BR102014023292B1 - FUEL HEATING SYSTEM AND FUEL INJECTION GUTTER - Google Patents

Abstract

fuel heating system, and fuel injection rail. A fuel heating system heats fuel from a fuel supply source (7) and introduces the fuel to a fuel injection valve (10). The fuel heating system is attached around the internal combustion engine along with the fuel injection valve. The fuel heating system has: a heating body (30) having a heating chamber (300) therein, an inlet opening (33) through which fuel from the fuel supply source is introduced to the heating chamber (300); an outlet opening (34) through which the fuel within the heating chamber (300) is discharged to the fuel injection valve; and a heating device (60) having a heat generator (62). the heating device (60) is attached with the heating body (30) such that the heat generator (62) is located within the heating chamber (300). the inlet opening (33) is located in an upper portion of the heating chamber (300) in a vertical direction.

Description

TECHNICAL FIELD

[0001] The present description refers to a fuel heating system and a fuel injection chute having the same.

FUNDAMENTALS

[0002] Conventionally, a fuel supply system has been known as having a fuel injection valve that injects heated fuel into an internal combustion engine. For example, a fuel injection chute described in Patent Document 1 (Japanese Patent No. 4834728) supplies heated fuel into a heating chamber for the internal combustion engine to improve the fuel's ignitability. The internal combustion engine will be referred to as an engine hereafter.

SUMMARY

[0003] In general, when fuel alcohol such as ethanol or fuel mixed with alcohol and gasoline is used, the ignitability of the fuel may deteriorate under the condition that the concentration of alcohol is high and an ambient temperature is low. Properly starting the engine may not be possible. In order to avoid such a situation, by supplying heated fuel to the engine, the engine can be started regardless of the ambient temperature even if the fuel alcohol or blended fuel has a high concentration of alcohol.

[0004] When gasoline is used, the viscosity of the fuel increases at a low ambient temperature, and a fuel particle sprayed from the fuel injection valve enlarges in size. When the pulverized fuel particle enlarges in size, the fuel's ignitability deteriorates, and a fear of an abnormality such as a decrease in engine output and a deterioration in emission can generate. By supplying heated fuel to the engine, the pulverized fuel particle can be reduced in size, and engine output decrease and emission deterioration can be suppressed, even if the ambient temperature is low.

[0005] Patent Document 1 describes a fuel heating system having a heat generator that extends along an axis of a heating chamber formed into a cylindrical shape (see FIG. 20 of Patent Document 1) . In a state where the fuel heating system is attached with the engine, an inlet opening for introducing fuel into the heating chamber is formed in an upper wall surface which is one of the wall surfaces defining an upper side of the heating chamber in a vertical direction. The top wall surface is located above the heat generator in the vertical direction. The inlet opening faces the heat generator. Additionally, an outlet opening for discharging fuel from an interior of the heating chamber to the fuel injection valve is formed in a wall surface that faces the wall surface having the inlet opening. In other words, the outlet opening is formed in a lower wall surface which is located below the heat generator in the vertical direction and faces the upper wall surface located above the heat generator in the vertical direction. The inlet opening is located below a center of the heat generator in the vertical direction, and the outlet opening is located above the center of the heat generator in the vertical direction.

[0006] According to the fuel heating system in Patent Document 1, the fuel flowing into the heating chamber through the inlet opening is placed in contact with the heat generator. Then the fuel is heated by the heat generator and has its weight changed. Therefore, the heated fuel moves upward along the upper wall surface which is located above the heat generator in the vertical direction and is grouped at an upper end portion in the heating chamber. On the other hand, low temperature fuel moves downward along the bottom wall surface which is located below the heat generator in the vertical direction and is grouped in a lower end portion in the heating chamber. Therefore, the heat generator works with low heating efficiency, and there is a fear that low temperature fuel is guided to the fuel injection valve through the outlet opening that is provided in the lower wall surface located below the generator of heat in the vertical direction.

[0007] As fuel having high temperature is grouped in the upper end portion in the heating chamber, the fuel can be boiled in the upper end portion. When fuel is boiled, bubbles are generated in the fuel, and the heating efficiency of fuel heating due to the heat generator may deteriorate.

[0008] The present description addresses the above problems. Thus, it is an object of the present description to provide a fuel heating system and a fuel injection chute with which the heating efficiency of fuel heating is improved, and fuel having high temperature can be effectively introduced to a valve of fuel injection.

[0009] A fuel heating system heats fuel from a fuel supply source and introduces the fuel to a fuel injection valve that supplies fuel to an internal combustion engine. The fuel heating system is attached with the internal combustion engine or around the internal combustion engine along with the fuel injection valve. The fuel heating system has: a heating body having a heating chamber therein, an inlet opening through which fuel from the fuel supply source is introduced to the heating chamber; an outlet opening through which fuel within the heating chamber is discharged to the fuel injection valve; and a heating device having a heat generator. . .

[00010] The heating device is attached with the heating body such that the heat generator is located inside the heating chamber. The inlet opening is located in an upper portion of the heating chamber in a vertical direction.

[00011] According to the present description, the fuel heated by the heat generator inside the heating chamber has the weight changed, moved upwards to an upper portion of the heating chamber in the vertical direction, and grouped around the upper portion. As the inlet opening is located in the upper portion of the heating chamber in the vertical direction, fuel having high temperature and gathered in the upper portion of the heating chamber may be agitated due to the fuel flowing into the heating chamber from the inlet opening . Additionally, the fuel can be avoided from being boiled and having bubbles in the upper portion of the heating chamber by introducing low temperature fuel into the heating chamber from the inlet opening. Furthermore, by mixing a low temperature fuel flowing from the inlet opening in the heating chamber and the fuel having high temperature and pooled in the upper portion, the fuel from the inlet opening can be readily heated. Even if the fuel in the upper portion of the heating chamber is boiled, and bubbles are generated in the fuel, the bubbles can move outside the heating chamber. Therefore, the heating efficiency of heating fuel inside the heating chamber can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS

[00012] The above objectives and other objectives, features and advantages of the present description will be more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings: FIG. IA is a perspective diagram illustrating a fuel heating system and a fuel injection chute according to a first embodiment; FIG. 1B is a block diagram illustrating a control configuration of an electrical control unit in accordance with the first embodiment; Figure 2 is a perspective view illustrating the fuel heating system and fuel injection chute according to the first embodiment and which is viewed from a different direction as compared to FIG. 1A; Fig. 3 is a cross-sectional view illustrating the fuel heating system according to the first embodiment; Fig. 4 is a cross-sectional view taken along line IV-IV in Fig. 3; Fig. 5 is a cross-sectional view taken along a line V-V in Fig. 3 and illustrates the fuel heating system attached around an internal combustion engine, according to the first embodiment; Fig. 6 is an exploded perspective view of a heating body of the fuel heating system according to the first embodiment; Fig. 7 is a cross-sectional diagram illustrating the heating body of the fuel heating system according to the first embodiment; Fig. 8 is a cross-sectional view illustrating a fuel heating system according to a second embodiment; FIG. 9 is a cross-sectional view taken along line IX-IX in FIG 8; FIG. 10 is a cross-sectional view taken along line X-X in FIG 8 and illustrates the fuel heating system attached around an internal combustion engine, according to the second embodiment; FIG 11 is a cross-sectional view illustrating a fuel heating system in accordance with a third embodiment; FIG 12 is a cross-sectional view taken along line XII-XII in FIG. 11; and FIG. 13 is a cross-sectional view taken along line XIII-XIII in FIG. 11 and illustrates the fuel heating system attached around an internal combustion engine, according to the third embodiment.

DETAILED DESCRIPTION

[00013] Embodiments of the present description will be described hereinafter with reference to the drawings. In modalities, a part that corresponds with a subject described in a preceding modality may be designated with the same reference number, and redundant explanation for the part may be omitted. When a drawing includes components or parts that practically correspond to each other, only the single component or part will be designated with a reference number to avoid the drawings being complicated.

(First modality)

[00014] A fuel heating system and a fuel injection chute having the same according to a first embodiment will be described with reference to FIGS. 1 to 7.

[00015] As shown in FIG. 1A, a fuel injection chute 1 of the first modality is attached around an internal combustion engine 2 (referred to as an engine 2 hereinafter). Engine 2 is a four cylinder engine having four of cylinders 3. Each of cylinders 3 has a combustion chamber 4. Engine 2 is operated with alcohol fuel such as ethanol or mixed ethanol and gasoline fuel. The combustion chamber 4 is connected with an inlet port 5, and inlet air is introduced to the combustion chamber 4 through the inlet port 5. The inlet port 5 is provided in an inlet manifold 6.

[00016] The inlet port 5 has a fuel injection valve 10. That is, four of the fuel injection valves 10 are arranged. The fuel injection valve 10 is arranged such that an injection port 11 is open inside the inlet port 5. Fuel is injected from the injection port 11 to the intake port 5, and the injected fuel is introduced to the combustion chamber 4 together with inlet air. Fuel is burned in combustion chamber 4.

[00017] According to the present embodiment, the fuel injection chute 1 is attached with the intake manifold 6 around the engine 2 together with the fuel injection valves 10 and distributes fuel from a fuel tank 7 for fuel injection valves 10. Fuel tank 7 is a source of fuel supply.

[00018] The fuel injection chute 1 includes an injection chute portion 20 extending in one direction and four of the fuel heating systems 100.

[00019] As shown in FIGS. 1 and 2, the injection chute portion 20 has an upper member 21 and a lower member 22.

[00020] The upper member 21 and the lower member 22 are made of a metal plate having a predetermined thickness and formed through plastic deformation such as pressing. The upper member 21 and the lower member 22 are formed into a long-length shape. In other words, the upper member 21 and the lower member 22 extend in one direction (for example, a horizontal direction). A longitudinal length of the upper member 21 is generally the same as that of the lower member 22. A short length of the upper member 21 is generally the same as that of the lower member 22.

[00021] The upper member 21 has an undercut portion that is undercut from a first surface side to a second surface side opposite the first surface side. The lower member 22 also has an undercut portion that is undercut from a first surface side to a second surface side opposite the first surface side.

[00022] The lower member 22 is coupled with the upper member 21 such that a longitudinal direction and a short direction of the lower member 22 are parallel with a longitudinal direction and a short direction of the upper member 21, respectively. Additionally, the lower member 22 is coupled with the upper member 21 such that the recessed portion of the lower member 22 faces the recessed portion of the upper member 21. Appropriately, the recessed portion of the upper member 21 is the portion. undercut of the lower member 22 form a fuel passage 200, as shown in FIGS. 1 and 2.

[00023] As shown in FIGS. 1 and 2, the sputter portion 20 has protruding portions 23 which are arranged one after the other in the longitudinal direction. The protruding portions 23 are protruding in a direction perpendicular to the longitudinal direction of the injection chute portion 20. The number of the protruding portions 23 is four which is equal to the number of the fuel injection valves 10, and each of the valves fuel injection port 10 has a protruding portion 23.

[00024] The upper member 21 has a fuel inlet 24 at an end portion of the upper member 21 in the longitudinal direction, as shown in FIGS. 1 and 2. One surface and the other surface of the upper member 21 are communicated with each other through the fuel inlet 24. That is, the fuel inlet 24 passes through the upper member 21 in a thickness direction perpendicular to the longitudinal direction.

[00025] As shown in FIGS. 1 and 2, the fuel inlet 24 is connected with one end of an inlet tube 25. The other end of the inlet tube 25 is connected with a fuel supply passage 8 extending from the fuel tank 7, as shown in FIG. IA A fuel pump 9 is located between the fuel tank 7 and the inlet pipe 25. When the fuel pump 9 is operated, the fuel pump 9 draws fuel from the fuel tank 7 and discharges the fuel into the pipe. inlet 25 through fuel supply passage 8 Appropriately, fuel within fuel tank 7 flows to fuel passage 200.

[00026] Each of the fuel heating systems 100 has a heating body 30, an inlet opening 33, an outlet opening 34, and a heating device 60. According to the present embodiment, a fuel heating system fuel 100 is attached with each of the protruding portions 23 arranged one after the other in the longitudinal direction of the injection chute portion 20 at generally regular intervals, as shown in FIGS. 1 and 2. The number of fuel heating systems 100 is four, that is, a fuel heating system 100 is attached with a fuel injection valve 10.

[00027] The heating body 30 includes an upper member 40 and a lower member 50 as shown in FIGS. 3 to 6.

[00028] The upper member 40 and the lower member 50 are made of a metal plate having a specified thickness and formed through a plastic deformation such as pressing or deep drawing.

[00029] The upper member 40 has an upper recessed portion 41 recessed from a first surface side to a second surface side opposite the first surface side. The lower member 50 has a lower recessed portion 51 recessed from a first surface side to a second surface side opposite the first surface side.

[00030] The upper member 40 and the lower member 50 are coupled together such that the upper recessed portion 41 faces the lower recessed portion 51.0 upper member 40 and the lower member 50 form the heating body 30. As shown in FIGS. 3 and 5, the upper member 40 and the lower member 50 have a contact surface between them, and the contact surface has a tubular shape. In accordance with the present embodiment, the upper member 40 and the lower member 50 are coupled together by a method such as brazing. A heating chamber 300 is defined between the upper recessed portion 41 and the lower recessed portion 51 of the heating body 30.

[00031] The heating body 30 includes a first wall surface 301, a second wall surface 302, a third wall surface 303, and a fourth wall surface 304 which are flat wall surfaces defining the heating chamber 300 .

[00032] The first wall surface 301, the second wall surface 302, and the third wall surface 303 are included in the upper recessed portion 41. The fourth wall surface 304 is included in the lower recessed portion 51 and turns for the first wall surface 301.

[00033] As shown in FIG. 5, the second wall surface 302 is perpendicular to the first wall surface 301. In other words, the second wall surface 302 is angled relative to the first wall surface 301 at a right angle. Suitably, a corner portion 310 is provided between the first wall surface 301 and the second wall surface 302. The heating chamber 300 includes the corner portion 310.

[00034] Corner portion 310 includes third wall surface 303 connecting with first wall surface 301 and second wall surface 302.

[00035] As shown in FIG. 4, heating body 30 additionally has a fifth wall surface 305 which is a curved wall surface defining heating chamber 300. Fifth wall surface 305 is curved along a circular arc having a specified center point P in heating chamber 300. Fifth wall surface 305 is perpendicular to both first wall surface 301 and fourth wall surface 304.

[00036] The heating body 30 has a first cylinder part 31 and a second cylinder part 32.

[00037] The first cylinder part 31 is made of a material that is the same material as the upper member 40 and formed into a cylindrical shape. The first cylinder part 31 is located outside the heating chamber 300 and formed integrally with the upper member 40 such that one end of the first cylinder part 31 is connected with the upper member 40.

[00038] The inlet opening 33 is formed in the upper recessed portion 41 of the upper member 40 and is located in a position corresponding to the end of the first cylinder part 31. The inlet opening 33 is located in the first wall surface 301 as shown in FIGS. 3 and 5.

[00039] The second cylinder part 32 is made of a material that is the same material as the lower member 50 and formed into a cylindrical bottom shape. The second cylinder part 32 is located within the heating chamber 300 and formed integrally with the lower member 50 such that an end of the second cylinder part 32 opposite a bottom portion of the second cylinder part 32 is connected with the lower member 50. The second cylinder portion 32 is formed integrally with the lower member 50 by a method such as deep drawing.

[00040] The outlet opening 34 is formed in the bottom portion (i.e., an end side) of the second cylinder part 32, as shown in FIGS. 3 to 7. The end of the second cylinder part 32 opposite the bottom portion of the second cylinder part 32 is open at a surface which is opposite the lower recessed portion 51 of the lower member 50, as shown in FIGS. 6 and 7. The second cylinder part 32 will be referred to as a cylinder part.

[00041] As shown in FIGS. 4, 5, and 7, the outlet opening 34 is located on a side of the second cylinder part 32 adjacent the corner portion 310 with respect to an axis Ax2 of the second cylinder part 32. That is, the outlet opening 34 is positioned around corner portion 310 and third wall surface 303.

[00042] Inlet opening 33 is a specified distance away from outlet opening 34.

[00043] As shown in FIGS. 3 and 5, the upper member 40 of the heating body 30 is connected with a recessed portion 23 (i.e., the lower member 22) of the injection chute portion 20 such that the other end of the first cylinder part 31 is located. inside the fuel passage 200 of the injection chute portion 20. Suitably, the fuel in the fuel passage 200 flows in the heating chamber 300 through an opening at the other end of the first cylinder part 31, an interior of the first part of cylinder 31, and the inlet opening 33.0 heating body 30 (i.e. the upper member 40) and the injection chute portion 20 (i.e., the lower member 22) are connected together by a method such as brazing.

[00044] As shown in FIGS. 3 and 5, one end of the fuel injection valve 10 which is opposite the other end having the injection port 11 is connected with an interior of the second cylinder part 32. Suitably, the fuel in the heating chamber 300 is introduced. to the fuel injection valve 10 through the outlet opening 34.

[00045] As shown in FIG. 3, the heating device 60 has a body portion 61, a heat generator 62, and a retainer 63.

[00046] The body portion 61 is formed generally in a cylindrical shape. For example, the heat generator 62 is made of metal and formed into a rod shape, specifically a column shape that extends in one direction. Heat generator 62 is attached with body portion 61 coaxially with body portion 61. Heat generator 62 generates heat when electrical energy is supplied to heat generator 62. In the result, heat generator 62 it can heat fluid medium (e.g. steam or liquid) flowing around the heat generator 62.

[00047] Retainer 63, for example, is made of metal and generally formed into a cylindrical shape. Retainer 63 is attached with upper member 40 such that one end of retainer 63 is connected with an opening provided in upper member 40. Retainer 63 and upper member 40 are coupled together by a method such as brazing.

[00048] The body portion 61 is disposed on the retainer 63 at least partially and the heat generator 62 is located inside the heating chamber 300. That is, the heating device 60 is attached with the heating body 30 such that the heat generator 62 is located within the heating chamber 300. In the result, the heating device 60 can heat the fuel in the heating chamber 300 by the heat generator 62.

[00049] The specified center point P is located between the heat generator 62 and the outlet opening 34 as shown in FIG. 4. The heating device 60 is attached with the heating body 30 such that a geometric axis of the heat generator 62 is angled with respect to the first wall surface 301 and the fourth wall surface 304, as shown in FIG. 3. The retainer 63 retains the body portion 61 hermetically against gas.

[00050] According to the present embodiment, each of the four fuel heating systems 100 has the heating body 30 and the heating device 60. That is, the fuel injection chute 1 has four heating bodies 30 and four heater devices 60, and each of the four heater devices 60 has a body portion 61. As shown in FIGS. 1 and 2, a longitudinal direction of each of the four heating devices 60 is angled with respect to a virtual surface in which the longitudinal direction of the injection chute portion 20 and the protruding direction of the protruding portions 23 extend. That is, a geometric axis of the heating device 60 is angled with respect to the virtual surface. The heating devices 60 are attached to the heating bodies 30, respectively, such that the geometric axes of the body portion 61 are parallel to each other.

[00051] The fuel injection chute 1 of the present embodiment additionally has an attachment portion 90. The attachment portion 90 includes a body portion 91 and an attachment portion 92. The body portion 91, for example, is made of metal to have a long flat plate shape. Two of the attachment portions 92 are provided at two locations along a longitudinal direction of the body portion 91 as shown in FIG. two.

[00052] The body portion 91 is connected with the lower member 50 of the heating body 30. The attachment part 90 and the heating body 30 (i.e., the lower member 50) are connected together by such a method. like brazing. The fuel injection chute 1 is attached with the inlet manifold 6 in such a way that a fastening member such as a strap is inserted into a hole of the attachment portion 92 to secure the attachment portion 92 to the inlet manifold 6.

[00053] As shown in FIG. 5, the fuel heating system 100 (i.e., the fuel injection chute 1) of the present embodiment is attached with the inlet manifold 6 around the engine 2. The corner portion 310, the inlet opening 33, and the outlet opening 34 are located above the heating chamber 300 in the vertical direction. In this case, the heat generator 62 is located below the corner portion 310, the inlet opening 33, and the outlet opening 34 in the vertical direction. In other words, the corner portion 310, the inlet 33, and the outlet 34 are located above the heat generator 62 in the vertical direction in a state where the fuel heating system 100 (i.e., the fuel injection chute 1) is attached with inlet manifold 6.

[00054] The inlet opening 33 is located in an upper portion of the heating chamber 300 in the vertical direction in the state where the fuel heating system 100 (i.e., the fuel injection chute 1) is attached with the manifold inlet 6. More specifically, inlet opening 33 is formed in an upper wall surface (i.e., first wall surface 301) which is one of the wall surfaces defining an upper side of heating chamber 300 in the vertical direction.

[00055] Additionally, the third wall surface 303 is angled with respect to a horizontal surface perpendicular to the vertical direction. Appropriately, as shown in FIG. 5, an outer peripheral portion of the third wall surface 303 adjacent the outlet opening 34 is at the highest position of all parts on the third wall surface 303 in the vertical direction, in the state in which the fuel heating system 100 (i.e., that is, the fuel injection chute 1) is attached with the inlet manifold 6. In other words, the third wall surface 303 is inclined with respect to the horizontal surface such that the third wall surface 303 slopes towards the opening of exit 34.

[00056] As shown in FIG. IB, the air conditioning unit of the present modality additionally has an electrical control unit 12 (referred to as an ECU 12 hereinafter). The ECU 12 is a small computer and includes a CPU for calculating, a ROM and RAM that store data, and a part for input and output. The ECU 12 performs a process using a program in ROM to control devices in a vehicle based on signals from sensors arranged in the vehicle.

[00057] When engine 2 starts in a condition where a fuel alcohol concentration is greater than or equal to a predetermined value and an ambient temperature is less than or equal to a predetermined value, the ECU 12 performs a preheat operation to preheat fuel before operating fuel injection valve 10 to inject fuel. In this case, fuel from the fuel tank 7 must flow into the heating chamber 300 through the fuel passage 200 of the injection chute portion 20 and the inlet opening 33.

[00058] The ECU 12 supplies electrical energy to the heating device 60 to cause the heat generator 62 to generate heat for preheating. Suitably, the heat generator 62 within the heating chamber 300 heats fuel around the heat generator 62. The fuel heated by the heat generator 62 is changed in weight, and the heated fuel moves upwards in the vertical direction, in other words, it moves to a side adjacent to corner portion 310. The heated fuel is grouped around corner portion 310, in other words, around third wall surface 303. When fuel is in heating chamber 300 is sufficiently heated by the heat generator 62, the preheating operation is stopped.

[00059] After the preheat operation is stopped, the ECU 12 operates the fuel injection valve 10 to inject fuel. Suitably, heated fuel grouped around corner portion 310 in heating chamber 300 is introduced to fuel injection valve 10 through outlet 34 and injected from injection port 11 to inlet port. 5 and then is supplied to combustion chamber 4 of engine 2. As the fuel injected to inlet port 5 has high temperature, the fuel's ignitability improves. Thus, the engine 2 can be started under the condition that the alcohol concentration of the fuel is greater than or equal to the predetermined value and that the ambient temperature is less than or equal to the predetermined value.

[00060] After the engine 2 is started, the ECU 12 continuously supplies electrical energy to the heating device 60 to heat the fuel in the heating chamber 300 in the condition that the alcohol concentration of the fuel is greater than or equal to the predetermined value and that the ambient temperature is less than or equal to the predetermined value. Suitably, fuel heated by heat generator 62 is continuously injected from fuel injection valve 10.

[00061] As described above, according to the present embodiment, the heating body 30 has the heating chamber 300 therein. Inlet opening 33 introduces fuel from fuel tank 7 into heating chamber 300. Outlet opening 34 introduces fuel into heating chamber 300 to fuel injection valve 10.

[00062] The heating device 60 includes the heat generator 62 which generates heat. The heating device 60 is attached with the heating body 30 such that the heat generator 62 is located within the heating chamber 300. The heat generator 62 can heat the fuel within the heating chamber 300.

[00063] The inlet opening 33 is located above the heating chamber 300 in the vertical direction in the state where the fuel heating system 100 (i.e. the fuel injection chute 1) is attached with the inlet manifold 6 around the motor 2. Specifically, the inlet opening 33 is provided in the first wall surface 301 which is one of the wall surfaces defining the upper side of the heating chamber 300 in the vertical direction.

[00064] The fuel heated in the heating chamber 300 and heated by the heat generator 62 has the changed weight, moves to the upper portion of the heating chamber 300 in the vertical direction (i.e., around the corner portion 310), and is grouped around the corner portion 310. As the inlet opening 33 is provided in the first wall surface 301 which is one of the wall surfaces defining the upper portion of the heating chamber 300 in the vertical direction, the grouped heated fuel in the upper portion of the heating chamber 300 in the vertical direction (i.e. around the corner portion 310) may be agitated due to the fuel flowing into the heating chamber 300 from the inlet opening 33. As low temperature fuel flows into the heating chamber 300 from the inlet opening 33, the fuel can be avoided from being boiled and having bubbles in the upper portion of the heating chamber 300 in the vertical direction (i.e. around the portion of corner 310. Additionally, the low temperature fuel from the inlet opening 33 can be readily heated by mixing the low temperature fuel which flows into the heating chamber 300 from the inlet opening 33 and the fuel heated in the upper portion of the heating 300 in the vertical direction (ie, around corner portion 310). Furthermore, even if fuel is boiled and bubbles are generated in the fuel in the upper portion of the heating chamber 300 in the vertical direction (i.e., around the corner portion 310), the bubbles move out of the heating chamber 300, in in other words, they move to the fuel passage 200, through the inlet opening 33. Thus, the heating efficiency of the fuel heating in the heating chamber 300 can be improved. .

[00065] The heating body 30 includes the upper member 40 having the specified thickness and the lower member 50 having the specified thickness. The heating chamber 300 of the present embodiment is defined by the upper member 40 and the lower member 50, which have the specified thickness and are coupled together. When fuel is continuously injected from fuel injection valve 10, a pulse of fuel in heating chamber 300 can be reduced as upper member 40 and lower member 50 are elastically deformed. Suitably, a fuel injection from the fuel injection valve 10 can be stabilized. Additionally, as the upper member 40 and the lower member 50 are made of a material specified to have the specified thickness, the upper member 40 and the lower member 50 may be lighter in weight and have greater resistance to vibration.

[00066] As the upper member 40 and the lower member 50 are made of the material specified to have the specified thickness, the upper member 40 and the lower member 50 can be formed easily through a plastic deformation such as pressing or deep drawing even whether the upper recessed portion 41 and the lower recessed portion 51 have a complicated shape. Suitably, the manufacturing cost can be reduced compared to a case where the upper member 40 and the lower member 50 are formed through a method such as trimming.

[00067] The second cylinder part 32 is formed integrally with the heating body 30, and the fuel injection valve 10 is connected with the interior of the second cylinder part 32. Appropriately, the number of components and the manufacturing cost can be reduced compared to a case where an additional component is used to connect the fuel injection valve 10 to the heating body 30. Additionally, as the second cylinder part 32 is located inside the heating chamber 300, and the outlet opening 34 can be closed with the corner portion 310. Suitably, heated fuel around the corner portion 310 can be effectively introduced to the fuel injection valve 10 through the opening of outlet 34. In addition, the entire fuel heating system 100 including the second cylinder part 32 can be reduced in size.

[00068] The fuel injection chute 1 of the present embodiment has the injection chute portion 20 and the four fuel heating systems 100.

[00069] The injection chute portion 20 extends in one direction and has the fuel passage 200 connected with the inlet opening 33. The fuel from the fuel tank 7 flows through the fuel passage 200. The four systems fuel heaters 100 are arranged one after the other in the longitudinal direction of the jet chute portion 20 (i.e. along the jet chute portion 20) at regular intervals.

[00070] The fuel injection valve 10 is arranged on each of the four fuel heating systems 100, i.e. the number of the injection valves 10 is four.

[00071] According to the present embodiment, the four heating chambers 300 are arranged to correspond with the four of the cylinders 3, respectively. Therefore, the temperature of fuel supplied to combustion chambers 4 of cylinders 3 can be suppressed to vary among cylinders 3, and fuel from fuel tank 7 can be effectively heated and supplied to each of the injection valves of fuel 10.

[00072] The corner portion 310, the inlet opening 33, and the outlet opening 34 of the present embodiment are located above the heat generator 62 in the vertical direction in a state where the fuel heating system 100 (i.e. , the fuel injection chute 1) is attached with the inlet manifold 6 (ie around the engine 2).

[00073] When the fuel in the heating chamber 300 is heated by the heat generator 62, the heated fuel changes weight, moves to the side adjacent to the corner portion 310, and is grouped in the corner portion 310, as the corner portion 310 is located above heat generator 62 in the vertical direction. Furthermore, fuel heated around the corner portion 310 can be effectively introduced to the fuel injection valve 10 through the outlet opening 34, as the outlet opening 34 is located above the heat generator 62 in the direction. vertical.

[00074] The heating body 30 of the present embodiment has the third wall surface 303 connecting with both the first wall surface 301 and the second wall surface 302. Appropriately, the fuel is heated around the corner portion 310 can be effectively introduced to the fuel injection valve 10 through the outlet opening 34 as a distance between a wall surface (i.e., the third wall surface 303) formed in the corner portion 310 and the opening of outlet 34 is shortened (i.e., third wall surface 303 may be proximate to outlet opening 34).

[00075] The third wall surface 303 is sloped with respect to the horizontal surface such that the third wall surface 303 slopes towards the outlet opening 34. Appropriately, the fuel heated by the heat generator 62 has the changed weight and flows along the third wall surface 303 to a side adjacent the outlet opening 34. Therefore, heated fuel can be effectively introduced to the fuel injection valve 10 through the outlet opening 34.

[00076] The heating body 30 of the present embodiment additionally has the first cylinder part 31. Fuel that flows into the heating chamber 300 from the inlet opening 33 through the first cylinder part 31 flows along the geometric axis Axl of the first cylinder part 31 and impinges on fourth wall surface 304. Fuel which has impinged on fourth wall surface 304 flows to a side adjacent to heat generator 62 along fourth wall surface 304. Therefore, fuel is placed easily in contact with the heat generator 62, and the heating efficiency of fuel heating can be improved.

[00077] The heating body 30 of the present embodiment has the fifth wall surface 305 having a curved shape and defining the heating chamber 300. The fifth wall surface 305 is curved along the circular arc having the specified center point P defined in heating chamber 300. Suitably, fuel flowing in heating chamber 300 from inlet opening 33 through first cylinder part 31 flows along the axis Axl of the first cylinder part and impinges on the fourth wall surface 304. Fuel which has impinged on fourth wall surface 304 flows along fifth wall surface 305 having the curved shape and flows along heat generator 62 in a longitudinal direction of heat generator 62 while fuel is maintained to be in contact with the heat generator 62. That is, the fifth wall surface 305 guides the fuel along the heat generator 62 in the longitudinal direction. al. Therefore, the fuel can be in contact with the heat generator 62 for a longer time, and the heating efficiency of the fuel heating can be improved.

[00078] The fuel passage 200 is defined by the upper member 21 and the lower member 22 having the specified thickness and coupled together. Suitably, a fuel pulse in the fuel passage 200 can be reduced, and the processing cost of manufacturing the injection chute portion 20 can be reduced.

[00079] According to the present embodiment, the inlet opening 33 is spaced a specified distance from the outlet opening 34. Thus, the fuel flowing into the heating chamber 300 from the inlet opening 33 can be avoided from being introduced into outlet opening 34 without being heated by heat generator 62. Properly, lower temperature fuel can be avoided from being injected from fuel injection valve 10.

[00080] According to the present embodiment, the longitudinal direction of each of the four heating devices 60 is angled with respect to the virtual surface including the longitudinal direction of the injection chute portion 20 and the direction in which the protruding portions 23 are in protrusion. The four heating devices 60 are attached to the four heating bodies 30, respectively, such that the geometric axis of the body portion 61 are parallel to each other. Thus, the body portion 61 can be prevented from interfering with an adjacent part such as the heating body 30 when the body portion 61 is fitted to the retainer 63. Appropriately, the heating device 60 can be easily attached, and the working efficiency of attaching the heating device 60 can be improved.

(Second modality)

[00081] A fuel heating system of a second embodiment will be described with reference to FIGS. 8 to 10. An internal structure of the heating chamber 300 of the second mode is different from that of the first mode.

[00082] A guide part 70 is additionally arranged in the heating chamber 300 according to the second mode. The guide part 70 is made of a metal plate having a specified thickness and formed through a plastic deformation such as bending.

[00083] As shown in FIGS. 8 and 9, guide portion 70 includes a body portion 71, a shield portion 72, and an anchor portion 73.

[00084] The body portion 71 is formed with a generally rectangular plate shape as shown in FIG. 9. The shield portion 72 is formed with a generally triangular plate shape as shown in FIG. 10. The shield portion 72 is formed integrally with the body portion 71 such that one side of the shield portion 72 is connected with the body portion 71 and angled relative to the body portion 71 at a right angle. The fixed portion 73 is formed with a generally rectangular plate shape as shown in FIG. 9. Attachment portion 73 is formed integrally with shield portion 72 such that one side of attachment portion 73 is connected with the other side of shield portion 72 and angled with respect to shield portion 72 at a right angle. Appropriately, body portion 71 is angled with respect to a virtual surface including fixed portion 73.

[00085] The guide part 70 is located within the heating chamber 300, and the fixed portion 73 is fixed around the inlet opening 33 which is provided in the first wall surface 301 of the upper member 40, as shown in FIG. 8. Fixed portion 73 is connected with upper member 40 (i.e., first wall surface 301) by a method such as brazing. The guide portion 70 is arranged such that the geometric axis Axl of the first cylinder portion 31 passes through the body portion 71. The body portion 71 is inclined with respect to the first wall surface 301 such that a virtual surface including the portion of body 71 crosses at least a portion of the heat generator 62 as shown in FIG. 10. In the result, the fuel flowing in the heating chamber 300 from the inlet opening 33 through the first cylinder part 31 flows along the geometric axis Axl of the first cylinder part 31 and impinges on the body portion 71. Fuel that has impinged on body portion 71 flows along body portion 71 to a side adjacent to heat generator 62. Thus, body portion 71 can guide fuel, which has flown into heating chamber 300 from there. inlet opening 33, to the side adjacent to the heat generator 62. Suitably, the fuel can be in contact with the heat generator 62 for a longer time, and the heating efficiency of the fuel heating can be improved.

[00086] The shield portion 72 is located between the inlet opening 33 and the outlet opening 34. That is, at least a part of the guide part 70 is located between the inlet opening 33 and the outlet opening 34. Therefore, the shield portion 72 prevents the fuel, which has flown into the heating chamber 300 from the inlet opening 33, from flowing to a side adjacent to the outlet opening 34. heating 300 from the inlet opening 33 can of course be avoided from being introduced into the outlet opening 34 without being heated by the heat generator 62. Thus, low temperature fuel can certainly be avoided from being injected from the valve of fuel injection 10.

[00087] According to the present embodiment, the fuel flowing in the heating chamber 300 from the inlet opening 33 through the first cylinder part 31 flows along the geometric axis Axl of the first cylinder part 31 and colliding with the body portion 71. Fuel which has impinged on body portion 71 flows along body portion 71 to a side adjacent heat generator 62. Fuel flowing to side adjacent heat generator 62 along body portion 71 collides with the fifth wall surface 305 formed in a curved shape, flows along the fifth wall surface 305, and flows along the heat generator 62 in the longitudinal direction during contact with the heat generator 62. That is, the fifth wall surface 305 introduces the fuel guided by the guide portion 70 to flow along the heat generator 62 in the longitudinal direction. Therefore, the fuel can be in contact with the heat generator 62 even longer compared to a case that does not use a guide part, and the heating efficiency of the fuel heating can be further improved.

(Third modality)

[00088] A fuel heating system according to a third embodiment will be described with reference to FIGS. 11 to 13. A configuration of the guide part 70 of the third mode is different from that of the second mode.

[00089] According to the third embodiment, the guide part 70 additionally includes an orifice 74. The orifice 74 passes through the body portion 71 in a direction of thickness of the body portion 71.

[00090] As shown in FIGS. 11-13, the hole 74 is located around the axis Axl of the first cylinder part 31. The axis Axl of the first cylinder part 31 passes through a part of the body portion 71 away from the hole 74. In other words , the geometric axis Axl of the first cylinder part 31 does not pass through the hole 74. As shown in FIG. 12, when the inlet opening 33 is projected to the body portion 71 in an axial direction of the cylinder part 31 along which the geometric axis Axl extends, the projected image of the inlet opening 33 overlaps with a part of the orifice 74.

[00091] According to the above configuration, a considerable amount of the fuel flowing in the heating chamber 300 from the inlet opening 33 through the first cylinder 31 collides with the body portion 71 and flows along the body portion 71 to the side adjacent to the heat generator 62. Suitably, the heating efficiency of heating fuel due to the heat generator 62 can be improved. A portion of the fuel which flows in the heating chamber 300 from the inlet opening 33 through the first cylinder portion 31 flows from a first side of the shield portion 72 to a second side of the shield portion 72 which is opposite to the first side through hole 74. Therefore, the heated fuel grouped on the second side of the shield portion 72, in other words, around the corner portion 310, can be agitated due to the fuel from the inlet opening 33, and the Heating efficiency of heating fuel in heating chamber 300 can be improved. Additionally, by introducing low temperature fuel from inlet opening 33 to a side adjacent to corner portion 310 through hole 74 for mixing with heated fuel, fuel along corner portion 310 is prevented from be boiled and have bubbles, and fuel from the inlet opening 33 can be readily heated.

(Other modifications)

[00092] The inlet opening can be located anywhere in the heating chamber as long as the inlet opening is located on the upper side in the heating chamber in the vertical direction, in the state where the fuel heating system is attached with or around the internal combustion engine. The inlet opening may be included in another wall surface defining the heating chamber other than the wall surface (i.e., the first wall surface 301) defining the upper side of the heating chamber in the vertical direction.

[00093] The heating body can be provided through the integral formation of the upper limb and the lower limb. The heating body can be formed by a method such as trimming. The heating body can have any shape as long as the heating body includes the corner portion in the heating chamber.

[00094] The first cylinder part 31 and the cylinder part (i.e. the second cylinder part 32) can be omitted.

[00095] The fuel heating system (ie a fuel injection chute) of the above modalities is attached with the inlet manifold by connecting the attachment part to the lower member of the heating body. However, the attachment part can be connected with another part such as the upper member of the heating body. The fuel heating system can be attached directly with the internal combustion engine or around the internal combustion engine without the attachment part.

[00096] The body portion, the heat generator, and the retainer of the heating device can be formed in any shape. The retainer can be formed integrally with the heating body. The heating device may lack the body portion and retainer.

[00097] The injection chute portion can be provided through the integral formation of the upper limb and the lower limb. The gate chute portion can be formed through a method such as trimming other than pressing. Any member such as a tube member can configure the injection chute portion as long as the member has a fuel passage inside the member and extends in one direction. Components of the above modalities are connected by brazing. However, components can be connected through another method such as soldering.

[00098] The fuel injection chute of the above arrangements is attached with the inlet manifold such that the injection port of the fuel injection valve is exposed inside the inlet port. However, the injection port of the fuel injection valve may be exposed inside the combustion chamber of the internal combustion engine. That is, the fuel injection chute can be attached with a direct injection type internal combustion engine.

[00099] The number of heating bodies and the number of heating devices can be varied based on the number of fuel injection valves attached with the internal combustion engine. That is, the present description can be used for an internal combustion engine having variable number of cylinders. For example, the fuel heating system of the present description can be used for an internal combustion engine having a single cylinder. In this case, a heating body and a heating device may be needed, and the injection chute portion may not be needed.

[000100] The present description can be used for an internal combustion engine operated with gasoline, not just alcohol fuel such as ethanol or mixed fuel alcohol and gasoline. In this case, even if the ambient temperature is low, the fuel viscosity decreases by heating the fuel using the heating device, and an injected fuel particle can be reduced in size. Therefore, the ignitability of the fuel in the combustion chamber can be improved.

[000101] Such changes and modifications are to be understood to be within the scope of the present description as defined by the appended claims.

Claims (8)

1. Fuel heating system (100) that heats fuel from a fuel supply source (7) and introduces fuel to a fuel injection valve (10) that supplies fuel to an internal combustion engine (2), the fuel heating system being attached to the internal combustion engine (2) or around the internal combustion engine together with the fuel injection valve (10), the fuel heating system characterized in that comprising: a heating body (30) having a heating chamber (300) therein, an inlet opening (33) through which fuel from the fuel supply source is introduced to the heating chamber (300 ); an outlet opening (34) through which fuel within the heating chamber (300) is discharged to the fuel injection valve (10); a heating device (60) having a heat generator (62) which generates heat, the heating device (60) being attached to the heating body (30) such that the heat generator (62) is located within the heat chamber. heating (300) to heat the fuel inside the heating chamber (300); and a cylinder part (32) located within the heating chamber (300), the cylinder part (32) having the outlet opening (34) at one end, the other end of the cylinder part (32) being connected to the heating body (30), the fuel injection valve (10) being connectable to the cylinder part (32) so that a part of the fuel injection valve (10) is located within one end to the other end of the part. of cylinder (32) the cylinder part is formed so that a fuel injection valve part (10) is located inside the heating body (30), wherein the inlet opening (33) is located in a upper portion of the heating chamber (300) in a vertical direction, and from one end to the other end of the cylinder part (32) is located inside the heating body (30). 2. Fuel heating system (100) according to claim 1, characterized in that the other end of the cylinder part (32) is connected with an inner wall of the heating body (30) so as not to protrude from an outer wall of the heating body (30). 3. Fuel heating system (100) according to claim 1 or 2, characterized in that the cylinder part (32) is made of the same material as the heating body (30) and is integrally formed as the heating body (30). 4. Fuel heating system (100) according to any one of claims 1 to 3, characterized in that the inlet opening (33) is formed in the heating body (30), a shaft of the inlet opening ( 33) and an axis of the outlet opening (34) are spaced apart, the axis of the inlet opening (33) does not intersect an axis of the heat generator (62) and is not parallel with the axis of the heat generator ( 62), and the axis of the outlet opening (34) does not intersect the axis of the heat generator (62) and is not parallel with the axis of the heat generator (62). 5. Fuel heating system (100) according to any one of claims 1 to 4, characterized in that the inlet opening (33) is formed in a wall surface (301) which is one of the wall surfaces which define the upper portion of the heating chamber (300) in the vertical direction. 6. Fuel heating system (100) according to any one of claims 1 to 5, characterized in that the heating body (30) includes: an upper member (40) made of metal having a specified thickness and including an upper recessed portion (41); and a lower member (50) made of metal having a specified thickness and including a lower recessed portion (51) wherein the upper member (40) is coupled to the lower member (50), and the heating chamber (300) is defined between the upper recessed portion (41) and the lower recessed portion (51). 7. Fuel injection chute (1), characterized in that it comprises: a plurality of fuel heating systems (100) as defined in any one of claims 1 to 6; and an injection chute portion (20) extending in one direction and having a fuel passage (200) connected with the inlet opening (33), fuel from the fuel supply source (7) flowing through. of the fuel passage (200), wherein in the plurality of fuel heating systems, the systems are arranged one after the other along the injection chute portion (20), and the fuel injection valve (10) is disposed in each of the plurality of fuel heating systems (100). 8. Fuel injection chute (1) according to claim 7, characterized in that the heating body is provided outside the chute portion (20).

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