JP2008064039A - Fuel supplying device of multi-cylinder engine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the consuming amount of second fuel by uniformly distributing the second fuel injected from a single fuel flow rate control valve into a plurality of cylinders while using the single fuel flow rate control valve. <P>SOLUTION: The fuel supplying device of a multi-cylinder engine is composed of a first fuel supplying device 41 equipped with a plurality of solenoid fuel injection valves V1 capable of individually injecting first fuel F1 to intake air passages Ma of a plurality of cylinders Ec, a plurality of fuel nozzles 51 individually opening to the intake air passages Ma and a second fuel distributing pipe 50 distributing the second fuel F2 into those, and a second fuel supplying device 42 equipped with a single solenoid fuel flow rate control valve V2 attached to a fuel introducing inlet member 58 of the second fuel distributing pipe 50 and capable of discharging the second fuel F2 into the second fuel distributing pipe 50. On the fuel flow rate control valve V2, a seal holder 66 liquid-tightly welded to a valve seat member 3 so as to surround a valve hole of the valve seat member 3, and a seal means 61 attached to an annular seal groove 67a of the seal holder 66 and made from a seal member 69 are provided. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  In the present invention, a multi-cylinder engine is separately supplied with a first fuel (eg, alcohol) used during normal operation and a second fuel (eg, gasoline) used during start-up or warm-up operation. , It relates to the improvement of the fuel supply system of a multi-cylinder engine.

Conventionally, as a fuel supply device for such a multi-cylinder engine, as disclosed in Patent Document 1, a plurality of electromagnetic types capable of individually injecting a first fuel into a plurality of intake passages respectively connected to a plurality of cylinders. A first fuel supply device having a fuel injection valve; and a second fuel having a single electromagnetic fuel flow control valve capable of injecting a second fuel into an intake distribution chamber connected to an upstream end of the plurality of intake passages. What consists of a supply apparatus is known.
JP 58-20943 A

  By the way, the above-mentioned conventional apparatus is advantageous in terms of cost reduction because a single fuel flow control valve is sufficient, but the injected fuel from the single fuel flow control valve is mixed with air in the intake distribution chamber. Since it is difficult to evenly distribute to a plurality of cylinders, the fuel injection amount from the fuel flow control valve is set to a large number in order to avoid excess or deficiency of the second fuel supplied to each cylinder. Forced to do that.

  The present invention has been made in view of such circumstances, and enables the second fuel injected therefrom to be evenly distributed to a plurality of cylinders while using a single fuel flow control valve. An object of the present invention is to provide a fuel supply device for the multi-cylinder engine that can reduce the consumption of the second fuel.

  In order to achieve the above object, the present invention provides a multi-cylinder engine in which a first fuel used during normal operation and a second fuel used during start-up are separately supplied. In the fuel supply device, a first fuel supply device including a plurality of electromagnetic fuel injection valves capable of individually injecting first fuel into a plurality of intake passages respectively connected to a plurality of cylinders, and a plurality of intake passages individually A plurality of fuel nozzles that open, a second fuel distribution pipe that distributes the second fuel to the fuel nozzles, and a fuel inlet member of the second fuel distribution pipe are attached to discharge the second fuel into the second fuel distribution pipe And a second fuel supply device having a single electromagnetic fuel flow control valve, the valve comprising a valve hole that opens at an end surface of the valve seat member. A seal holder that is liquid-tightly coupled to In that a more composed sealing means and the sealing member closely mounted on the annular seal groove formed in the outer periphery of the seal holder to the fuel inlet member inner peripheral surface and the first feature.

  The intake passage corresponds to an intake pipe Ma in an embodiment of the present invention described later.

  According to the present invention, in addition to the first feature, the seal holder includes an annular channel portion having a seal groove and fitted to the outer peripheral surface of the valve seat member, and an inner periphery from one inner peripheral edge of the channel portion. A ring-shaped flange that protrudes in the direction and overlaps the end surface of the valve seat member, and an annular weld portion is formed between the ring-shaped flange and the end surface of the valve seat member for liquid-tight coupling. Two features.

  Furthermore, in addition to the first or second feature, the third feature of the present invention is that the fuel flow control valve is configured in the same structure as the fuel injection valve except for its sealing means.

  According to the first aspect of the present invention, the second fuel can be evenly distributed to the plurality of intake passages while using a single fuel flow control valve, and therefore the second fuel is distributed to the plurality of cylinders. Since even supply is possible and the engine can be accurately started with as little second fuel as possible, it is economical.

  In addition, the fuel flow control valve includes a seal holder that is connected to the valve seat member of the valve seat member in a liquid-tight manner surrounding a valve hole that opens at an end surface thereof, and an annular seal groove formed on the outer periphery of the seal holder. Since a sealing means is provided which is mounted and is a sealing member that comes into close contact with the inner peripheral surface of the fuel inlet member of the fuel distribution pipe, the end face of the valve seat member is exposed to the high-pressure second fuel during engine startup. However, it is possible to reliably prevent the second fuel from leaking outside through the outer peripheral surface of the valve seat member and the inner peripheral surface of the fuel introduction cylinder by the seal holder and the seal member.

  According to the second feature of the present invention, the seal holder has an annular channel portion that has a seal groove and is fitted to the outer peripheral surface of the valve seat member, and protrudes inwardly from the inner peripheral edge of the channel portion. And an annular flange that overlaps the end face of the valve seat member, and an annular weld is formed between the annular flange and the end face of the valve seat member to form a liquid-tight connection. The annular welded portion can more reliably leak the second fuel through the outer peripheral surface of the valve seat member, and can increase the coupling strength between the valve seat member and the seal holder.

  According to the third feature of the present invention, the fuel flow control valve is configured in the same structure as the fuel injection valve except for its sealing means, so that most parts of the fuel injection valve can be used in common. This can greatly reduce the cost.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below based on examples of the present invention shown in the accompanying drawings.

  1 is a plan view of a multi-cylinder engine equipped with a fuel supply device of the present invention, FIG. 2 is an enlarged sectional view taken along line 2-2 of FIG. 1, FIG. 3 is an enlarged plan view of part 3 of FIG. 4 is a sectional view taken along line 5-5 in FIG. 4, FIG. 6 is an enlarged sectional view taken along line 6-6 in FIG. 4, and FIG. 7 is an enlarged sectional view taken along line 7-7 in FIG.

  First, in FIG. 1, the multi-cylinder engine E has four cylinders Ec, Ec,. An exhaust manifold ME is joined to the front surface of the cylinder head Eh of the engine E, and an intake manifold MI is joined to the rear surface thereof.

  The intake manifold MI is coupled to a plurality of intake pipes Ma, Ma, which are provided in the cylinder head Eh and communicate with intake ports Ei, Ei,... Of the cylinders Ec, Ec, and upstream ends of the intake pipes Ma, Ma,. The throttle body TH having a throttle valve is connected to the inlet of the intake distribution box Mb.

  The intake manifold MI includes a first fuel supply device 41 that supplies the engine E with a first fuel F1 (for example, alcohol or a fuel mainly composed of alcohol) during normal operation, and a second fuel supply device 41 that starts when the engine E is started. A second fuel supply device 42 that supplies fuel F2 (for example, gasoline or fuel mainly composed of gasoline) is connected.

  The first fuel supply device 41 includes a first fuel tank 43 that stores the first fuel F1, a first fuel pump 45 that is installed in the first fuel tank 43, pressurizes and discharges the first fuel F1, A single first fuel distribution pipe 49 connected to the discharge port of the first fuel pump 45 via a first fuel conduit 47 and downstream ends of a plurality of intake pipes Ma, Ma,. It comprises a plurality of electromagnetic fuel injection valves V1, V1,... That inject fuel distributed from one fuel distribution pipe 49 toward the corresponding intake port Ei. The first fuel pump 45 is electrically operated and includes a pressure regulator that adjusts the discharge pressure of the first fuel F1 to a predetermined value. The first fuel distribution pipe 49 is supported by the intake manifold MI.

  On the other hand, the second fuel supply device 42 includes a second fuel tank 44 that stores the second fuel F2, a second fuel pump 46 that pumps up and discharges the second fuel F2 from the second fuel tank 44, and the first fuel pump 46. A single electromagnetic fuel flow control valve V2 connected to the discharge port of the fuel pump 45 via a second fuel conduit 48, and a second fuel distribution pipe 50 connected to the fuel outlet of the fuel flow control valve V2. And a plurality of fuel nozzles 51, 51,... Attached to intermediate portions of the plurality of intake pipes Ma, respectively, for injecting the fuel distributed from the second fuel distribution pipes 50 into the corresponding intake pipes Ma, The second fuel distribution pipe 50 is supported by the intake manifold MI.

  In FIG. 2, the fuel injection valve V1 in the first fuel supply device 41 will be described.

  A casing 1 of the fuel injection valve V1 includes a cylindrical valve housing 2 (magnetic material), a bottomed cylindrical valve seat member 3 that is liquid-tightly coupled to the front end of the valve housing 2, and a valve housing 2 It is comprised from the cylindrical fixed core 5 couple | bonded liquid-tightly on both sides of the annular spacer 4 in the rear end.

  The annular spacer 4 is made of a non-magnetic metal, for example, stainless steel, and the valve housing 2 and the fixed core 5 are abutted against both end surfaces of the annular spacer 4 so as to be welded in a liquid tight manner.

  A first fitting tube portion 3a and a second fitting tube portion 2a are formed at opposite ends of the valve seat member 3 and the valve housing 2, respectively. The first fitting cylinder 3a is press-fitted together with the stopper plate 6 into the second fitting cylinder 2a, and the stopper plate 6 is sandwiched between the valve housing 2 and the valve seat member 3. After the first and second fitting tube portions 3a, 2a are fitted, the outer peripheral surface of the first fitting tube portion 3a exposed from the first fitting tube portion 2a and the end surface of the second fitting tube portion 2a Laser welding is performed over the entire circumference of the sandwiched annular corner, whereby the valve housing 2 and the valve seat member 3 are liquid-tightly coupled to each other.

  The valve seat member 3 includes a valve hole 7 that opens to a front end surface thereof, a conical valve seat 8 that is continuous with the inner end of the valve hole 7, and a cylindrical guide hole 9 that is continuous with a large diameter portion of the valve seat 8. The guide hole 9 is formed coaxially with the second fitting cylinder portion 2a.

  A steel plate injector plate 10 is liquid-tightly welded to the front end surface of the valve seat member 3 and a plurality of fuel injection holes 38, 338... Communicating with the valve hole 7 are formed in the injector plate 10. Is done.

  A movable core 12 facing the front end surface of the fixed core 5 is slidably accommodated in the valve housing 2 and the annular spacer 4, and is accommodated in the movable core 12 in the guide hole 9 so as to be slidable in the axial direction. The valve body 16 is integrally coupled. The valve body 16 is in contact with the stopper plate 6 in contact with a spherical valve portion 16a that can be seated on the valve seat 8, a pair of front and rear journal portions 16b and 16b that are slidably supported in the guide hole 9. A flange 16c that defines the valve opening limit of the body 16 is integrally provided, and each journal portion 16b is provided with a plurality of chamfered portions 17, 17.

  The fixed core 5 has a hollow portion 21 communicating with the inside of the valve housing 2 through a notch 20 on the outer periphery of the upper end portion of the movable core 12, and the movable core 12 is closed to the valve portion 16 in the hollow portion 21. A coiled valve spring 22 that is biased in the direction, that is, the seating direction on the valve seat 8, and a pipe-shaped retainer 23 that supports the rear end of the valve spring 22 are accommodated.

  At this time, a positioning recess 24 for receiving the front end portion of the valve spring 22 is formed on the rear end surface of the movable core 12. The set load of the valve spring 22 is adjusted by adjusting the fitting and fixing position of the retainer 23 to the hollow portion 21.

  A fuel inlet cylinder 25 having a fuel inlet 25a communicating with the hollow portion 21 of the fixed core 5 through a pipe-shaped retainer 23 is integrally connected to the rear end of the fixed core 5, and a fuel inlet cylinder 25a is connected to the fuel inlet cylinder 25a. A filter 27 is attached. An O-ring 19 is attached to the outer periphery of the fuel inlet cylinder 25. The first fuel distribution pipe 49 is provided with the same number of first fuel distribution port cylinders 53, 53... As the plurality of fuel injection valves V1, V1,. When the rear end portion is fitted, the O-ring 19 comes into close contact with the inner peripheral surface of the fuel distribution port cylinder 53.

  A coil assembly 28 is fitted on the outer periphery of the annular spacer 4 and the fixed core 5. The coil assembly 28 includes a bobbin 29 fitted to the outer circumferential surface of the annular spacer 4 and the fixed core 5, and a coil 30 wound around the bobbin 29, and a coil housing 31 surrounding the coil assembly 28. Is connected to the outer peripheral surface of the valve housing 2 by welding.

  The coil housing 31, the coil assembly 28, and the fixed core 5 are embedded in a synthetic resin coating 32, and a coupler that accommodates a connection terminal 33 connected to the coil 30 in the middle of the coating 32. 34 are continuously provided.

  An annular seal stopper 39 is fitted to the outer periphery of the valve housing 2 and the valve seat member 3. The seal stopper 39 and a synthetic resin cap 35 fitted to the front end portion of the valve seat member 3. An annular groove 36 is defined therebetween, and an O-ring 37 that is in close contact with the outer peripheral surface of the valve seat member 3 is attached to the annular groove 36, and the O-ring 37 serves as a front end portion of the electromagnetic fuel injection valve V 1. When mounted in the mounting holes 40 provided in the respective intake pipes Ma of the intake manifold MI, they are brought into close contact with the inner peripheral surface of the mounting holes 40.

  Thus, when the coil 30 is demagnetized, the valve body 16 is pressed forward by the urging force of the valve spring 22, and the valve portion 16 a is seated on the valve seat 8. Therefore, the fuel pressurized by the first fuel pump 45 and distributed to each fuel injection valve V1 by the first fuel distribution pipe 49 passes through the fuel filter 27 and the fuel inlet cylinder 25 of each fuel injection valve V1 and enters the valve housing 1. And is made to wait.

  When the coil 30 is energized by energization, the magnetic flux generated by the coil 30 sequentially travels through the fixed core 5, the coil housing 31, the valve housing 2, and the movable core 12, and the magnetic core is attracted to the fixed core 5 together with the valve body 16 by the magnetic force. Since the valve seat 8 is opened, the high-pressure fuel in the valve housing 2 passes through the valve hole 7 through the chamfered portion 17 of the valve portion 16, and passes from the fuel injection holes 38, 38... To the intake port Ei of the engine E. Be injected.

  Next, the second fuel distribution pipe 50, the fuel flow control valve V2, and the fuel nozzle 51 will be described with reference to FIGS.

  3 to 6, the second fuel distribution pipe 50 is formed by brazing a pair of inner and outer channel members 55 and 56 that are fitted to each other, with the bottom wall of the inner channel member 55 facing outward. By bulging, a fuel distribution passage 50 a is defined between the bottom walls of both channel members 55 and 56. A fuel inlet member 58 is fixed to the bottom wall of the inner channel member 55 by brazing or the like.

  As shown in FIGS. 5 and 7, the fuel introduction port member 58 has an L-shaped introduction hole 58a having one end opened in the second fuel distribution pipe 50, and a large diameter connected to the other end of the introduction hole 58a. The front end portion of the fuel flow control valve V2 is fitted into the mounting hole 58b via the sealing means 61. A fuel supply port cylinder 57 is mounted via a seal member 52 at the rear end of the fuel flow control valve V2. The sealing means 61 will be described in detail later.

  A bracket 59 having a pair of arm portions 59a, 59a disposed on both sides of the fuel flow control valve V2 is fixed to the second fuel distribution pipe 50 by welding or the like, and the arm portions 59a, 59a of the bracket 59 are attached to the arm portions 59a, 59a. Welding nuts 62, 62 are provided.

  As shown in FIGS. 3 to 5, a pair of connecting rods 60 and 60 projecting so as to overlap the pair of arm portions 59 a and 59 a are fixed to the end wall of the fuel supply port cylinder 57. The connecting rods 60, 60 and the arm portions 59a, 59a are coupled by the welding nuts 62, 62 and bolts 63, 63 screwed to these. Thus, the fuel flow rate control valve V2 is held between the fuel introduction port member 58 and the fuel supply port cylinder 57. A connecting pipe 65 projects from the rear end of the fuel supply port cylinder 57, and the second fuel conduit 48 is connected to the connecting cylinder 65.

  Next, as shown in FIG. 7, the fuel flow control valve V2 has the same structure as the fuel injection valve V1 from the valve seat member 3 at the front end to the fuel filter 73 at the rear end. The parts corresponding to the injection valve V1 are denoted by the same reference numerals, the description thereof will be avoided, and only the parts different from the fuel injection valve V1 will be described below.

  The valve seat member 3 of the fuel flow control valve V2 is provided with a sealing means 61 for sealing the space between the fuel introduction port member 58 and the mounting hole 58b. The seal means 61 has a seal groove 67 a and is made of a metal-made annular channel portion 67 that is press-fitted into the outer peripheral surface of the valve seat member 3, and protrudes inwardly from the inner peripheral edge of the front end of the channel portion 67. An annular welded portion 70 is provided that includes a seal holder 66 composed of an annular flange 68 that overlaps the end surface of the valve seat member 3, and an annular welded portion 70 that liquid-tightly couples the annular holder 68 and the end surface of the valve seat member 3. It is formed. When the annular welded portion 70 is formed, thermal distortion of the valve seat 8 due to welding can be avoided by using laser welding that ensures welding with low heat input. A seal member 69 that is in close contact with the inner peripheral surface of the mounting hole 58b of the fuel inlet member 58 is mounted in the seal groove 67a.

  Thus, if the coil 30 is energized by energization, the magnetic flux sequentially travels through the fixed core 5, the coil housing 31, the valve housing 2 and the movable core 12 as in the case of the fuel injection valve V1. Is sucked into the fixed core 5 together with the valve body 16 so that the valve body 16 is opened and the valve seat 8 is opened, so that the high-pressure second fuel F2 waiting in the valve housing 2 is chamfered in the valve section 16. 17 and discharged from the valve hole 7. However, in the fuel flow control valve V2, the fuel discharged from the valve hole 7 is supplied into the second fuel distribution pipe 50, and the flow rate of the discharged fuel is preset by the valve opening stroke of the valve body 16.

  The first fuel pump 45, the fuel injection valve V1, the second fuel pump 46, and the fuel flow control valve V2 are based on signals from various sensors (not shown) for detecting the state of the engine E by the electronic control unit 71. It is controlled by a control signal to be output.

  Next, as shown in FIG. 6, the fuel nozzle 51 is provided with a fuel filter 73 at an upstream end portion of a fuel passage 72 passing through the fuel nozzle 51, and a metering jet 74 is formed at the downstream end portion thereof. O-rings 75 and 76 are attached to the outer periphery of both ends of the fuel nozzle 51, respectively. The same number of second fuel distribution port tubes 54, 54... Are connected to the bottom wall of the outer channel member 56 of the second fuel distribution pipe 50 and communicated with the fuel distribution passage 50 a. The The upstream end of the fuel nozzle 51 is fitted to each second fuel distribution port cylinder 54 via an O-ring 75. Further, the downstream end portion of the fuel nozzle 51 is fitted into a nozzle mounting hole 78 opened in each intake pipe Ma of the intake manifold MI via an O-ring 76.

  Next, the operation of this embodiment will be described.

  When the engine E is started, the second fuel pump 46 is activated by a control signal from the electronic control unit 71, the coil 30 of the fuel flow control valve V2 is energized, and the valve body 16 is opened. Therefore, the second fuel pump 46 pumps the second fuel F2 in the second fuel tank 44 to the fuel flow control valve V2, and the second fuel F2 is supplied from the valve hole 7 of the fuel flow control valve V2 to the second fuel component. After being discharged into the pipe 50 and filling its interior, it is distributed to a plurality of fuel nozzles 51, 51..., And is measured by the fuel passages 72 of these fuel nozzles 51, 51. Then, the fuel is injected into the corresponding intake pipe Ma. Therefore, the second fuel F2 can be evenly distributed to the plurality of intake pipes Ma while using the single fuel flow control valve V2. The second fuel F2 injected into each intake pipe Ma is supplied to the corresponding cylinder Ec while being mixed with air flowing through each intake pipe Ma. Thus, the second fuel F2 can be evenly supplied to the plurality of cylinders Ec, Ec, and the engine E can be started and warmed up accurately with the least amount of the second fuel F2, which is economical. .

  By the way, the fuel flow control valve V2 is formed on the valve seat member 3 of the fuel flow control valve V2 so as to surround the valve hole 7 opened at the end face thereof and to be liquid-tightly coupled, and on the outer periphery of the seal holder 66. During the start of the engine E, the sealing means 61 is provided which comprises the sealing member 69 that is mounted in the annular sealing groove 67a and is in close contact with the inner peripheral surface of the mounting hole 58b of the fuel inlet port 58 of the second fuel distribution pipe 50. Even if the end surface of the valve seat member 3 is exposed to the high-pressure second fuel F2, the second fuel F2 is exposed to the outside through the outer peripheral surface of the valve seat member 3 and the inner peripheral surface of the mounting hole 58b of the fuel inlet member 58. Leakage can be reliably prevented by the seal holder 66 and the seal member 69.

  In particular, the seal holder 66 has an annular channel portion 67 that has a seal groove 67 a and is fitted to the outer peripheral surface of the valve seat member 3, and protrudes inwardly from an inner peripheral edge of the channel portion 67 to the valve seat member. 3, and an annular welded portion 70 is formed between the annular flange 68 and the end surface of the valve seat member 3 in a liquid-tight manner. The annular welded portion 70 can more reliably leak the second fuel F2 through the outer peripheral surface of the valve seat member 3 and can increase the coupling strength between the valve seat member 3 and the seal holder 66.

  Further, since the fuel flow control valve V2 is configured in the same structure as the fuel injection valve V1 except for the sealing means 61, most parts of the fuel injection valve V1 can be used in common, thereby reducing the cost. Can greatly contribute.

  When the engine E is started, the operation of the second fuel pump 46 is stopped by the control signal from the electronic control unit 71, and the fuel flow control valve V2 is closed, so that the second fuel to each intake pipe Ma is closed. The supply of F2 is stopped. Instead, the first fuel pump 45 is now activated, and the first fuel F1 in the first fuel tank 43 is pumped to the plurality of fuel injection valves V1, V1,. The first fuel pump 45 may start to operate when the engine E is started.

  In the normal operation state of the engine E, as usual, during the intake stroke of each cylinder Ec of the engine E, the coil 30 of the fuel injection valve V1 corresponding to the cylinder Ec is set for a predetermined time by the control signal from the electronic control unit 71. Since the energization is performed and the valve body 16 is opened, the first fuel F1 pumped from the first fuel pump 45 is injected from the fuel injection holes 38, 38... Of the fuel injection valve V1 toward the corresponding intake port Ei. It is supplied to the corresponding cylinder Ec. Thus, the normal operation of the engine E can be performed with the first fuel F1.

  The present invention is not limited to the above embodiment, and various design changes can be made without departing from the scope of the invention. For example, the present invention can be configured so that the second fuel F2 is used even during the warm-up operation of the engine E, and both are temporarily used when switching from the second fuel F2 to the second fuel F2. The fuels F1 and F2 may be used.

The top view of a multicylinder engine provided with the fuel supply apparatus of this invention. FIG. 2 is an enlarged sectional view taken along line 2-2 in FIG. 1. FIG. 3 is an enlarged plan view of part 3 of FIG. 1. FIG. 4 is a view taken in the direction of arrow 4 in FIG. 3. FIG. 5 is a sectional view taken along line 5-5 of FIG. FIG. 6 is an enlarged sectional view taken along line 6-6 in FIG. FIG. 7 is an enlarged sectional view taken along line 7-7 in FIG.

Explanation of symbols

E ... Multi-cylinder engine Ec ... Cylinder F1 ... First fuel F2 ... Second fuel Ma ... Intake passage (intake pipe)
V1 ... Fuel injection valve V2 ... Fuel flow control valve 3 ... Valve seat member 7 ... Valve hole 41 ... First fuel supply device 42 ... First 2. Fuel supply device 49... First fuel distribution pipe 50... Second fuel distribution pipe 51... Fuel nozzle 58. ··· Seal holder 67 ··· Channel portion 68 ··· Ring portion 69 ··· Seal member 70 ··· Ring welded portion

Claims (3)

In the fuel supply device for a multi-cylinder engine, the first fuel (F1) used during normal operation and the second fuel (F2) used during start-up are individually supplied to the multi-cylinder engine (E).
A first fuel supply device (41) comprising a plurality of electromagnetic fuel injection valves (V1) capable of individually injecting the first fuel (F1) into a plurality of intake passages (Ma) respectively connected to a plurality of cylinders (Ec). A plurality of fuel nozzles (51) individually opened in the plurality of intake passages (Ma), a second fuel distribution pipe (50) for distributing the second fuel (F2) to the fuel nozzles (51), and A single electromagnetic fuel flow control valve attached to the fuel inlet member (58) of the second fuel distribution pipe (50) and capable of discharging the second fuel (F2) into the second fuel distribution pipe (50) The fuel flow control valve (V2) includes a valve hole (7) that opens to the end face of the valve seat member (3). A seal holder (66) that is liquid-tightly coupled to the seat member (3), and this seal holder (6 ) Is provided with a sealing means (61) comprising a sealing member (69) mounted in an annular sealing groove (67a) formed on the outer periphery of the fuel inlet port member (58) and closely contacting the inner peripheral surface of the fuel inlet member (58). A fuel supply system for multi-cylinder engines. The fuel supply system for a multi-cylinder engine according to claim 1,
The seal holder (66) is provided with an annular channel portion (67) having a seal groove (67a) fitted to the outer peripheral surface of the valve seat member (3), and one end of the channel portion (67). An annular flange (68) that protrudes inwardly from the periphery and overlaps the end face of the valve seat member (3), and between these annular flange (68) and the end face of the valve seat member (3). A fuel supply device for a multi-cylinder engine, characterized in that an annular weld (70) for liquid-tightly connecting the two is formed. The fuel supply device for a multi-cylinder engine according to claim 1 or 2,
A fuel supply device for a multi-cylinder engine, characterized in that the fuel flow control valve (V2) has the same structure as the fuel injection valve (V1) except for its sealing means (61).

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