Matrix injector driver circuit

Abstract

A fuel injector control circuit reduces the number of gates required by arranging high side and low side gates in a matrix. Each coil is selectively activated by activating a unique pair of a high side gate and a low side gate, thus reducing the total number of gates required.

Description

BACKGROUND OF THE INVENTION

The present invention relates generally to fuel injector control circuits.

Known fuel injector control circuits generally comprise an open coil and a close coil for each fuel injector. To inject fuel into the cylinder, it is necessary to activate the open coil and then the close coil. Some applications require that the close coil on a given cylinder be activated before the associated open coil is deactivated. This is known as simultaneous excitation.

Known fuel injector fuel circuits connect each coil to the power supply with a different switch (such as a FET or other gate). Thus, for an 8 cylinder engine, 16 high side gates were required, each with associated drive circuitry.

When a coil is energized, some energy is stored in a magnetic field that surrounds the coil. When the coil is de-energized, it is desirable to recover some of the energy that was stored in the magnetic field. This energy recovered is done by a known technique called “recirculation.”

SUMMARY OF THE INVENTION

The present invention provides cost saving by reducing the number of high side gates and the associated drive circuitry from 16 to as few as 4 (for an eight cylinder engine). Various configurations are illustrated herein, with different benefits and features in each. However, as a general principal, each of these utilizes high and low side gates which selectively activate selected coils via a matrix.

BRIEF DESCRIPTION OF THE DRAWINGS

Other advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:

FIG. 1 is a high-level schematic of the fuel injector control system of the present invention;

FIG. 2 is a schematic for a first circuit for controlling coils according to the present invention;

FIG. 3 is a schematic of a second, alternate circuit for controlling coils according to the present invention;

FIG. 4 is a schematic for a third circuit for controlling coils according to the present invention.

FIG. 5 is a schematic of a fourth alternate circuit for controlling coils and according to the present invention;

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

A fuel injector control circuit 20 is shown schematically in FIG. 1. A microcontroller 22 is programmed generally to control high side drivers 24 to drive high side gates 26 and low side drivers 28 to drive low side gates 30 . The high side gates 26 and low sides gates 30 selectively activate coils 32 , which in turn selectively activate injectors 34 .

Generally, the present invention reduces the number of high side gates 26 . This is accomplished by treating the coils as a matrix, wherein each coil is selected by selective activation of one of the high side gates and one of the low side gates.

For example, a first circuit 40 is shown generally in FIG. 2 , including high side gates 26 , including gates Q 1 , Q 2 , Q 5 , Q 6 , Q 9 , Q 10 , Q 13 , Q 14 . The circuit 40 further includes low side gates 30 , including Q 17 -Q 20 . This circuit 40 illustrates 16 coils OC_A-H and CC_A-H. In the circuit 40 , high side gate Q 1 connects odd coil OC_A and odd coil CC_A selectively to power supply. In circuit 40 , each of the high side drivers connects the open coil and associated close coil for one of the 8 injectors.

The low side gates 30 , Q 17 -Q 120 selectively connect different groups of the coils to ground. For example, as can be seen in FIG. 2 , Q 17 selectively connects the odd open coils, Q 18 selectively connects the odd close coils, Q 19 selectively connects the even open coils and Q 20 selectively connects the even close coils. Thus, any one of the 16 coils can be selectively individually activated by switching on the proper pair of a high side gate 26 and a low side gate 30 . The diodes D 1 -D 16 are placed in series with each coil and prevent interaction between the coils. The operation of the first circuit 40 is further demonstrated in the following table.

	TABLE 1
	Q17 Low	Q18 Low	Q19 Low	Q20 Low
	side driver	side driver	side driver	side driver
	for odd	for odd	for even	for even
	open coils	close coils	open coils	open coils
Q1 High side	OC_A	CC_A
driver for cyl. A
Q2 High side			OC_B	CC_B
driver for cyl. B
Q5 High side	OC_C	CC_C
driver for cyl. D
Q6 High side			OC_D	CC_D
driver for cyl. D.
Q9 High side	OC_E	CC_E
driver for cyl. E
Q10 High side			OC_F	CC_F
driver for cyl. F
Q13 High side	OC_G	CC_G
driver for cyl. G
Q14 High side			OC_H	CC_H
driver for cyl. H

In this example, because gates are connected on common points on the high side of open and close coils in the same cylinder, simultaneous excitation cannot be performed. On the other hand, the advantages of this configuration include that the failure of one high side gate will only disable one cylinder and that three wire coils (with the high side connection with both open and close coils on the same wire) can be used.

A preferred method and apparatus for controlling of low side gates 30 is disclosed in co-pending patent application U.S. Ser. No. 09/703,537 entitled “CONTROL OF DRIVER CURRENT VIA LOW SIDE GATES” filed on the same date as this application, the assignee and inventors of which are the same as the assignee and inventors of this patent application, and which is hereby incorporated by reference fully as if repeated herein.

FIG. 3 illustrates a second circuit for activating the coils. As can be seen, the second circuit 50 requires only 4 high side gates. In the circuit 50 , each of the high side gates, Q 1 , Q 5 , Q 9 and Q 13 operates the open and close coils for two cylinders. Low side gates 30 , Q 17 -Q 20 , operate identically as in FIG. 2 . Thus in this circuit 50 , any of the coils can be selectively activated by switching the appropriate pair of high and low side gates. This is shown in the Table 2 below.

	TABLE 2
	Q17 Low	Q18 Low	Q19 Low	Q20 Low
	side driver	side driver	side driver	side driver
	for odd	for odd	for even	for even
	open coils	close coils	open coils	open coils
Q1 High side	OC_A	CC_A	OC_B	CC_B
driver for cyl. A
and B
Q5 High side	OC_C	CC_C	OC_D	CC_D
driver for cyl. C
and D
Q9 High side	OC_E	CC_E	OC_F	CC_F
driver for cyl. E
and F
Q13 High side	OC_G	CC_G	OC_H	CC_H
driver for cyl. G
and H

Some advantages of this configuration are that the failure of one high side FET will only disable two cylinders, this configuration only utilizes four high side gates and that this version allows the use of three wire coils. The disadvantage of this configuration is that simultaneous excitation of the open and close coils on the same cylinder is not possible.

FIG. 4 illustrates a third circuit 60 for operating the fuel injector coils for operating. In this third circuit 60 , 8 high side gates Q 1 , Q 2 , Q 5 , Q 6 , Q 9 , Q 10 , Q 14 are no longer connected to two coils in the same cylinder (as in FIG. 3 ). Rather, each high side gate Q 1 , Q 5 , Q 9 , Q 13 is connected to a pair of open coils (one even, one odd), while the gates Q 2 , Q 6 , Q 10 and Q 14 are connected to a pair of close coils (one even, one odd). The low side gates 30 operate as described above with respect to FIG. 1 in this third circuit 60 . Because the open and close coils on any cylinder do not share any high side driver, simultaneously excitation can be utilized. The operation of this circuit 60 is further described in the Table 3, below.

	TABLE 3
	Q17 Low	Q18 Low	Q19 Low	Q20 Low
	side driver	side driver	side driver	side driver
	for odd	for odd	for even	for even
	open coils	close coils	open coils	open cells
Q1 High side	OC_A		OC_B
driver for cyl. A
and B open coils
Q2 High side		CC_A		CC_B
driver for cyl. A
and B close coils
Q5 High side	OC_C		OC_D
driver for cyl. C
and D open coils
Q6 High side		CC_C		CC_D
driver for cyl. C
and D close
Q9 High side	OC_E		OC_F
driver for cyl. E
and F open coils
Q10 High side		CC_E		CC_F
driver for cyl. E
and F close coils
Q13 High side	OC_G		OC_H
driver for cyl. G
and H open coils
Q14 High side		CC_G		CC_H
driver for cyl. G
and H close

FIG. 5 illustrates a fourth schematic 70 including 4 high side gates, Q 1 , Q 5 , Q 9 and Q 13 . High side gate Q 1 selectively connects open coils A, B, C, D to power supply, while Q 5 selectively connects close coils A, B, C, D. Similarly, gate Q 9 selectively connects open coils E, F, G, H to the power supply while gate Q 13 selectively connects close coils E, F, G, H to the power supply. In schematic 70 , the low side gates 30 are configured differently, as shown. Gate Q 17 selectively connects open coils 1 and 5 and close coils 2 and 6 to ground. The operation of the remaining gates and activation of the remaining coils are illustrated in the following table as well as in schematic FIG. 5 .

	TABLE 4
	High Side	High Side	High Side	High Side
	Driver Q1	Driver Q5	Driver Q9	Driver Q13
	1-4 Open	1-4 Close	5-8 Open	5-8 Close
	Coils	Coils	Coils	Coils
Low Side Driver	Open Coil	Close Coil	Open Coil	Close Coil
Q17	#1	#2	#5	#6
1 and 5 Open
2 and 6 Close
Low Side Driver	Open Coil	Close Coil	Open Coil	Close Coil
Q18	#2	#1	#6	#5
2 and 6 Open
1 and 5 Close
Low Side Driver	Open Coil	Close Coil	Open Coil	Close Coil
Q19	#3	#4	#7	#8
3 and 7 Open
4 and 8 Close
Low Side Driver	Open Coil	Close Coil	Open Coil	Close Coil
Q20	#4	#3	#8	#7
4 and 8 Open
3 and 7 Close

The circuit 70 enables both recirculation and overlap by a more creative arrangement of the low side drivers. On any given cylinder the open coil and close coil do not share either a high side driver or a low side driver.

As shown above, the present invention reduces the number of gates and associated driver circuitry required, thus reducing cost. Some embodiments described still permit simultaneous excitation and recirculation. Of course, although a few arrangements have been described, additional different arrangements utilizing the inventive concepts described herein could also be utilized.

In accordance with the provisions of the patent statutes and jurisprudence, exemplary configurations described above are considered to represent a preferred embodiment of the invention. However, it should be noted that the invention can be practiced otherwise than as specifically illustrated and described without departing from its spirit or scope.

Claims

1. A fuel injector control circuit comprising:a plurality of coils, including a first coil and a second coil; a first gate connecting a first end of each of the first and second coils to a power supply; a second gate selectively connecting a second end of said first coil to ground; and a third gate selectively connecting a second end of said second coil to ground.

2. The circuit of claim 1 wherein said first coil is activated based upon said first gate and said second gate being closed.

3. The circuit of claim 2 wherein said second coil is activated upon said first gate and said third gate being closed.

4. The circuit of claim 3 wherein said first coil is an open coil for a first fuel injector and said second coil is a close coil for the first fuel injector.

5. A fuel injector control circuit comprising:a plurality of open coils; a plurality of close coils, each associated with one of said open coils for controlling a fuel injector; a plurality of high side gates each selectively connecting at least two of said plurality of coils to a power supply; and a plurality of low side gates, each selectively connecting at least two of said coils to ground.

6. The circuit of claim 5 wherein each said high side gate selectively connects one of said open coils and an associated one of said close coils to the power supply.

7. The circuit of claim 5 wherein each of said high side gates selectively connects at least two open coils to the power supply.

8. The circuit of claim 5 wherein each of said high side gates connects at least two of said open coils and two of said close coils to the power supply.

9. The circuit of claim 5 wherein each of said high side gates connects at least two of said plurality of open coils to the power supply.

10. The circuit of claim 9 wherein at least one of said high side gates connects at least 4 open coils to the power supply.

11. A method for controlling a plurality of fuel injectors including the steps of:a) associating each of a plurality of open coils with one of a plurality of high side gates and one of a plurality of low side gates, b) associating each of a plurality of close coils with one of the plurality of high side gates and one of the plurality of low side gates c) activating each of said coils based upon activation of a unique pair of one of said high side gates and one of said low side gates.

12. The method of claim 11 further including the step of simultaneously exciting and open coil and an associated close coil.

13. The method of claim 11 further including the step of recovering some energy stored in a magnetic field of each of the plurality coils to the power supply.