JP5039411B2 - Fuel supply device - Google Patents

Description

  The present invention relates to an improvement of a fuel supply device.

As a conventional fuel supply device, one in which a filter case and a pressure regulator are integrally formed is known (for example, see Patent Document 1).
JP-A-8-74710

FIG. 1 of Patent Document 1 will be described below.
In the fuel filter, a filter insert body 6 is disposed inside a casing 1 provided with an inlet 2, an outlet 3 and a reflux port 5, and a pressure regulator 4 is incorporated on the inside of the casing 1 on the reflux port 5 side. . In the filter insert body 6, end caps 7, 7 provided at both ends are fitted into the casing 1 and supported by a support pipe 8.

  In Patent Document 1, the pressure regulator 4 is arranged inside the cylindrical filter insert body 6, and fuel is passed from the outside to the inside of the filter insert body 6 to be filtered, so that the surface area of the filter insert body 6 is secured. Then, the casing 1 becomes large. In addition, since the filter insert body 6 is provided with a support tube 8 and an end cap 7 that are a framework, the number of parts is large, resulting in an increase in cost.

  In addition, the pressure regulator 4 is limited in space in the casing 1 by the filter insert body 6 and the support tube 8 and has a low degree of freedom in layout. Further, when the pressure regulator 4 is disposed in the vicinity of the reflux port 5, the installation location of the reflux port 5 is limited.

  An object of the present invention is to provide a fuel supply device provided with a fuel filter that is compact and has a small number of parts and that can further increase the layout flexibility of a pressure regulator and a fuel inlet.

According to the first aspect of the present invention, a fuel filter is disposed outside the fuel tank, the outside of the fuel filter is covered with a fuel filter case, and a pressure regulator for adjusting the pressure in the fuel filter is integrated with the fuel filter case. The fuel filter is formed by a bag-like filter body and a fuel passage that communicates with the inside of the filter , in the fuel supply device in which the fuel that has passed through the pressure regulator is returned to the fuel tank . The bag-shaped filter body is stored in a cylindrical fuel filter case with the fuel passage inside, and the bag enters the inside of the rounded filter body. After passing through the filter body, the fuel escapes from the fuel passage. It is characterized by being filtered by .

  As an effect, since the fuel filter has a bag shape, the fuel filter can be stored in a small size in the filter case, and the fuel filter case becomes compact. In addition, since the fuel filter swells when the fuel is passed through the bag-like fuel filter from the inside to the outside and the shape is stabilized, a frame member is not particularly required for the fuel filter. Therefore, the number of parts of the fuel filter is reduced.

Furthermore, since the shape of the bag-like fuel filter in the case can be easily changed, the degree of freedom in layout of the fuel return port disposed in the vicinity of the pressure regulator and the pressure regulator is increased.
In the present invention, by storing the element body in the filter case that is rounded, the element body can be stored in a compact manner in the filter case, the filter case can be reduced in size, and the filter can be reduced in size.
The fuel passage is located inside the rounded portion of the filter body, and the fuel enters the inside of the rounded filter body, passes through the filter body, and is filtered by exiting the fuel passage. A projecting portion cannot be formed on the outside, and the filter case can be reduced in size, the space in the filter case can be effectively used, and the area of the filter body can be increased.

The invention according to claim 2 is characterized in that the fuel filter is disposed downstream of the fuel pump and the pressure regulator is disposed downstream of the fuel filter.
As an operation, the fuel that has passed through the fuel filter is returned to the fuel tank through the pressure regulator in a state where dust is removed. Therefore, for example, when another fuel primary filter is provided in the fuel pump, the amount of dust filtered into the fuel primary filter is reduced.

The invention according to claim 3 is characterized in that the fuel return pipe extends from the pressure regulator to the upper fuel tank.
As an effect, the air accumulated in the fuel filter easily escapes from the fuel return pipe to the upper fuel tank via the pressure regulator.

The invention according to claim 4 is characterized in that the length and the outer diameter of each of the fuel supply pipe for flowing fuel from the fuel tank to the fuel filter and the fuel return pipe are different.
As an operation, since the length and the outer diameter of the fuel supply pipe and the fuel return pipe are different, the fuel supply pipe and the fuel return pipe can be easily distinguished.

  The invention according to claim 5 is characterized in that the filter case includes a case body and a case cover, and the fuel inlet and the fuel return port are arranged offset from the central axis of the case cover.

  As an effect, by offsetting the fuel intake port and the fuel return port from the center axis of the case cover, for example, when the pressure regulator is arranged in the vicinity of the fuel return port, the layout degree of the pressure regulator is increased, and the pressure is increased. The degree of freedom of the shape of the regulator is increased, and an arrangement for making the filter case compact is possible.

The invention according to claim 6 is characterized in that the filter case is provided with a stepped portion protruding radially outward, and the lower end of the pressure regulator is supported by the stepped portion.
As an effect, since the pressure regulator is supported by the simple shape of the filter case, the cost of the filter case can be reduced.
According to a seventh aspect of the present invention, the pressure regulator is formed in a bottomed cylindrical resin case fitted into a cylindrical portion integrally formed on the lower surface of the case cover, and is opened at the bottom of the regulator case. A spherical steel valve body that opens and closes the through hole and a compression coil spring that urges the valve body to close the through hole. The through hole leads to the filter element side, and the opening of the regulator case is The fuel return port leads to the inside of the fuel return port.

In the invention according to claim 1, the fuel filter is formed of a bag-like filter body and a fuel passage communicating with the inside of the filter, and the bag-like filter body with the fuel passage inside in a cylindrical fuel filter case. Since the fuel enters the inside of the rounded filter body, passes through the filter body and then passes through the fuel passage, it is filtered so that the fuel is returned to the fuel filter in the fuel filter case. The layout flexibility of the opening and the pressure regulator can be increased, the filter case can be made compact, the number of parts of the fuel filter can be reduced, and the cost can be reduced.
In particular, in the present invention, the element body can be housed in the filter case in a compact manner by accommodating the element body in a rounded filter case, the filter case can be reduced in size, and the filter can be reduced in size. .
The fuel passage is located inside the rounded portion of the filter body, and the fuel enters the inside of the rounded filter body, passes through the filter body, and is filtered by exiting the fuel passage. A projecting portion cannot be formed on the outside, and the filter case can be reduced in size, the space in the filter case can be effectively used, and the area of the filter body can be increased.

  In the invention according to claim 2, since the fuel filter is arranged downstream of the fuel pump and the pressure regulator is arranged downstream of the fuel filter, the fuel that has passed through the fuel filter enters the fuel tank via the pressure regulator. For example, when another fuel primary filter is provided in the fuel pump, the replacement cycle of the fuel primary filter can be lengthened, and the maintenance frequency of the fuel primary filter can be reduced.

  In the invention according to claim 3, since the fuel return pipe extends from the pressure regulator to the upper fuel tank, the air accumulated in the fuel filter easily flows to the upper fuel tank, and the fuel supply in the fuel passage is smoothly performed. Can be done.

  In the invention according to claim 4, since the length and the outer diameter of the fuel supply pipe for flowing fuel from the fuel tank to the fuel filter and the fuel return pipe are set to be different from each other, the fuel supply pipe, the fuel return pipe, When connecting to the fuel filter, incorrect assembly can be prevented.

  In the invention according to claim 5, the filter case is constituted by the case main body and the case cover, and the fuel intake port and the fuel return port are arranged offset from the central axis of the case cover. When arranged near the fuel return port, the degree of freedom in the layout of the pressure regulator and the shape of the pressure regulator can be increased, and the filter case can be made compact.

In the invention according to claim 6, the filter case is provided with a stepped portion protruding radially outward, and the lower end of the pressure regulator is supported by the stepped portion, so that the support structure of the pressure regulator is simplified. The cost of the fuel filter case, and thus the fuel filter, can be suppressed.
In the invention according to claim 7, the pressure regulator is opened at the bottom of the regulator case made of resin with a bottomed cylindrical shape fitted to a cylindrical portion integrally formed on the lower surface of the case cover, and the regulator case. A spherical steel valve body that opens and closes the through hole and a compression coil spring that urges the valve body to close the through hole. The through hole leads to the filter element side, and the opening of the regulator case is , It led to the fuel return port.

The best mode for carrying out the present invention will be described below with reference to the accompanying drawings. The drawings are viewed in the direction of the reference numerals.
FIG. 1 is a side view of a vehicle employing a fuel filter structure according to the present invention. In the vehicle 10, an engine 12 is disposed at the center of a body frame 11, and a front fork 13 can be steered at the front end of the body frame 11. A motorcycle that is supported and has a rear fork 14 supported at the rear lower portion of the vehicle body frame 11 so as to be able to swing up and down. The main fuel is ethanol, gasoline, or a mixed oil of gasoline and ethanol. Only when the temperature is low and the engine startability is not good, gasoline or a mixed oil of gasoline and ethanol (however, the mixture ratio of gasoline is higher than that of the main fuel) is used as an auxiliary fuel.

  The vehicle body frame 11 includes a head pipe 21 provided at the front end, a main frame 22 extending rearward from the head pipe 21, a center frame 23 extending downward from an intermediate portion of the main frame 22, a rear portion of the main frame 22, and a center frame. 23 is a skeleton member made up of a plurality of press-molded parts, each of which includes a sub-frame 24 connected to each of the lower portions of 23 and a down frame 26 extending obliquely downward and rearward from the head pipe 21.

The head pipe 21 is a portion to which the front fork 13 is rotatably attached. The front fork 13 has a bar handle 31 at the top and a front wheel 32 at the bottom.
The main frame 22 is a portion where a main fuel tank 33 that stores main fuel is straddled across the front, and a seat 34 is attached to the rear.

  The center frame 23 is a portion that supports the engine 12 together with the down frame 26, and a pivot shaft 36 provided on the center frame 23 serves as a swing shaft of the rear fork 14. A rear wheel 35 is attached to the rear end of the rear fork 14.

A rear cushion unit 37 is passed and attached to the rear portion of the rear fork 14 and the rear portion of the main frame 22.
The down frame 26 is a part that supports the engine 12 via a bracket 38.

  The engine 12 has a transmission 41 integrally provided at a rear portion thereof, a cylinder head 44 is provided at a cylinder portion 43 that extends upward, and an intake device 46 is connected to a rear portion of the cylinder head 44. An exhaust device 47 is connected to the front portion of 44.

  The intake device 46 includes an intake pipe 51 having one end connected to the cylinder head 44, a throttle body 52 having one end connected to the other end of the intake pipe 51, and a connecting tube 53 connected to the other end of the throttle body 52. And an air cleaner 54 connected to each other.

  The exhaust device 47 includes an exhaust pipe 56 having one end connected to the front portion of the cylinder head 44 and extending downward and rearward from the front of the engine 12, and a muffler 57 connected to the other end of the exhaust pipe 56 and extending rearward. Become.

  In the figure, 61 is a front cowl, 62 is a headlamp, 63 is a front fender, 64 is a side cover that covers the side of the air cleaner 54, 66 is a rear side cover, 67 is a rear fender, 68 is a tail lamp, 71 is a main stand, 72 is The output shaft of the transmission 41, 73 is a drive sprocket attached to the output shaft 72, 74 is a driven sprocket attached integrally to the rear wheel 35, and 76 is a chain hung between the drive sprocket 73 and the driven sprocket 74, 77 is a chain cover.

  FIG. 2 is a side view of the main part of the fuel supply apparatus according to the present invention. Main fuel (hereinafter simply referred to as “fuel”) is filtered into a fuel pump 92 attached to the bottom 91 of the main fuel tank 33. A secondary filter 143 for filtering fuel is connected to the fuel pump 92 via a fuel supply pipe 142, and one end of the fuel supply pipe 144 is connected to the secondary filter 143 to supply fuel. A pipe 144 extends upward and the other end is connected to a fuel injection valve 94 provided in the upper throttle body 52.

  The secondary filter 143 is disposed on the downstream side of the primary filter 143 provided in the fuel pump 92, and the eyes of the secondary filter 143 are finer than the eyes of the primary filter 143. In this figure, the fuel piping from the secondary filter 143 to the main fuel tank 33 is omitted, but will be described with reference to FIG.

  FIG. 3 is a perspective view of a main part of the fuel supply apparatus according to the present invention. The secondary filter 143 is arranged on the outer side of the center frame 23 and attached to the center frame 23 with a bracket 146. A fuel return pipe 135 extends upward and is connected to the main fuel tank 33.

  The fuel return pipe 135 is made of a rubber hose, and has a shorter length and a larger outer diameter than the resin fuel supply pipe 142. Therefore, the fuel return pipe 135 can be easily distinguished from the fuel supply pipe 142, and the fuel supply pipe 142, the fuel return pipe 135, Can be prevented from being erroneously assembled when assembled to the secondary filter 141.

  The structure from the main fuel tank 33 to the fuel injection valve 94 described above, that is, the main fuel tank 33, the primary filter 141 (see FIG. 2), the fuel pump 92, the fuel supply pipe 142, the secondary filter 143, the fuel return The pipe 135, the fuel supply pipe 144, the throttle body 52, and the fuel injection valve 94 are components that constitute the fuel supply apparatus 150.

As described above, by arranging the secondary filter 143 on the outer side of the center frame 23, maintenance such as replacement of the secondary filter 143 can be easily performed. Further, the capacity of the secondary filter 143 can be increased, and the fuel pulsation can be more easily attenuated.

  FIG. 4 is a cross-sectional view of the fuel pump according to the present invention. The fuel pump 92 is attached to the lower case 151 made of resin attached to the main fuel tank 33 (see FIG. 2) and to the upper portion of the lower case 151. The upper case 152 is made of resin, and the drive unit 153 is disposed inside the upper case 151 and the lower case 152.

  The lower case 151 includes a flange portion 155 for attaching to the main fuel tank 33, a fuel passage 156 for flowing fuel sent by the drive portion 153, and a discharge port 157 connected to the fuel passage 156. 141 is a portion that accommodates 141.

The upper case 152 includes a plurality of suction ports 161 for sucking fuel.
The drive unit 153 includes a motor unit and a pump unit driven by the motor unit.
That is, the primary filter 141 is disposed on the upstream side of the drive unit 153 of the fuel pump 92.

  As indicated by an arrow in the figure, the fuel is sucked from the suction port 161 of the upper case 152, passes through the primary filter 141, and then rises in the drive unit 153, passes through the fuel passage 156, and is discharged from the discharge port. The flow from 157 to the outside, that is, the fuel supply pipe 142 shown in FIG. 2, reaches the secondary filter 143 shown in FIG.

5A and 5B are explanatory views of the secondary filter according to the present invention, in which FIG. 5A is a perspective view and FIG. 5B is an exploded perspective view.
In (a), the secondary filter 143 is made of a resin-made cylindrical case 171, a fuel suction port 171 a for sucking fuel, a fuel discharge port 171 b for discharging fuel, and the main fuel tank 33 (FIG. 3). And a fuel return port 171c for returning to the reference).

  In (b), the secondary filter 143 includes a case body 173 including a case body 173 and a case cover 174 that closes the opening of the case body 173, and a filter element 176 housed in the case 171. The fuel discharge port 171b is integrally formed with the case cover 174, and the fuel intake port 171a and the fuel return port 171c are integrally formed with the case cover 174.

The case main body 173 includes a small-diameter cylindrical portion 173A formed in the lower portion and a large-diameter cylindrical portion 173B formed in the upper portion of the small-diameter cylindrical portion 173A, and a pressure regulator 186 described later is provided inside the large-diameter cylindrical portion 173B. Has been placed.
The case cover 174 is integrally formed with an internal passage 171d communicating with the fuel suction port 171a.

  The filter element 176 includes a bag-shaped filter body 181 made of nonwoven fabric, and a connection port 182 in which a fuel passage 182a communicating with the inside of the filter body 181 is formed and connected to the internal passage 171d of the case cover 174. The connection port 182 is attached to the center of the width of the filter body 181.

6A and 6B are explanatory views of the filter element according to the present invention. FIG. 6A is a sectional view taken along line 6-6 in FIG. 5, and FIG. 6B shows a state when the filter main body 181 is stored. It is a perspective view.
In (a), the filter main body 181 of the filter element 176 is formed by superposing a resin (PP (polypropylene)) mesh 181B on a three-layered resin (PP (polypropylene)) non-woven fabric 181A so that the non-woven fabric 181A is on the inside. The bag is formed in such a manner that it is folded in half and the side edges are welded. The bag is integrally formed with the connection port 182, and is disposed inside the filter body 181. The outer flange 182b penetrates the filter body 181. At the same time, it is attached to the end of the connection port 182 so as to be sandwiched between the inner flange 182c which is bonded to the outer flange 182b by ultrasonic welding or adhesive or by fitting.

  (B) shows a state in which the element body 181 is rounded with the connection port 182 inside when the filter element 176 is housed in the case 171 (see FIG. 5). Depending on the size of the element body 181, the element body 181 may be wound once or twice and stored in the case 171.

  In this way, the element body 181 can be housed in the case 171 in a compact manner by rolling or winding the element body 181 and storing it in the case 171, and the case 171 can be reduced in size. That is, the secondary filter 143 can be downsized.

The connection port 182 is located on the inner wall 181a of the rounded or wound portion of the filter body 181 and extends outward, that is, toward the opening of the tubular filter body 181.
Therefore, a protruding portion cannot be formed on the outer wall 181b of the rounded or wound portion of the filter main body 181, and the case 171 can be reduced in size, and the space in the case 171 can be effectively used. The area of the filter body 181 can be increased.

  FIG. 7 is a cross-sectional view of the secondary filter according to the present invention. The secondary filter 143 returns the fuel to the main fuel tank 33 on the lower surface of the case cover 174 when the internal fuel pressure exceeds a predetermined value. A pressure regulator 186 for adjusting the fuel pressure inside the secondary filter 143 is integrally provided, and a check valve 188 is disposed in the fuel discharge port 171b of the case body 173.

The pressure regulator 186 has a bottomed cylindrical resin case 191 fitted into a cylindrical portion 174a formed integrally with the lower surface of the case cover 174, and a through hole opened in the bottom of the regulator case 191. A spherical steel valve body 192 that opens and closes 191a and a compression coil spring 193 that biases the valve body 192 so as to close the through hole 191a. The through hole 191a leads to the filter element 176 side, and a regulator case An opening 191b of 191 communicates with the fuel return port 171c.
The regulator case 191 has a lower end surface 191A supported by a step portion 173C that connects the small diameter cylindrical portion 173B and the large diameter cylindrical portion 173B of the case main body 173.

  Here, 174b is an annular fitting portion that is integrally formed on the lower surface of the case cover 174 and fitted into the upper portion of the case body 173, and 195 is an O-ring that seals between the tubular portion 174a and the regulator case 191. It is.

  As described above, the pressure regulator 186 is disposed on the downstream side of the filter main body 181, so that the fuel filtered by the filter main body 181 passes through the pressure regulator 186 and is returned to the main fuel tank 33 (see FIG. 3). When the fuel in the main fuel tank 33 passes through the primary filter 141 (see FIG. 2) again, dust is reduced and the primary filter 141 is less likely to be clogged. That is, the replacement cycle of the primary filter 141 becomes longer, and the maintainability can be improved.

  Further, since the pressure regulator 186 is integrally formed with the case 171 of the secondary filter 143, an increase in the number of parts can be suppressed, and the cost can be reduced.

  Further, the lower end surface 191A of the regulator case 191 is supported by the step portion 173C of the case body 173 so that the case cover 174 is attached to the case body 173 after the regulator case 191 is fitted to the cylindrical portion 174a of the case cover 174. Thus, the regulator case 191 can be sandwiched between the step portion 173C and the case cover 174 and fixed to the case 171, and the structure for attaching the pressure regulator 186 to the case 171 can be simplified.

  The check valve 188 includes a valve case 196, a valve body 197 disposed in the valve case 196 so as to be movable up and down, and a spring that presses the hemispherical head portion 197a of the valve body 197 against the tapered valve seat 196a. In the figure, the valve body 197 closes the tapered valve seat 196a.

  The fuel in the case 171 flows to the outside (the fuel injection valve 94 (see FIG. 3)) from the secondary filter 143 through the fuel discharge port 171b by pushing down the valve body 197 against the elastic force of the spring 198. On the contrary, the reverse flow of fuel from the fuel injection valve 94 side into the secondary filter 143 is prevented because the valve body 197 rises and the head portion 197a hits the valve seat 196a to block the fuel passage. The

  While the engine is operating, the fuel pump is operated, and the fuel flows to the fuel injection valve 94 (see FIG. 2) so as to push down the valve body 197 against the elastic force of the spring 198 by the pressure from the fuel pump.

  Since the fuel pump is also stopped after the engine is stopped, the valve element 197 is pushed up by the spring 198 and hits the valve seat 196a to close the fuel passage. Therefore, the fuel passage from the fuel discharge port 171b to the fuel injection valve 94 is kept at a high pressure.

  It is desirable to keep the internal pressure of the fuel line high in order to improve the function of the fuel line immediately after the fuel pump is started next time after the fuel pump stops, but even if the internal pressure of the fuel line is increased, the pressure regulator Since a small amount of fuel leaks from 186 to the discharge side and the internal pressure gradually decreases, a check valve 188 is provided on the discharge side of the pressure regulator 186.

  2 and 7, the secondary filter 143 is disposed on the downstream side of the fuel pump 92, and the pressure regulator 186 is disposed on the downstream side of the filter main body 181 of the secondary filter 143, so that the filter has passed through the filter main body 181. The fuel is returned to the main fuel tank 33 (see FIG. 2) via the pressure regulator 186. For example, when the primary filter 141 which is another fuel primary filter is provided in the fuel pump 92, The replacement cycle of the primary filter 141 can be lengthened, and the maintenance frequency of the primary filter 141 can be reduced.

  3 and 7, since the fuel return pipe 135 extends from the pressure regulator 186 to the upper main fuel tank 33, the air accumulated in the secondary filter 143 can easily flow to the upper main fuel tank 33. The fuel supply in the fuel passage can be performed smoothly.

  Further, the case 171 is composed of a case main body 173 and a case cover 174, and the fuel intake port 171a and the fuel return port 171c are offset from the central axis 200 of the case cover 174. When arranged in the vicinity of the fuel return port 171c, the degree of freedom in layout of the pressure regulator 186 and the degree of freedom in the shape of the pressure regulator 186 can be increased, and the case 171 can be made compact.

  Further, the case 171 is provided with a stepped portion 173C protruding outward in the radial direction, and the lower end of the pressure regulator 186, that is, the lower end surface 191A of the regulator case 191 is supported by the stepped portion 173C. The support structure can be simplified, and the cost increase of the case 171 and thus the secondary filter 143 can be suppressed.

8A and 8B are cross-sectional views of the secondary filter according to the present invention.
(A) is a state in which fuel is not sent into the filter main body 181 of the secondary filter 143, and the bag-shaped filter main body 181 is in a curled and deflated state.
In the figure, 173a is an inner surface of the case main body 173, and a plurality of 173b are convex portions protruding inward from the inner surface 173a.

  (B) shows a state in which fuel is sent from the connection port 182 of the secondary filter 143 into the filter main body 181. The filter body 181 swells because the internal fuel pressure increases, and the fuel gradually flows from the connection port 182 to the end as shown by the arrow and flows out from the inside through the filter body 181. At this time, a plurality of gaps 201 are formed between the swelled filter body 181 and the inner surface 173a by the plurality of convex portions 173b, and fuel flows into these gaps 201, and further, fuel flows through the gaps 201. There is no stagnation of fuel because it flows to other places. Therefore, the fuel filtration efficiency can be improved.

  As shown in FIGS. 2, 7, and 8, the secondary filter 143 as a fuel filter is disposed outside the fuel tank 33, and the outer side of the secondary filter 143 is a case 171 as a fuel filter case. A pressure regulator 186 is integrally formed in the case 171 to adjust the pressure in the secondary filter 143, and the fuel that has passed through the pressure regulator 186 is returned to the fuel tank 33. Since the secondary filter 143 has a bag shape and fuel is filtered by passing from the inside to the outside of the filter body 181, the filter body 181 can be accommodated in the case 171 in a small size. Can be made compact.

Further, since the filter body 181 swells and stabilizes its shape when fuel is passed through the bag-like filter body 181 from the inside to the outside, a special skeleton member is not necessary for the filter body 181. Therefore, the number of parts of the filter main body 181 can be reduced.
Further, since the shape of the bag-shaped filter body 181 in the case 171 can be easily changed, the degree of freedom in layout of the pressure regulator 186 and the fuel return port 171c can be increased.

  In the present embodiment, as shown in FIG. 7, the pressure regulator 186 is integrally provided on the case cover 174 of the case 171, but the present invention is not limited thereto, and the pressure regulator 186 may be provided on the case body 173. .

  The fuel supply device of the present invention is suitable for a motorcycle.

1 is a side view of a vehicle provided with a fuel supply device according to the present invention. It is a principal part side view which shows the fuel supply apparatus which concerns on this invention. It is a principal part perspective view which shows the fuel supply apparatus which concerns on this invention. It is sectional drawing of the fuel pump which concerns on this invention. It is explanatory drawing of the secondary filter which concerns on this invention. It is explanatory drawing of the filter element which concerns on this invention. It is sectional drawing of the secondary filter which concerns on this invention. It is a cross-sectional view of the secondary filter according to the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Vehicle, 33 ... Fuel tank (main fuel tank), 92 ... Fuel pump, 135 ... Fuel return pipe, 142 ... Fuel supply pipe, 143 ... Fuel filter (secondary filter), 143A ... Fuel filter case (case), DESCRIPTION OF SYMBOLS 150 ... Fuel supply apparatus, 171 ... Fuel filter case (case), 171a ... Fuel inlet, 171c ... Fuel return port, 173 ... Case main body, 173C ... Step part, 174 ... Case cover, 174a ... Cylindrical part, 181 ... Filter body, 182a ... fuel passage, 186 ... pressure regulator, 191 ... regulator case, 191a ... through hole, 191b ... opening, 192 ... valve body, 193 ... compression coil spring, 200 ... central axis of case cover.

Claims (7)

The fuel filter (143) is disposed outside the fuel tank (33), outside the fuel filter (143) is covered with the fuel filter casing (171), to the fuel filter case (171), the fuel filter (143) In the fuel supply device, a pressure regulator (186) for adjusting the internal pressure is integrally formed, and the fuel that has passed through the pressure regulator (186) is returned to the fuel tank (33) .
The fuel filter (143) is formed of a bag-shaped filter body (181) and a fuel passage (182a) communicating with the inside of the filter (143).
The bag-shaped filter body (181) is stored in a rounded state in the tubular fuel filter case (171) with the fuel passage (182a) on the inside,
Fuel enters the inside of the rounded filter body (181), passes through the filter body (181), and then passes through the fuel passage to be filtered.
The fuel supply apparatus characterized by the above-mentioned. The fuel filter (143) is disposed downstream of the fuel pump (92) , and the pressure regulator (186) is disposed downstream of the fuel filter (143). Fuel supply system. The fuel supply device according to claim 1 or 2, wherein a fuel return pipe (135) extends from the pressure regulator (186) to the upper fuel tank (33) . The fuel supply pipe (142) for flowing fuel from the fuel tank (33) to the fuel filter (143) and the fuel return pipe (135) are set to have different lengths and outer diameters. The fuel supply device according to claim 3 The filter case (171) includes a case main body (173) and a case cover (174) . The fuel inlet (171a) and the fuel return port (171c) are connected to the central axis (200 ) of the case cover (174). ) fuel supply system according to claim 1, characterized in that it is arranged offset from. The filter case (171) is provided with a step portion (173C) projecting radially outward, and a lower end of the pressure regulator (186) is supported by the step portion (173C). Item 6. The fuel supply device according to Item 5. The pressure regulator (186) includes a bottomed cylindrical resin case (191) fitted to a cylindrical portion (174a) integrally formed on the lower surface of the case cover (174), and the regulator case. A spherical steel valve element (192) that opens and closes a through hole (191a) opened in the bottom of (191), and a compression coil bar that biases the valve element (192) to close the through hole (191a). It is composed of a spring (193), the through hole (191a) leads to the filter element (176) side, and the opening (191b) of the regulator case (191) leads to the fuel return port (171c). The fuel supply device according to any one of claims 1 to 3.

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