. A method for testing and / or adjusting valves, in particular injection valves of an internal combustion engine, wherein a valve is acted upon with a defined control signal in order to determine a signal (QK) which characterizes the flow of fuel, characterized in that the valve is provided with a acted upon gaseous medium and a first variable (QPN), which characterizes the flow of the gaseous medium and / or at least a second variable (IAN, IAB) are recorded.

2. The method according to any one of the preceding claims, characterized in that the second variable (IAN, IAB) indicates the current value (IAN) at which the valve opens and / or that the second variable indicates the current value (IAB) at which the Valve closes.

3. The method according to any one of the preceding claims, characterized in that the first variable (QPN) indicates a pneumatically dynamic flow.

4. The method according to any one of the preceding claims, characterized in that starting from the first and the second variable (IAN, IAB), the signal (QK) is determined, which characterizes the flow of fuel.

5. The method according to any one of the preceding claims, characterized in that in the event of a deviation between the signal (QK), which characterizes the flow of fuel, and a predeterminable target value (QKS), the valve is compared.

6. The method according to any one of the preceding claims, characterized in that in the event of a deviation between the first variable (QPN) and a predefinable setpoint and / or in the event of a deviation between the second variable (IAN, IAB) and a predefinable setpoint, the valve is compared he follows.

7. The method according to any one of the preceding claims, characterized in that the flow of fuel is the dynamic flow.

8. The method according to any one of the preceding claims, characterized in that compressed air is used as the gaseous medium.

9. Device for testing and / or adjusting valves, in particular injection valves of an internal combustion engine, with a first means (160) which act on a valve with a defined control signal in order to determine a signal (QK) which characterizes the flow of fuel, thereby characterized in that second means (145) are provided which act on the valve with a gaseous medium and detect a first variable (QPN) which characterizes the flow of the gaseous medium and / or at least a second variable (IAN, IAB).