WO2015051971A1

WO2015051971A1 - Method for operating a load connected to a motor vehicle electrical system

Info

Publication number: WO2015051971A1
Application number: PCT/EP2014/069434
Authority: WO
Inventors: Tobias Schuhmacher
Original assignee: Robert Bosch Gmbh
Priority date: 2013-10-11
Filing date: 2014-09-11
Publication date: 2015-04-16
Also published as: CN105637747B; CN105637747A; DE102013220529A1; KR102469591B1; KR20160068918A

Abstract

The invention relates to a method for operating a load (12) connected to a motor vehicle electrical system (18) using a step-up converter (14). An input voltage (Ue) of the step-up converter (14) is ascertained, and a current (I) flowing from an output capacitor (42) and a valve (36) of the step-up converter (14) is ascertained. The valve (36) is opened or closed depending on the current (I) and depending on the input voltage (Ue).

Description

Description title

Method for operating a consumer on a motor vehicle electrical system State of the art

The invention relates to a method for operating a load on a motor vehicle electrical system by means of a boost converter according to the preamble of claim 1.

Step-up converters are well known and serve to boost their input voltage to a desired output voltage end level.

From DE 103 53 835 A1 a method for operating a

Hochsetzstellers known in which the switching on and off of a

Switching element of the boost converter takes place in accordance with a predetermined duty cycle whose size is set or varied in response to the operating situation of at least one of the components of the boost converter during the current operating mode.

Disclosure of the invention

The problem underlying the invention is solved according to claim 1. Advantageous developments are specified in the subclaims. Characteristics important to the invention can be further found in the following description and in the drawings, wherein the features in both

Alone position as well as in different combinations for the invention may be important, without being explicitly referred to again.

A valve of the boost converter is closed or opened in response to a first and a second current threshold. In that at least one of the two current threshold values is determined as a function of an input voltage of the boost converter, the

Input voltage used as a reference variable. This makes it possible to larger than fixed preset current thresholds

To achieve output power at a reduced input voltage. In addition, the power loss can be limited at an increased input voltage.

Because of a distance between a first and second

Current threshold remains the same or decreases as the input voltage decreases, especially at low input voltage, no high

Inrush current are passed through, which in particular significantly improves the EMC emissions (EMC: Electromagnetic Compatibility).

Other features, applications and advantages of the invention will become apparent from the following description of embodiments of the invention, which are illustrated in the figures of the drawing. All described or illustrated features alone or in any combination form the subject matter of the invention, regardless of yours

Summary in the claims or their dependency and regardless of your wording or representations of the description or in the drawing. It will be for

functionally equivalent sizes and features in all figures, the same reference numerals used in different embodiments.

Hereinafter, exemplary embodiments of the invention will be explained with reference to the drawings. In the drawing show:

Figure 1 is a circuit diagram for a circuit for controlling a consumer;

Figure 2 is a schematic view of a control device of a boost converter; and

characters

3 to 6 are each a schematic current / input voltage-time diagram. Figure 1 shows a circuit diagram for a circuit 10 for controlling a

Consumer 12, in particular a magnetic coil (not further shown), and in particular (not shown) electromagnetic

Actuating device for an injection valve (not shown) a

Internal combustion engine (not shown).

A DC-DC converter 14 ("current-controlled boost converter", "boost converter") is fed to an input 16 from a DC voltage source 18 with an input voltage Ue and generates an output 20 at an output voltage Ua, which at least temporarily higher than the

Input voltage Ue is. The DC voltage source 18 is set

Motor vehicle electrical system. The input voltage Ue is measured by means of a voltage measuring device 19, which outputs its measuring signal to the terminal 21.

Furthermore, in a lower region in the drawing, the DC-DC converter 14 has a base terminal 24, which in the present case is connected to a reference potential 28 via a current measuring resistor 26. In the present case, the second reference potential 28 is a ground potential, GND. Parallel to the current measuring resistor 26, a voltage measuring device 30 a is connected, which outputs its measuring signal to the terminal 31. Via the terminal 31, a current I, which flows through the current measuring resistor 26, or an equivalent measure can be determined.

At the input 16 of the DC-DC converter 14, a filter capacitor 32 is connected against the second reference potential 28. Furthermore, the input 16 is connected to a first terminal (without reference numeral) of a converter inductor 34. A second connection (without reference number) of the

Transducer inductance 34 is connected to a D-terminal (drain) of a switching transistor 36 and the anode terminal of a diode 38. In the present case, the switching transistor 36 as a MOSFET (metal-oxide-semiconductor field effect transistor, English "metal-oxide-semiconductor field-effect transistor") executed. The switching transistor 36 is commonly referred to as a valve. An S-terminal ("source") of the switching transistor 36 is connected to the base terminal 24 of the DC-DC converter 14. A G terminal 40 ("gate") of the switching transistor 36 is connected to a not shown in the figure 1

Control unit for controlling the DC-DC converter 14 is connected. A cathode terminal of the diode 38 is connected to the output 20 and a first

Connection of an output capacitor 42 connected. A second terminal of the capacitor 42 is connected to the base terminal 24. The current I through the resistor 26 flows from the output capacitor 42 and the valve 36.

A difference between the output voltage Ua and the reference potential 28 corresponds in the present case to an operating voltage generated by the DC-DC converter 14 for driving the load 12.

FIG. 2 shows in a schematic block diagram the control unit 44 for connection to the connections 21, 31 and 40 from FIG. 1. By means of the connection 21, the control unit 44 can detect the input voltages Ue. By means of the connection 31, the control unit 44 can detect the current I flowing out of the valve 36 and the output capacitor 42. Depending on the current I and the input voltages Ue, the valve 36 is opened or closed via the connection 40. Of course, the methods shown and executed here by an unspecified explained

Voltage control, so a control of the output voltage Ua, are superimposed.

FIG. 3 shows a schematic current / input voltage-time diagram 46. Three different time periods T1 to T3 are shown. In schematic form, a voltage curve 48 is shown. In the periods T1 to T3 are associated current waveforms 50, 52 and 54. The current and voltage waveforms shown in Figures 3 to 6 are merely schematic and exemplary and are not particularly to the timing shown

limited. Rather, depending on the value of the input voltage Ue, at least one current threshold value la, 1b is changed. Starting from the current 52 towards the current 50, the first

Current threshold la 1 increased to the first current threshold Ia2 and the second current threshold Ib2 to the second current threshold Ib3

increased when the input voltage Ue below a first

Voltage threshold Uea drops.

Starting from the current profile 52 toward the current profile 54, the first current threshold value la 1 is increased to the first current threshold value Ia2 and the second current threshold value Ib2 is reduced to the second current threshold value Ib1 if the input voltage Ue exceeds a second voltage threshold value Ueb.

FIG. 4 shows a further schematic diagram 56 with current profiles 58, 60 and 62. In contrast to FIG. 3, the second current threshold Ib remains constant above the input voltage Ue. Starting from the current curve 60 toward the current course 58, the first current threshold Ia2 to the first

Current threshold Ia3 increased when the input voltage Ue falls below the first voltage threshold Uea. Starting from the current curve 60 toward the current profile 62, the first current threshold value Ia2 is reduced to the first current threshold value Ia3 when the input voltages Ue exceeds the second voltage threshold value Ueb.

FIG. 5 shows a schematic diagram 64 with current profiles 66, 68 and 70. The first current threshold value la remains constant above the input voltage Ue. The second current threshold value Ib2 is increased, starting from the current profile 68 toward the current profile 66, to the second current threshold value Ib3 when the input voltage Ue drops below the first voltage threshold value Uea.

Starting from the current curve 68 toward the current curve 70, the second current threshold value Ib2 is reduced to the second current threshold value Ib1 when the input voltage Ue exceeds the second voltage threshold value Ueb.

FIG. 6 shows a further schematic diagram 72 with current profiles 74, 76 and 78. Starting from the current profile 76 towards the current profile 74, the second current threshold value Ib2 remains constant above the input voltage Ue and the first current threshold value la 1 becomes the first current threshold value Ia2 increased when the input voltage Ue among the first

Voltage threshold Uea drops.

Starting from the current profile 76 toward the current profile 78, the first current threshold value Ia1 remains constant over the input voltage Ue and the second

Current threshold Ib2 is reduced to the second current threshold Ib1 when the input voltage Ue exceeds the second voltage threshold Ueb. The change in current thresholds Ia and Ib became the previous ones

Figures 4 to 6 starting from the time range T2 described.

Of course, the change in the current threshold values Ia and Ib can also be based on the time ranges T1 and T3, respectively

Time range T2 describe.

Claims

claims

1 . A method for operating a consumer (12) on a motor vehicle electrical system (18) by means of a boost converter (14), wherein a

Input voltage (Ue) of the boost converter (14) is determined, characterized in that one of an output capacitor (42) and a valve (36) of the boost converter (14) effluent (I) is determined, and that the valve (36) in Dependence on the current (I) and in

Depending on the input voltage (Ue) is opened or closed.

2. The method of claim 1, wherein the valve (36) is closed when the current (I) reaches or falls below a first current threshold (Ia), the valve (36) being opened when the current (I) has a second current threshold (Ib) reaches or exceeds, and wherein the first current threshold (la) and / or the second current threshold (Ib) in

Dependence on the input voltage (Ue) is determined.

3. The method of claim 2, wherein the first current threshold (la) and / or the second current threshold (Ib) is increased when the

Input voltage (Ue) decreases, and / or wherein the first current threshold (la) and / or the second current threshold (Ib) is lowered when the input voltage (Ue) increases.

4. The method of claim 2 or 3, wherein a distance between the first and second current threshold (la, lb) remains the same or is reduced when the input voltage (Ue) decreases.

5. The method according to any one of claims 2 to 4, wherein the first

Current threshold (la) is a lower current threshold, and wherein the second current threshold (Ib) is an upper current threshold, which is greater than the first current threshold (la).

6. The method according to any one of claims 2 to 5, wherein the first

Current threshold (Ia1, Ia2) is increased and the second

Current threshold (Ib2, Ib3) is increased when the input voltage (Ue) below a first voltage threshold (Uea) decreases, and wherein the first current threshold (Ia1, Ia2) is increased and the second

Current threshold (Ib2, Ib1) is lowered when the input voltage (Ue) exceeds a second voltage threshold (Ueb).

7. The method of claim 6, wherein the first current threshold (la) and the second current threshold (Ib) are increased in such a way, if the

Input voltage (Ue) below the first voltage threshold (Uea) decreases that the distance between the first and the second

Current threshold (Ia1, Ib2; Ia2, Ib3) remains substantially the same.

Method according to Claim 6 or 7, wherein the first current threshold value (1a) is increased in such a way and the second current threshold value (Ib) is reduced in such a way when the input voltage (Ue) has a second current threshold value (Ie)

Voltage threshold (Ueb) exceeds that the distance between the first and second current thresholds (Ia1, Ib2, Ia2, Ib1) is reduced.

Method according to one of claims 2 to 5, wherein the second

Current threshold (Ib) above the input voltage (Ue) remains constant and the first current threshold (Ia2, Ia3) is increased when the

Input voltage (Ue) falls below a first voltage threshold (Uea), and wherein the second current threshold (Ib) exceeds the

Input voltage (Ue) remains constant and the first current threshold (Ia2, Ia1) is lowered when the input voltage (Ue) exceeds a second voltage threshold (Ueb). 10. The method according to any one of claims 2 to 5, wherein the first

Current threshold (la) above the input voltage (Ue) remains constant and the second current threshold (Ib2, Ib3) is increased when the

Input voltage (Ue) falls below a first voltage threshold (Uea), and wherein the first current threshold (la) above the

Input voltage (Ue) remains constant and the second current threshold

(Ib2, Ib1) is lowered when the input voltage (Ue) exceeds a second voltage threshold (Ueb).

1 1. Method according to one of claims 2 to 5, wherein the second

Current threshold (Ib2) above the input voltage (Ue) remains constant and the first current threshold (Ia1, Ia2) is increased when the

Input voltage (Ue) falls below a first voltage threshold (Uea), and wherein the first current threshold (Ia1) remains constant above the input voltage (Ue) and the second current threshold (Ib2, Ib1) is decremented when the input voltage (Ue) is a second current threshold (Ueb) exceeds.

12. The method according to any one of the preceding claims, wherein the consumer (12) is an electromagnetic actuator for an injection valve of an internal combustion engine.

13. A computer program for a digital computing device, which is designed to carry out a method according to one of claims 1 to 12.

14. Control unit (44) for operating a boost converter (14), in particular a motor vehicle, which is provided with a digital computing device, in particular a microprocessor on which a computer program according to claim 13 is executable.

15. Storage medium for a control unit (44) according to claim 14, on which a computer program according to claim 13 is stored.