Injector module, injector electric block body, injector main bodies to be used for the same, and ignition coil device module

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an injector module to be used for an internal-combustion engine of a vehicle or the like and injector electric block body and injector main bodies to be used for the same.

Further, the present invention relates to an ignition coil device module to be used for an internal-combustion engine for a vehicle or the like.

2. Related Art

Conventionally, an injector for injecting fuel to combustion chambers of an internal-combustion engine is comprised of a needle valve and an electromagnetic coil for electromagnetically driving the needle valve to open and close being unified with each other, generally. Then, the fuel injecting orifice side ends of injectors are inserted into the injector mounting holes at the engine head side, and delivery pipes are attached to the fuel intake side ends of the injectors and fastened to the engine head side with bolts or the like, whereby the injectors are installed, fixed, and sandwiched between the engine head and delivery pipes.

Furthermore, exciting current conducting harness terminals for each electromagnetic coil are connected to each injector thus installed and fixed via connectors.

Further, recently, electronic control has been widely employed for engine systems of vehicles and the like, and various techniques have been employed in which ignition coil devices (igniter-combined ignition coils) and injectors are also provided in the ignition systems and fuel systems of the engine corresponding to the combustion chambers, and the ignition coil devices and injectors are controlled by an engine control unit to control the fuel injection amount and ignition timing for each combustion chamber.

As a wiring form for the ignition coil devices in such a conventional type of engine room, a structure has been employed in which ignition coil devices are attached to the corresponding positions of the cylinder head cover of the engine by fastening with bolts and the like, and harness terminals drawn out from the engine control unit are connected to the ignition coil devices, respectively by connectors.

[Problems to be Solved]

However, in the abovementioned injectors, connectors of the harness terminals must be connected to the injectors in the vicinity of the engine head, so that efficiency of the assembly work to the engine head is poor.

In addition, since harnesses formed of electric wire bundles are used as the wiring members between the engine control unit and injectors, and the harness terminals and injectors are connected to each other by connectors, the entire injector is very heavy.

Further, according to the conventional structure, since a system is employed in which the harness terminals drawn out from the engine control unit are connected, respectively, to the ignition coil devices attached to the engine side in the engine room, this system is troublesome and assembly work efficiency is very poor.

SUMMARY OF THE INVENTION

Therefore, a first object of the invention is to provide an injector module which shows excellent assembly work efficiency to an engine body and can be reduced in weight, and an injector electric block and injector main bodies to be used for the same.

Further, a second object of the invention to provide an ignition coil device module in which assembly work efficiency to an engine is improved.

[Means for Solving the Problems]

In order to solve the abovementioned problems, an injector module according to Aspect 1 of the invention is provided with a plurality of injector parts corresponding to combustion chambers of an engine and fuel injecting control of the injector parts is made by an engine control unit, wherein, said injector module comprises: an injector electric block body which is formed so that, inside an injector frame body with injector main body housing holes made in the frame body at positions corresponding to injector mounting holes at the engine body side, electromagnetic coil parts are installed so as to be wound around the inner circumferences of the injector main body housing holes, and wiring for connection to the electromagnetic coil parts are installed; and injector main bodies which are formed into roughly columnar shapes and have valve parts to adjust the timing of fuel injection from fuel injecting orifices, columnar parts which are provided in succession to the valve parts to feed fuel supplied from fuel intakes linearly, and movable magnetic bodies which can reciprocate between predetermined open and close positions for opening and closing the valve parts and are pressed toward the close positions, wherein the injector main bodies are inserted into the injector main body housing holes in a posture in which the movable magnetic bodies are movable to the open positions against the pressing forces in accordance with excitation of the electromagnetic coil parts and are movable to the close positions due to the pressing forces in accordance with non-excitation of the electromagnetic coil parts.

As described in Aspect 2 of the invention, the injector module may be constructed so that fixing core portions are provided at the centers of the electromagnetic coil parts, the movable magnetic bodies are provided to be extensions of the fixing core portions, auxiliary core portions are provided around the outer circumferences of the movable magnetic bodies, and outer circumferential core portions are provided around the outer circumferences of the electromagnetic coil parts, whereby a magnetic circuit is formed so that magnetic fluxes generated by power supply to the electromagnetic coil parts passes the fixing core portions, movable magnetic bodies, auxiliary core portions, and outer circumferential core portions and then reach the fixing core portions again.

As described in Aspect 3, nonmagnetic bodies may be interposed between the fixing core portions and outer circumferential core portions.

As described in Aspect 4, in place of or in addition to the outer circumferential core portions provided around the outer circumferences of the electromagnetic coil parts, inter-injector core portions may be provided between the injector main body housing holes of the injector frame body to form a magnetic circuit in which magnetic fluxes generated by power supply to the electromagnetic coil parts pass through the adjacent inter-injector core portions.

As described in Aspect 5, the injector electric block body may be unified with a delivery pipe.

As described in Aspect 6, a construction may be employed in which pressure-welding terminals are connected to the winding ends of the electromagnetic coil parts, and coated single-core wires are used for wiring, and the ends of the wires are pressure-welded to the pressure-welding terminals.

The injector electric block body of the injector module described in Aspect 7 is provided with a plurality of injector parts corresponding to combustion chambers of an engine, where fuel injecting control of the injector parts is made by an engine control unit, and comprises: an injector frame body with injector main body housing holes made in the frame body at positions corresponding to injector mounting holes at the engine body side; electromagnetic coil parts which are disposed to be wound around the inner circumferences of the injector main body housing holes to electromagnetically open and close the valve parts of the injector main bodies to be inserted into the injector main body housing holes; and wiring which is installed inside the injector frame body for connection to the electromagnetic coil parts.

The injector main bodies of the injector module described in Aspect 8 are provided with a plurality of injector parts corresponding to combustion chambers of an engine, where fuel injecting control at the injector parts is made by an engine control unit, and are formed into roughly columnar shapes having fuel intakes on one side and fuel injecting holes on the other side, and comprises: valve parts which are provided at the fuel injecting hole sides to adjust the injection timing of fuel supplied through the fuel intakes; and movable magnetic bodies which can reciprocate between predetermined open and close positions for opening and closing the valve parts, and are pressed towards the close positions, and open the valve parts by moving to the open positions against the pressing forces by use of excitation of the electromagnetic coil parts provided at the injector mounting hole sides of the injector electric block body side.

Further, in an ignition coil device module in which ignition coil devices are provided corresponding to a plurality of combustion chambers of an engine, and ignition control of the ignition coil devices is made by an engine control unit, the ignition coil devices are electrically connected at predetermined pitches by flexible wiring with flexibility and unified with each other, whereby ignition control is made through the flexible wiring.

Furthermore, the flexible wiring may be a flexible printed board.

Furthermore, the pitches of electrical connection of the ignition coil devices to the flexible wiring may be made longer than the provision pitches of the ignition coil devices for the engine.

Furthermore, the ignition coil device module may be structured so that, on one surface of each ignition coil device, connection surface base portions at which the electrical connecting terminals are exposed are provided, and fixed cover members to be fixed in a detachable manner at each connection surface base portion so as to surround the outsides of connecting terminals at the connection base end portions are provided, and by fixing the fixed cover members to the connection surface base portions, the flexible wiring is sandwiched and fixed between the fixed cover members and connection surface base portions, wiring conductors at portions in the flexible wiring thus sandwiched and fixed corresponding to the connecting terminals of the connection surface base portions are exposed, and the connecting terminals and wiring conductors are electrically connected to each other by the sandwiching fixation.

In addition, between the connection surface base end portions and fixed cover members, annular sealing members may be provided to surround the outsides of the connecting portions between the connecting terminals and wiring conductors.

Furthermore, when the flexible wiring is sandwiched and fixed by fixing the fixed cover members to the connecting terminals, pressing elastic materials for pressing the exposed portions of the wiring conductors against the connecting terminals may be provided on the fixed cover members.

Furthermore, a cylinder head cover in which the flexible wiring and fixed cover members are installed may be provided.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a block diagram showing the electric construction of the engine control system.

FIG. 2

is an exploded perspective view showing the injector module of the embodiment of the invention.

FIG.

3

(

a

) is a front view of the injector electric block body, and FIG.

3

(

b

) is a plan view of the injector electric block body.

FIG. 4

is a sectional view showing the closed condition of the valve part of the injector module.

FIG. 5

is a sectional view showing the open condition of the valve part of the injector module.

FIG. 6

is a sectional view showing the injector module of the modified example.

FIG.

7

(

a

) is a front view of the injector electric block body of the same modified example, FIG.

7

(

b

) is a plan view of the same injector electric block body, and FIG.

7

(

c

) is a side view of the same injector electric block body.

FIG.

8

(

a

) is a plan view of the injector electric block body of another modified example, FIG.

8

(

b

) is a plan view of the same injector electric block body, and FIG.

8

(

c

) is a side view of the same injector electric block body.

FIG. 9

is a sectional view of the same injector module as mentioned above.

FIG. 10

is a front view showing the wiring to be applied to the same injector module as mentioned above.

FIG. 11

is a block diagram showing the electrical construction of the engine control system of the embodiment.

FIG. 12

is a perspective view showing the ignition coil device module relating to the embodiment.

FIG. 13

is a partial sectional side view of the same.

FIG. 14

is a partial sectional plan view of FIG.

3

.

FIG. 15

is a partially omitted front view of FIG.

3

.

FIG. 16

is a principal portion front view of the ignition coil device.

FIG. 17

is a plan view of the same.

FIG. 18

is a right side view of FIG.

6

.

FIG. 19

is a front view of the fixed cover member.

FIG. 20

is a right side view of the same.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, an injector module of an embodiment of this invention is explained.

This injector module is constructed as shown in

FIG. 1

so that, in an engine control system for making fuel injecting control for a plurality of injector parts

10

provided in accordance with combustion chambers of an engine by using engine control unit (unit called EFI-ECU or the like)

1

, a coil part and a valve part of each injector

10

are separated from each other, and the wiring structure for the coil part is unified with the coil part.

Incidentally, the engine control unit

1

is connected to the injector parts

10

via input/output part

1

a,

and then to power supply Systems such as various sensors and batteries and various parts such as junction blocks inside a vehicle, and further connected to ignition coil devices via input/output parts

1

b

through

1

d,

and controls the timing of fuel injection of the injector parts

10

based on various detection signals from the various sensors. In this embodiment, a construction with four injector parts

10

is employed for an assumed 4-cylinder engine, however, the number of injector parts may be properly changed depending on the number of cylinders of an engine.

As shown in FIG.

2

through

FIG. 5

, this injector module comprises injector electric block body

20

in which electromagnetic coil parts of injector parts

10

and the wiring structure to the electromagnetic coils are unified and a plurality of injector main bodies

30

having valve parts of the injector parts

10

.

The injector electric block body

20

is constructed so that, in injector frame body

21

with injector main body housing holes

21

h

made in the frame body at positions corresponding to injector mounting holes Eh at the engine body E side, electromagnetic coil parts

25

are installed and wound around the inner circumferences of the injector main body housing holes

21

h,

and wiring

26

for connection to the electromagnetic coil parts

25

is installed.

Concretely, the injector frame body

21

is formed from a nonmagnetic insulating material such as an insulating resin or the like, and in this embodiment, the frame body is constructed so that a plurality of projecting columnar parts

21

b

shaped into rough columns are projectedly provided in accordance with injector mounting holes Eh at the lower surface side of plate-shaped part

21

a

shaped into a rough rectangle in a plan view.

The injector main body housing holes

21

h

are formed to perforate the portions of the injector frame body

21

at which the projecting columnar parts

21

b

are formed, and the upper sides of the housing holes are formed to be small diameter portions

21

ha

into which the columnar parts

31

of the injector main bodies

30

can be inserted, and the lower sides of the housing holes are formed to be large diameter portions

21

hb

into which auxiliary core portions

41

of the injector main bodies

30

to be described later can be housed. The injector main bodies

30

can be inserted into the injector main body housing holes

21

h

from below.

The electronic coil parts

25

are obtained by winding electric wires with insulative coatings such as enamel or the like around bobbins

25

b

so as to have donut shapes with inner diameters that are the same as or larger than the inner diameters of the small diameter portions

21

ha,

and are disposed in a buried manner so as to surround the inner circumferences of the small diameter portions

21

ha

at portions of the small diameter portions

21

ha

close to the large diameter portions. That is, the electromagnetic coil parts

25

are disposed so as to be wound around the inner circumferences of the injector main body housing holes

21

h,

and when a current is supplied to each electromagnetic coil part

25

, magnetic fluxes generated from the coil parts

25

pass through the movable magnetic bodies

34

(described later) of the injector main bodies

30

, which are disposed at least inside the injector main body housing holes

21

h,

and attract the movable magnetic bodies

34

toward the inside of the electromagnetic coil parts

25

.

The wiring

26

includes four power supply wires

26

a

for separately supplying power to the electromagnetic coil parts

25

and ground wires

26

a

used commonly for the electromagnetic coil parts

25

, and is comprised of bus bars formed into thin bands from a conductive material such as metal or the like and bare round conductors whose sections are roughly round. The power supply wires

26

b

and ground wires

26

b

are buried in plate-shaped part

21

a

of the injector frame body

21

with a predetermined pattern together with the electromagnetic coil parts

25

by means of insert molding or the like, and to one side end of each power supply wire

26

a

and one side end of each ground wire

26

b,

in the vicinity of the corresponding electromagnetic coil parts

25

, terminals attached to the winding ends drawn out from the electromagnetic coil parts

25

are welded by fusing and electrically connected. The wiring

26

is buried in the injector frame body

21

by means of insert molding or the like together with the electromagnetic coil parts

25

, so that sufficient waterproofness can be obtained between the wiring

26

and electromagnetic coil parts

25

without employing other special waterproof structures.

Furthermore, connector housing part

22

is formed at one side of the injector frame body

21

, and the other end portions of the power supply wires

26

a

and ground wires

26

b

are projectedly provided as connector terminals inside the connector housing part

22

to form connector part

23

. Then, by connecting the connectors at wire harness terminals, whose illustrations are omitted, drawn out from the engine control unit

1

to the connector part

23

, the electromagnetic coil parts

25

and engine control unit

1

are electrically connected to each other, and excitation/non-excitation control for the electromagnetic coil parts

25

is made by supply and interruption of a fuel injection control current from the engine control unit

1

.

At one side of the injector electric block

20

, as attaching members for attachment and fixation to the engine main body E side, attaching pieces

29

with attaching holes

29

h

are projectedly provided. By screw-fastening bolts or the like inserted into the attaching holes

29

h

of the attaching pieces

29

into the screw holes of the engine body E side, the injector electric block body

20

is attached and fixed to the engine body E in a predetermined posture in a condition where the injector main bodies

30

are inserted into the injector main body housing holes

21

h.

The injector main bodies

30

are formed into roughly columnar shapes, and comprised of valve parts

35

, columnar parts

31

provided linearly in succession to the valve parts

35

, and movable magnetic bodies

34

which move by interlocking with the opening and closing operations of the valve parts

35

.

The columnar parts

31

have roughly columnar shapes, fuel intakes

31

h

are formed at the upper ends thereof, and fuel passages

31

p

penetrating along the axial direction are formed inside. The fuel intake sides of the columnar parts

31

are formed in a manner enabling them to be inserted and connected to fuel supply ports

51

of the delivery pipe

50

side. Fuel flowing in the delivery pipe

50

is divided at the fuel supply ports

51

and supplied to the fuel intakes

31

h,

and further pass through the fuel passages

31

p

and supplied to the valve parts

35

. O-rings O

1

of rubber or the like are compressed and interposed between the upper outer circumferential surfaces of the columnar parts

31

and inner circumferential surfaces of the fuel supply ports

51

to prevent fuel leakage flowing between the upper outer circumferential surfaces of the columnar parts

31

and inner circumferential surfaces of the fuel supply ports

51

.

The valve parts

35

are connected to the lower end sides of the columnar parts

31

, and adjust the injection timing of fuel supplied via the columnar parts

31

, and fuel injecting orifices

35

h

are formed at the lower end sides of the valve parts. The fuel injecting orifice

35

h

side ends of the valve parts

35

are formed in a manner enabling them to be inserted and connected into the injector mounting holes Eh of the engine main body E side, and fuel injected from the fuel injecting orifices

35

h

is supplied to the combustion chambers of the engine main body E side via an intake manifold. O-rings O

2

of rubber or the like are compressed and interposed between the outer circumferential surfaces of the valve parts

35

and the inner circumferential surfaces of the fuel injecting orifices

35

h

to prevent water entrance into the combustion chambers from the surfaces.

Concretely, the valve parts

35

are provided with tapered nozzles

37

inside cylindrical parts

36

opening at the lower sides, and spherical valves

38

at the front end sides of the nozzle

37

. The spherical valves

38

are formed to be spherical so as to close the front end side openings of the nozzles

37

, and fixed and supported at front end positions inside the cylindrical parts

36

by unillustrated supporting means. The nozzles

37

are supported at a depth inside the cylindrical parts

36

so as to advance and withdraw between predetermined advance positions (see FIG.

4

), at which said front end openings are closed by pressing the spherical valves

38

, and predetermined withdrawal positions (see

FIG. 5

) at which said openings are opened by withdrawing to the base end sides from the advance positions. At advanceable and withdrawable supporting parts

39

, fuel passages

39

p

are formed which are communicated with the fuel passages

31

p,

whereby fuel supplied through the fuel passages

31

p

is fed into the nozzles

37

and injected from the front end sides of the nozzles

37

. At this time, if the nozzles

37

advance to the advance positions, the front end openings of the nozzles

37

are closed by the spherical valves

38

to stop fuel injection from the nozzles

37

. On the other hand, if the nozzles

37

withdraw to the withdrawal positions, the front end openings of the nozzles

37

are opened, and fuel injection from the nozzles

37

is carried out.

Movable magnetic bodies

34

are formed from a magnetic material such as silicon steel or the like in a manner in that the bodies can reciprocate between predetermined close positions P

1

(see

FIG. 4

) and predetermined open positions P

2

(see

FIG. 5

) for opening and closing the valve parts

35

and are pressed toward the close positions P

1

.

Concretely, movable magnetic bodies

34

are provided and fixed to the base ends of the nozzles

37

in the valve parts

35

so that the nozzles

37

move to the withdrawal positions by interlocking with the movement of the movable magnetic bodies

34

to the open positions P

2

and then open the valve parts

35

(see FIG.

4

), and the nozzles

37

move to the advance positions by interlocking with the movement of the movable magnetic bodies

34

to the close positions P

1

and then close the valve parts

35

(see FIG.

5

). In addition, the movable magnetic bodies

34

may be disposed outside the valve parts

35

in a manner enabling them to reciprocate, and the movable magnetic bodies

34

and nozzles

37

may be connected to each other by predetermined connecting structures so that the movable magnetic bodies

34

interlock with the nozzles

37

.

At the advanceable and withdrawable supporting parts

39

, coil springs

40

as pressing means are interposed between the columnar parts

31

and nozzles

37

in a compressed manner, whereby the movable magnetic bodies

34

are pressed toward the close positions P

1

.

Furthermore, the injector main bodies

30

are inserted into injector main body housing holes

21

h

in a posture so that the movable magnetic bodies

34

can move to the open positions P

2

by means of excitation of the electromagnetic coil parts

25

against the pressing forces of the coil springs

40

, and the movable magnetic bodies

34

can move to the close positions P

1

by means of the pressing forces of the coil springs

40

in accordance with non-excitation of the electromagnetic coil parts

25

.

That is, in this injector module, as described later, when assembling the module to the engine body E side, the columnar parts

31

are disposed inside the small diameter portions

21

ha

and the valve parts

35

are disposed inside the large diameter portions

21

hb,

and the injector main bodies

30

are inserted into the injector main body housing holes

21

h

(see FIG.

4

and FIG.

5

), whereby the injector parts

10

are assembled. At this time, the valve parts

35

are disposed at positions shifting downward from the insides of the electromagnetic coil parts

25

along the axial core directions, so that the movable magnetic bodies

34

inside the valve parts

35

are also disposed at positions shifting downward from the inside of the electromagnetic coil parts

25

along the axial core directions. Therefore, when the electromagnetic coil parts

25

are excited by power supply in a condition where the movable magnetic bodies

34

are pressed to the close positions P

1

, magnetic fluxes generated therefrom pass the insides of the movable magnetic coil parts

34

, and the movable magnetic bodies

34

are attracted toward the insides of the electromagnetic coil parts

25

via the auxiliary core portions

41

, that is, attracted to the open positions P

2

. Also, in this condition, when power supply to the electromagnetic coil parts

25

is interrupted and the condition is changed into a non-excited condition, by the pressing forces of the coil springs

40

, the movable magnetic bodies

34

move to the close positions P

1

.

According to the abovementioned construction, the opening and closing drive of the valve parts

35

becomes possible by excitation and non-excitation of the electromagnetic coil parts

25

in principle, however, in this embodiment, in order to make the opening and closing drive of the valve parts

35

more accurate, the following construction is employed.

That is, as shown in FIG.

4

and

FIG. 5

, in the injector parts

10

, fixing core portions

32

made from a magnetic material are provided at the centers of the electromagnetic coil parts

25

, the movable magnetic bodies

34

are disposed at the lower end sides of the fixing core portions

32

, auxiliary core portions

41

made from a magnetic material are provided around the outer circumferences of the movable magnetic bodies

34

, and furthermore, outer circumferential core portions

27

made from a magnetic material are provided around the outer circumferences of the electromagnetic coil parts

25

, whereby a magnetic circuit is formed so that magnetic fluxes generated in accordance with power supply to the electromagnetic coil parts

25

pass through the fixing core portions

32

, movable magnetic bodies

34

, auxiliary core portions

41

, and outer circumferential core portions

27

in order and then reach the fixing core portions

32

again.

Concretely, in the injector main bodies

30

, columnar fixing core portions

32

are installed inside so as to extend along the center axes of the electromagnetic coil parts

25

within the columnar parts

31

, and the fuel passages

31

p

are formed along the center axes of the fixing core portions

32

. Also, annular auxiliary core portions

41

are provided around the outer circumferences of the columnar parts

36

of the cylindrical parts

36

of the valve parts

35

.

Furthermore, regarding the injector main body housing holes

21

h,

around the outer circumferences of the electromagnetic coil parts

25

and at the outsides of the upper and lower ends of the electromagnetic coil parts

25

, cylindrical outer circumferential core portions

27

made from a magnetic material such as iron plates are provided around the inner circumferences of the injector main body housing holes

21

h.

Thereby, a magnetic circuit is formed in which magnetic fluxes generated due to excitation of the electromagnetic coil parts

25

are passed from the lower end sides to upper end sides of the outer circumferential core portions

27

through the movable magnetic bodies

34

and auxiliary core portions

41

from the lower ends of the fixing core portions

32

and then reach the insides of the fixing core portions

32

again.

Between the fixing core portions

32

and outer circumferential core portions

27

, non-magnetic bodies

28

are interposed. The non-magnetic bodies

28

are formed from a non-magnetic material such as austenite steel or martensite steel, which prevents a temporary connecting condition between the fixing core portions

32

and outer circumferential core portions

27

and prevents magnetic fluxes from the fixing core portions

32

from directly entering the auxiliary core portions

41

without passing through the movable magnetic bodies

34

.

Concretely, the non-magnetic bodies

28

are formed to be roughly annular, and attached to the upper end face sides of the outer circumferential core portions

27

so as to surround the upper ends of the cylindrical parts

36

of the valve parts

35

.

In this embodiment, the annular auxiliary core portions

41

also have a function for releasing the attracted condition of the movable magnetic bodies

34

upward due to residual magnetism after power supply to the electromagnetic coil parts

25

is interrupted.

Furthermore, in this injector module, since the injector electric block body

20

and injector main bodies

30

may be combined so that the movable magnetic bodies

34

move to the open positions P

2

due to the magnetic action resulted by excitation of the electromagnetic coil parts

25

, the injector main bodies

30

are not inserted and fixed into the injector main body housing holes

21

h

of the injector electric block body

20

, and the outer circumferential shapes of the injector main bodies

30

are formed to be slightly smaller than the inner circumferential shapes of the injector main body housing holes

21

h,

and in a condition where slight spaces (for example, 0.5 mm) are left between the outer circumferences of the injector main bodies

30

and the inner circumferences of the injector main body housing holes

21

h,

the injector main bodies

30

are housed and disposed inside the injector main body housing holes

21

h.

Furthermore, the injector main bodies

30

are sandwiched and fixed between the portions at which the injector mounting holes Eh at the engine body E side are formed and the delivery pipe

50

, and the injector electric block body

20

is fixed to the engine body E side via the attaching pieces

29

. Thereby, tolerances in the manufacturing dimensions required for the injector main bodies

30

, injector electric block body

20

and the like become wide, and after assembling to the engine body E, tolerances for thermal contraction to be generated at the injector electric block body

20

and injector main bodies

30

become wide.

Next, the processes for assembling this injector module to the engine body E side are explained.

First, the valve parts

35

of the injector main bodies

30

are inserted and connected to the injector mounting holes Eh at the engine body E side. Next, the columnar parts

31

are disposed inside the small diameter portions

21

ha

and the valve parts

35

are disposed inside the large diameter portions

21

hb,

and then the injector main bodies

30

are inserted into the injector main body housing holes

21

h

of the injector electric block body

20

. In this condition, when the injector electric block body

20

is attached and fixed to the engine body E side via the attaching pieces

29

, while the injector main bodies

30

are maintained in the condition where they are inserted and disposed inside the injector main body housing holes

21

h,

the injector parts

10

are assembled, whereby the injector module is assembled to the engine body E side.

Thereafter, the upper ends of the columnar parts

31

of the injector main bodies

30

that project upward from the injector main body housing holes

21

h

of the injector electric block body

20

are inserted and connected to the fuel supply ports

51

of the delivery pipe

50

side, respectively.

The operation of the injector module thus assembled is explained.

First, in the non-operating condition of the engine, fuel supply to the delivery pipe

50

is stopped and power supply to the electromagnetic coil parts

25

is interrupted, and the movable magnetic bodies

34

are positioned at the close positions P

1

and valve parts

35

are in the closed condition (see FIG.

4

).

Then, when the engine is started, fuel supply to the delivery pipe

50

by an unillustrated fuel pump is started, and at the injector parts

10

, by supply and interruption of a fuel injection control current from the engine control unit

1

, excitation and non-excitation of the electromagnetic coil parts

25

are controlled, and control of fuel injection from predetermined valve parts

35

is made.

That is, focusing attention on one predetermined injector part

10

, when power is supplied to the electromagnetic coil part

25

, the electromagnetic coil part

25

is excited and the movable magnetic body

34

moves to the open position P

2

against the pressing force of the coil spring

40

and the valve part

35

opens by interlocking with the movement. Thereby, fuel to be fed into the delivery pipe

50

is branched at the fuel supply port

51

and fed to the injector main body

30

side, passes through the fuel passage

31

p,

and then is injected from the fuel injection orifice

35

h

of the valve part

35

and supplied to a combustion chamber of the engine body E side via the intake manifold. Thereafter, at said one injector part

10

, when power supply to the electromagnetic coil part

25

is interrupted, the electromagnetic coil part

25

changes into a non-excited condition and the movable magnetic body

34

moves to the close position P

1

due to the pressing force of the coil spring

40

, and interlocking with this, the valve part

35

closes and fuel supply to the combustion chamber is stopped.

The injector module thus constructed comprises an injector electric block body

20

formed so that, in an injector frame body

21

with injector main body housing holes

21

h

made in the frame body at positions corresponding to injector mounting holes Eh of the engine body E side, electromagnetic coil parts

25

are installed and wound around the inner circumferences of the injector main body housing holes

21

h,

and wiring

26

for connection to the electromagnetic coil parts

25

is installed; valve parts

35

formed into roughly columnar shapes to adjust the injection timing of fuel from the fuel injection orifices

35

h;

and injector main bodies

30

having columnar parts

31

which are linearly provided in succession to the valve parts

35

to feed fuel supplied from fuel intakes

31

h

to the valve parts

35

, and movable magnetic bodies

34

which can reciprocate between predetermined open positions P

2

and predetermined close positions P

1

for opening and closing the valve parts

35

and are pressed toward the close positions P

1

, wherein the injector main bodies

30

are inserted into the injector main body housing holes

21

h

in a posture in which the movable magnetic bodies

34

can move to the open positions P

2

due to excitation of the electromagnetic coil parts

25

against the pressing forces, and can move to the close positions P

1

due to the pressing forces in accordance with non-excitation of the electromagnetic coil parts. Therefore, connection of harness terminal connectors to each injector as in the conventional example is not necessary, and therefore, work efficiency of assembly to the engine body E side and waterproofness are excellent.

In addition, different from the conventional example, the harness terminals and injectors are not connector-connected by using harnesses formed of electric wire bundles as wiring members between the engine control unit and injectors, so that reduction in weight can be achieved, accordingly.

Furthermore, fixing core portions

32

are provided and positioned at the centers of the electromagnetic coil parts

25

, movable magnetic bodies

34

are provided to be extensions of the fixing core portions

32

, auxiliary core portions

41

are provided around the outer circumferences of the movable magnetic bodies

34

, and outer circumferential core portions

27

are provided around the outer circumferences of the electromagnetic coil parts

25

, whereby a magnetic circuit is formed so that magnetic fluxes generated in accordance with power supply to the electromagnetic coil parts

25

pass through the fixing core portions

32

, movable magnetic bodies

34

, auxiliary core portions

41

, and outer circumferential core portions

27

and then reach the fixing core portions

32

again. Thereby, the magnetic flux density at the movable magnetic bodies

34

becomes greater and can attract the movable magnetic bodies

34

to the open positions P

2

, and therefore, opening and closing operations can be made more accurate.

Furthermore, since non-magnetic bodies

28

are interposed between the fixing core portions

32

and outer circumferential core portions

27

, magnetic fluxes generated from the fixing core portions

32

are prevented from directly entering the auxiliary core portions

41

without passing through the movable magnetic bodies

34

, whereby more magnetic fluxes can be made to pass through the movable magnetic bodies

34

, and the movable magnetic bodies

34

can be more securely moved to the open positions P

2

by excitation of the electromagnetic coil parts

25

.

As shown in

FIG. 6

, in place of or in addition to the outer circumferential core portions

27

provided around the outer circumferences of the electromagnetic coil parts

25

, between the injector main body housing holes

21

h

of the injector frame body

21

, inter-injector core portions

48

may be provided to form a magnetic circuit in which magnetic fluxes generated in accordance with power supply to the electromagnetic coil parts

25

pass through the adjacent inter-injector core portions

48

.

Concretely, at the lower surface side of the injector frame body

21

of the injector electric block body

20

, columnar inter-injector core portions

48

made from a magnetic material (bolts or the like can be used) are provided between the injector main body housing holes

21

h,

and extended core portions

49

formed of iron plates or the like are extended from the base ends and front ends of the inter-injector core portions

48

toward the upper and lower portions of the adjacent electromagnetic coil parts

25

. Thereby, a magnetic circuit is formed in which magnetic fluxes generated in accordance with power supply to the electromagnetic coil parts

25

pass through the fixing core portions

32

, movable magnetic bodies

34

, auxiliary core portions

41

, lower-side extended core portions

49

, inter-injector core portions

48

, and upper-side extended core portions

49

and then reach the fixing core portions

32

again, and the magnetic flux density at the movable magnetic bodies

34

increases, whereby it becomes possible to more securely move the movable magnetic bodies

34

to the open positions P

2

by means of excitation of the electromagnetic coil parts

25

.

Furthermore, as shown in

FIG. 7

, injector electric block body

20

B may be unified with the delivery pipe

50

.

Concretely, the injector frame body

21

of the injector electric block body

20

B and the delivery pipe

50

may be integrally formed from a heat-resistant resin so that the injector main body housing holes

21

h

at the injector frame body

21

side and the fuel supply ports

51

at the delivery pipe

50

side are communicated with each other. The injector electric block body

20

B are substantially similar to the abovementioned injector electric block body

20

except for the wiring layout of wiring

26

B.

Thus, if the injector electric block body

20

B and delivery pipe

50

are unified with each other, assembly of the block body to the engine body E side becomes easier.

As in the modified example shown in FIGS.

8

through

FIG. 10

, as the construction in which the electromagnetic coil parts

25

and wiring

26

C are connected to each other, a construction may be employed in which coated single-core wires are used as wiring

26

C and the terminals of the wires are pressure-welded to pressure-welding terminals

62

attached to the terminals of the winding wires

25

a

of the electromagnetic coil parts

25

.

That is, explaining a point of difference of this modified example from the abovementioned embodiment, the following injector electric block body

20

C is used in this modified example in place of the injector electric block body

20

in the abovementioned embodiment.

This injector electric block body

20

C has an injector frame body

21

C provided with plate-shaped parts

21

Ca with roughly rectangle plate shapes so as to connect the columnar parts

21

Cb at one-side parts of columnar parts

21

Cb with rough columnar shapes provided for each injector mounting hole Eh. The columnar parts

21

Cb are provided with components similar to the projecting columnar parts

21

b

in the abovementioned embodiment, and components with the same construction as those of the injector main bodies

30

are inserted and disposed for these, and these are provided with the same symbols and description thereof is omitted.

Inside the plate-shaped parts

21

Ca, wiring

26

C is installed and laid in a predetermined wiring pattern on substrate

60

. The substrate

60

is formed into a roughly rectangle shape, and at the outer surface side thereof, a plurality of convex portions

61

for supporting the wiring

26

C in the predetermined wiring pattern are formed. Then, the wiring

26

C composed of coated single-core wires is sandwiched between the convex portions, whereby the wiring

26

C is held in the predetermined wiring pattern.

A pair of pressure-welding terminals

62

are provided at each position of the lower edge of the substrate

60

corresponding to the columnar parts

21

Cb.

The pressure-welding terminals

62

are formed from a conductive material such as metal or the like, and are provided with pressure-welding portions

63

for holding the wiring

26

C by pressure-welding and winding connecting portions

64

to which the winding wires

25

a

of the electromagnetic coil parts

25

are connected. The pressure-welding portion

63

is formed into a rough U shape by providing a pair of side plates on both sides of substrate portion

63

a,

and is attached to the substrate

60

by closely adhering the outer surface of the substrate portion

63

a

to the outer surface lower edge of the substrate

60

. Furthermore, slit-shaped pressure-welding grooves

63

c

which can hold the wiring

26

c

by pressure-welding are formed in the side plates

63

b,

by press-fitting the terminals of the wiring

26

C into the pressure-welding grooves

63

c,

the terminals of the wiring

26

C are held by means of pressure-welding to the pressure-welding portions

63

. The winding connecting portions

64

are formed into band shapes extended from the substrate portions

63

a

of the pressure-welding portions

63

to the lower sides of the electromagnetic coil parts

25

. Then, the winding wires

36

a

of the electromagnetic coil parts

25

are drawn out to the winding connecting portions

64

and welded and electrically connected to the winding connecting portions

64

by means of fusing or the like.

Then, the wiring

26

C is laid in a predetermined wiring pattern on the substrate

60

, the terminals of the wiring

26

C are pressure-welded and connected to the pressure-welding portions

63

of the pressure-welding terminals

62

provided at the lower edge of the substrate

60

, and in a condition where the terminals of the winding wires

25

a

of the electromagnetic coil parts

25

are connected to the winding connecting portions

64

of the pressure-welding terminals

62

, the wiring

26

C and substrate

60

are insert-molded into the injector frame body

21

C together with the electromagnetic coil parts

25

and others, whereby the injector electric block body

20

C is formed.

At one-side ends of the plate-shaped parts

21

Ca of this injector electric block body

20

C, connector parts

23

C having connector terminals electrically connected to the wiring

26

C are formed, and connectors of wire harness terminals drawn out from the engine control unit

1

can be connected to the connector parts

23

.

In this modified example, the one-side portion with the plate-shaped part

21

Ca formed of the outer circumferential core portion

27

C corresponding to the outer circumferential core portion

27

is eliminated, and accordingly, a plate-shaped part

21

Ca is provided in the vicinity of the columnar part

21

Cb to make the construction at this section compact. Furthermore, even when the outer circumferential core portion

27

C whose one-side portion is thus eliminated is used, a magnetic circuit is formed by other outer circumferential core portions

27

C, so that there is no problem.

Furthermore, the injector frame body

21

C of the injector electric block body

20

C is integrally formed with the delivery pipe

50

C, however, they may be separately formed.

As in this modified example, coated single-core wires are used as the wiring

26

C, and the terminals of the wires are pressure-welded and connected to the pressure-welding terminals

62

attached to the ends of the winding wires

25

a

of the electromagnetic coil parts

25

, whereby the wiring

26

C can be easily connected to the pressure-welding terminals

62

.

In this modified example, a mode in which wiring

26

C is installed in the plate-shaped parts

21

Ca provided at one side of each columnar part

21

Cb is explained, however, as in the abovementioned embodiment, the wiring

26

may be installed in the plate-shaped parts

21

a

provided on the projecting columnar parts

21

b.

Furthermore, although the wiring

26

C is insert-molded inside the plate-shaped parts

21

Ca, a construction may be employed in which the plate-shaped parts

21

Ca are divided into two along the longitudinal direction for the main bodies and cover parts and the wiring

26

C is housed between them. In this case, coated conductors may be used for the wiring

26

C.

Further,

FIG. 11

is a schematic drawing showing an example of an engine control system to which this ignition coil device module is applied, wherein engine control unit

101

(so-called EFI-ECU or the like) is connected to ignition coil devices

102

(igniter-combined ignition coils) via input and output portion

101

a,

and connected to a power supply system including various sensors and batteries provided at the engine body side and various parts such as junction blocks and the like inside a vehicle, and further connected to injectors. The engine control unit

101

is constructed so that the ignition timing of the ignition coil devices

102

and the fuel injection amount from the injectors are controlled based on various detection signals from the sensors.

In this engine control system, since a 4-cylinder engine is assumed, four ignition coil devices

102

are provided, however, the number of ignition coil devices may be properly changed depending on the number of cylinders of the engine. The four wires to be connected to each ignition coil device

102

include a wire for applying a primary voltage, a wire for inputting ignition timing signals to a switching device, a ground wire, and a wire for outputting detection signals of operating conditions of the ignition coil devices

102

. Depending on the control method by the engine control system, proper changes such as elimination or the like (for example, elimination of the wire for outputting detecting signals of the operating conditions of the ignition coil devices

102

) are added to these wires.

This ignition coil device module is constructed so that electrical connecting portions between these ignition coil devices

102

and engine control unit

1

and the ignition coil devices

102

are unified with each other, and as shown in FIG.

12

through

FIG. 15

, mainly comprised of a plurality of ignition coil devices

102

; flexible printed board

103

as an example of the flexible wiring having flexibility for electrically connecting the ignition coil devices

102

and the input and output portion

1

a

of the engine control unit

101

to each other; and a plurality of fixed cover members

104

for attaching and fixing the ignition coil devices

102

to predetermined positions of the flexible printed board

103

in a condition where the wiring circuits of the flexible printed board

103

side and the wiring circuits of the ignition coil devices

102

side are connected to each other.

The ignition coil devices

102

are, as shown in FIG.

16

through

FIG. 18

, constructed so that cylindrical connecting portions

102

b

which are smaller in diameter than coil bodies

102

a

and can be inserted into plug holes of the engine side are provided downward from the coil bodies

102

a

in which secondary high voltage generating ignition coils and switching devices are installed.

On one-side surface of each coil body

102

a,

connection surface base portions

102

c

at which connecting terminals

106

for input to and output from internal wiring circuits are arranged and exposed in parallel at predetermined pitches are projectedly formed.

At the projecting end face of the connection surface base portion

102

c,

circumferential annular concave groove

102

d

is formed to surround the outside of each connecting terminal

106

, and at four corners of the outer circumferential surface of the connection surface base portion

102

c,

latching projecting portions

102

e

are projectedly provided, respectively.

The fixed cover members

104

are, as shown in FIG.

19

and

FIG. 20

, molded from a hard resin or the like which has flexibility, and provided with rectangle main bodies

104

a

corresponding to the projecting end faces of the connection surface base portions

102

c,

and at four corners of the outer circumferential surfaces of the main bodies

104

a,

U-shaped latching portions

104

b

are provided corresponding to the latching projecting portions

102

e

of the connection surface base portions

102

c

so as to project in the directions to connection surface base portions

102

c.

Then, as shown in FIG.

13

through

FIG. 15

, in a condition where the flexible printed board

103

is interposed between the projecting end faces of the connection surface base portions

102

c

and the main bodies

104

a

of the fixed cover members

104

, the main bodies

104

a

are pressure-welded to the projecting end face sides, whereby the latching portions

104

b

and latching projecting portions

102

e

are latched with each other in a manner enabling them to unlatch due to elastic deformation of the latching portions

104

b.

Furthermore, in order to make this latching smooth, inclined latching guide surfaces are properly formed on the latching projecting portion

102

e

and latching portions

104

b.

At the opposing surfaces of the main bodies

104

a

of the fixed cover members

104

with respect to the connecting terminals

106

of the connection surface base portions

102

c,

spring housing grooves

104

c

which are long in the parallel-arrangement direction are formed, and in the spring housing grooves

104

c,

pressing elastic materials

108

formed of spring materials that are positioned inside the spring housing grooves and bent into rough U-shapes are held. In this embodiment, the base portions

108

a

of the pressing elastic materials

108

are held to be buried in the fixed cover members

104

.

The pressing elastic materials

108

are formed so as to project from the spring housing grooves

104

c

in their natural conditions as shown in

FIG. 20

, and on the other hand, when the fixed cover members

104

are attached and fixed to the connection surface base portions

102

c,

as shown in FIG.

13

and

FIG. 14

, the pressing elastic materials

108

are elastically deformed in a contracting condition within the spring housing grooves

104

c,

and due to the elastic forces, presses the sandwiched and held flexible printed board

103

against the connecting terminals

106

.

Predetermined wiring conductors are wired on the flexible printed board

103

, and the insulating films opposed to the connecting terminals

106

of the connection surface base portions

102

c

at the attaching and fixing positions of the ignition coil devices

102

are separated and the wiring conductors at portions corresponding to the connecting terminals

106

are exposed, and corresponding to the latching portions

104

b

of the fixed cover members

104

to be attached and fixed to the connection surface base portions

102

c

while sandwiching the flexible printed board

103

, latching portion insertion holes

103

a

are made in the flexible printed board

103

.

At this time, the pitches of electrical connection between the ignition coil devices

102

attached to the flexible printed board

103

are set to be slightly longer than the provision pitches of the ignition coil devices

102

to the engine side.

To one-side end of the flexible printed board

103

, connector

110

for connection to the input and output portion

101

a

of the engine control unit

101

is attached.

In a condition where O-rings as examples of annular sealing members are attached to the concave grooves

102

d

of the connection surface base portions

102

c,

each ignition coil device

102

is disposed at one-side surface of the attaching position of the flexible printed board

103

, and the fixing cover member

104

is pressed against the connection surface base portion

102

c

from the other side surface, whereby the pressing elastic material

108

elastically deforms, and an attached and fixed condition is obtained where each latching portions

104

b

and each latching projecting portions

102

e

are latched with each other.

By this fixed condition, the connecting terminals

106

of each ignition coil device

102

side and wiring conductors of the flexible printed board

103

side are pressure-welded and connected to each other, and the outsides of the electrical connecting portions are surrounded and sealed by the O-rings

112

.

The embodiment is constructed as mentioned above, and since the ignition coil devices

102

are electrically connected to each other by the flexible printed board

103

and unified with each other, assembly to the engine side can be carried out by only attaching the ignition coil devices

102

to the engine side and connecting the connectors

110

to the engine control unit

101

side. Therefore, different from the conventional example, connector-connection for each ignition coil device attached to the engine side is not necessary, so that assembly becomes easy and assembly work efficiency is improved.

Furthermore, since the flexible printed board

103

is used as the wiring for the ignition coil devices

102

, this is advantageous in terms of reduction in weight in comparison with the structure using wire harnesses formed of electric wire bundles.

Since the outsides of the connecting portions between the connecting terminals

106

of each ignition coil device

102

side and the wiring conductors of the flexible printed board

103

side are surrounded and sealed by O-rings

112

, water entrance to the electrical connecting portions is effectively prevented.

Furthermore, by the elastic forces of the pressing elastic materials

108

, the exposed portions of the wiring conductors of the flexible printed board

103

side are pressed against the connecting terminals

106

, electrical connecting conditions are more stably secured.

In addition, a system is employed in which the flexible printed board

103

is sandwiched and fixed by fixing the fixed cover members

104

to the connection surface base portions

102

c

of the ignition coil devices

102

and the connecting terminals

106

and wiring conductors of the flexible printed board

103

are electrically connected to each other by this sandwiching fixation, and this system has an advantage whereby assembly of the ignition coil device module can be easily carried out.

Furthermore, the pitches of electrical connection of the connecting terminals to the flexible printed board

103

are set to be slightly longer than the provision pitches of the ignition coil devices

102

, so that an advantage is also obtained whereby deviations and the like due to manufacturing tolerances and thermal expansion of the engine or the like can be effectively absorbed by the allowance in the flexible printed board

103

.

Then, since the connecting terminals

106

are connected by the flexible printed board

103

with flexibility, and in addition, the connecting pitches are set to be longer than the provision pitches of the ignition coil devices

102

, the ignition coil device module can be commonly used for engines if the engines are types whose provision pitches are shorter than the connecting pitches and which have the same number of cylinders, whereby applicability of the module for general purposes is also improved.

Furthermore, the flexible printed board

103

and fixed cover members

104

are installed inside a cylinder head cover made from a resin or the like, and if the flexible printed board

103

and fixed cover members

104

are installed in advance, by fixing the coil bodies

102

a

of the ignition coil devices

102

to the fixed cover members

104

, assembly of the ignition coil devices

102

to the cylinder head is completed, and this further improves assembly work efficiency.

In the abovementioned embodiment, a structure using the flexible printed board

103

as flexible wiring is shown, however, a structure using other flat cables and a plurality of electric wires may be employed.

Also, a structure using the O-rings

112

as annular sealing members is shown, however, annular packing materials and the like may be used.

[Effects of the Invention]

As mentioned above, according to the injector module described in Aspect 1 of the invention, the module comprises an injector electric block body formed so that, inside an injector frame body having injector main body housing holes made in it at positions corresponding to injector mounting holes of the engine body side, electromagnetic coils are installed and wound around the inner circumferences of the injector main body housing holes and wiring for connection to the electromagnetic coil parts is installed; valve parts which are formed to be columnar and adjust the injection timing of fuel from fuel injection orifices; and injector main bodies, which are provided with columnar parts linearly provided in succession to the valve parts to feed fuel supplied from fuel intakes to the valve parts, and movable magnetic bodies that can reciprocate between predetermined open and close positions for opening and closing the valve parts and are pressed toward the close positions, wherein the injector main bodies are inserted into the injector main body housing holes in a posture in which the movable magnetic bodies can move to the open positions against the pressing forces due to excitation of the electromagnetic coil parts, and can move to the close positions due to the pressing forces in accordance with non-excitation of the electromagnetic coil parts. Therefore, connection of the harness terminal connectors to each injector in the vicinity of the engine body as in the conventional example is not necessary, and therefore, assembly work efficiency to the engine body side and waterproofness are excellent.

Furthermore, different from the conventional example, the harness terminals and injectors are not connector-connected by using harnesses formed of electric wire bundles for wiring members between the engine control unit and injectors, so that reduction in weight can be achieved, accordingly.

As described in Aspect 2, fixing core portions are provided at the centers of the electromagnetic coil parts, movable magnetic bodies are provided to be extensions of the fixing core portions, auxiliary core portions are provided around the outer circumferences of the movable magnetic bodies, and outer circumferential core portions are provided around the outer circumferences of the electromagnetic coil parts, whereby a magnetic circuit is formed in which magnetic fluxes generated by power supply to the electromagnetic coil parts pass through the fixing core portions, movable magnetic bodies, auxiliary core portions, and outer circumferential core portions, and then reach the fixing core portions again. Thereby, the magnetic flux density at the movable magnetic bodies becomes high, the movable magnetic bodies can be attracted to the open positions by greater attraction forces, and therefore, the opening and closing operations can be more securely carried out.

Furthermore, as described in Aspect 3, when non-magnetic bodies are interposed between the fixing core portions and outer circumferential core portions, magnetic fluxes that have come out from the fixing core portions are prevented from directly entering the auxiliary core portions without passing through the movable magnetic bodies, and it becomes possible to make more magnetic fluxes pass through, and accordingly, the movable magnetic bodies can be more securely moved to the open positions by means of excitation of the electromagnetic coil parts.

Furthermore, as described in Aspect 4, in place of or in addition to the outer circumferential core portions provided around the outer circumferences of the electromagnetic coil parts, inter-injector core portions are provided between the injector main body housing holes of the injector frame body to form a magnetic circuit in which magnetic fluxes generated by power supply to the electromagnetic coil parts pass through the adjacent inter-injector core portions, whereby the magnetic flux density at the movable magnetic bodies increases, the movable magnetic bodies can be attracted to the open positions by greater forces, and therefore, the opening and closing operations can be more securely carried out.

As described in Aspect 5, if the injector electric block body is unified with the delivery pipe, assembly of the block body and the pipe to the engine body can be more easily carried out.

Furthermore, as described in Aspect 6, the winding terminals of the electromagnetic coil parts are connected to the pressure-welding terminals, and coated single-core wires are used for the wiring and the ends of the wires are pressure-welded and connected to the pressure-welding terminals, whereby the wiring can be easily connected to the pressure-welding terminals.

Furthermore, according to the injector electric block body of an injector module described in Aspect 7 of the invention, a plurality of injector parts are provided in accordance with the combustion chambers of the engine, and fuel injection control of the injector parts is made by an engine control unit, wherein said injector electric block body comprises an injector frame body having injector main body housing holes made in it at positions corresponding to injector mounting holes of the engine body side, electromagnetic coil parts for opening and closing valve parts of injector main bodies inserted into the injector main body housing holes, and wiring for connection to the electromagnetic coil parts that are installed inside the injector frame body. Therefore, connection of connectors of harness terminals to each injector in the vicinity of the engine body as in the conventional example is not necessary, so that assembly work efficiency to the engine body side and waterproofness are excellent, and reduction in weight can be achieved as a result of the unnecessary connectors.

According to the injector main bodies described in Aspect 8, the main bodies are formed into roughly columnar shapes with fuel intakes at one-side end and fuel injection orifices at the other side ends, and comprise valve parts which are provided at the fuel injection orifice sides to adjust the injection timing of fuel supplied through the fuel intakes; and movable magnetic bodies which can reciprocate between predetermined open and close positions for opening and closing the valve parts and are pressed toward the close positions, and move to the open positions due to excitation of the electromagnetic coil parts provided at the injector mounting hole sides of the injector electric block body side against the pressing forces to open the valve parts. Therefore, connection of harness terminal connectors to each injector as in the conventional example is not necessary, and therefore, assembly work efficiency to the engine body side and waterproofness are excellent, and also, as a result of the connectors being made unnecessary, reduction in weight can be achieved.

Further, as described above, according to the ignition coil device module of the invention, ignition coil devices are electrically connected to each other at predetermined pitches by flexible wiring with flexibility and unified with each other, and ignition control is made through the flexible wiring, and assembly to the engine side is completed by only attaching the ignition coil devices to the engine side and connecting the ends of the flexible wiring to the engine control unit side. Therefore, different from the conventional example, connector-connection to each ignition coil device attached to the engine side is not necessary, so that assembly becomes easy and assembly work efficiency can be improved.

If a structure using a flexible printed board as flexible wiring is employed, this has an advantage whereby reduction in weight can be achieved in comparison with the structure using wire harnesses formed of electric wire bundles.

Furthermore, if a structure in which the pitches of electrical connection of the ignition coil devices to the flexible wiring are set to be longer than the provision pitches of the ignition coil devices to the engine or the like is employed, deviations due to manufacturing tolerances and thermal expansions of the engine or the like can be effectively absorbed by allowances in the flexible wiring, and the ignition coil device module can be commonly used for engines if the engines are types whose provision pitches are shorter than the connection pitches and which have the same number of cylinders.

Furthermore, if a structure in which connection surface base portions at which electrical connecting terminals are exposed are provided at one surface of each ignition coil device, fixed cover members are provided to be fixed in a detachable manner to the connection surface base portions so as to surround the outsides of the connecting terminals at the connection surface base portions, and the fixed cover members are fixed to the connection surface base portions, whereby flexible wiring is sandwiched and fixed between the fixed cover members and connection surface base portions, wiring conductors at portions in the flexible wiring thus sandwiched and fixed corresponding to the connecting terminals of the connection surface base portions are exposed, and the connecting terminals and wiring conductors are electrically connected to each other by the sandwiching fixation, assembly of the ignition coil device module can be easily carried out.

Furthermore, if a structure is employed in which annular sealing members are provided to surround the outsides of the connecting portions between the connecting terminals and wiring conductors are provided between the connection surface base portions and fixed cover members, water entrance to the electrical connecting portions between the connecting terminals and wiring conductors can be effectively prevented.

Furthermore, if a structure is employed in which pressing elastic materials are provided on the fixed cover members for pressing the exposed portions of the wiring conductors against the connecting terminals when the fixed cover members are fixed to the connecting terminals to sandwich and fix the flexible wiring, electrical connecting conditions of the connecting terminals and wiring conductors can be more stably obtained.

Furthermore, if a structure provided with a cylinder head cover in which the flexible wiring and fixed cover members are installed is employed, assembly work efficiency is further improved.

Number	Date	Country	Kind
2000-368152	Dec 2000	JP
2001-046325	Feb 2001	JP

Number	Name	Date	Kind
5030116	Sakai et al.	Jul 1991	A
5086743	Hickey	Feb 1992	A
5127382	Imoehl	Jul 1992	A
6019928	Fujitani et al.	Feb 2000	A
6053148	Glovatsky et al.	Apr 2000	A
6612290	Nozaki et al.	Sep 2003	B2

Injector module, injector electric block body, injector main bodies to be used for the same, and ignition coil device module

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Term Extension

Abstract

Description

Claims

Priority Claims (2)

US Referenced Citations (6)

Foreign Referenced Citations (1)