JP2018144746A - Fuel control valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fuel control valve which prevents liquid fuel from flowing out.SOLUTION: A fuel control valve 8 comprises a case 10 and a movable body 20. The case 10 has a seat face 18. The movable body 20 has a movable valve body face 25. The movable body 20 moves by gravity to put a valve into an opened state and a closed state. The movable body 20 is also a float which floats on fuel to put the valve into the closed state. The fuel control valve 8 also has: a support shape 40 to support resin molding; a buoyancy control mechanism 50 which stabilizes a position of the movable body 20 even in a tilted position; a barrier mechanism 60 which prevents droplets of the fuel generated by rippling of a fuel surface FL from flowing out; and a flow rate control mechanism 70 which achieves a rapid change in a flow rate.SELECTED DRAWING: Figure 2

Description

  The disclosure herein relates to a fuel control valve.

  Patent document 1 discloses a fuel control valve. Patent document 1 is disclosing the fuel control valve called the float valve which responds to the liquid level of a fuel liquid. Further, Patent Document 1 discloses a fuel control valve called a rollover valve that responds to the inclination angle of a vehicle, in particular, toppling over. Patent Document 2 discloses a needle type fuel control valve.

JP 2007-77934 A Japanese Patent Laid-Open No. 2006-196245

  In the prior art configuration, the fuel control valve may tilt when the float is floating on the liquid fuel. In this case, the liquid level FL around the float is also inclined. At this time, a part of the float floats above the liquid level FL. The weight of this additional flying portion serves to sink the entire float. At the same time, the other part of the float sinks below the liquid level FL. This additional subsidence part pushes away liquid fuel and provides buoyancy to the float. Thus, the additional subsidence portion acts to lift the entire float. As a result, the characteristics of the fuel control valve may change due to the inclination of the fuel control valve.

  For example, the position of the fuel control valve may change according to the difference between the weight of the additional flying portion and the buoyancy provided by the additional sinking portion. For example, when the weight of the additional floating portion is larger than the buoyancy of the additional falling portion, the entire float sinks. As a result, the fuel control valve may change from the closed state to the open state.

  In view of the above, or other aspects not mentioned, there is a need for further improvements in fuel control valves.

  One disclosed object is to provide a fuel control valve that suppresses the effects of tilt.

  Another object disclosed is to provide a fuel control valve that suppresses changes in the open / closed state due to inclination.

  The fuel control valve disclosed herein includes a case (10) that provides a passage extending from a tank that stores fuel, and a float that is movably accommodated in the case and floats on the liquid level (FL) of the liquid fuel. And a movable body (20) that opens and closes. The movable body has a subsidence portion (51) that sinks from the liquid surface in a normal normal posture, the subsidence portion has a predetermined diameter (D1), and a first portion (51a) through which the liquid surface in the normal posture passes. And a second part (51b) located below the first part and having a diameter (D2) equal to or greater than the diameter of the first part.

  According to the disclosed fuel control valve, when the movable body floats in the normal posture, the liquid level is positioned in the first portion. A second part is located below the first part. The diameter of the second part is greater than or equal to the diameter of the first part. When the case and the movable body are inclined, the liquid level moves with respect to the movable body. As a result, the radially outer portion of the second portion tends to float above the liquid surface. However, since the second portion is below the first portion, the volume of the second portion that floats from the liquid surface is suppressed. Moreover, since the diameter of the second portion is equal to or larger than the diameter of the first portion, the volume of the first portion that rises from the liquid surface due to the inclination is also suppressed. As a result, the influence of inclination is suppressed.

  The fuel control valve disclosed herein includes a case (10) that provides a passage extending from a tank that stores fuel, and a float that is movably accommodated in the case and floats on the liquid level (FL) of the liquid fuel. And a movable body (20) that opens and closes. The movable body has a subsidence part (51) that sinks from the liquid surface in a normal normal posture and a floating part (52) that floats from the liquid surface in a normal posture, and the floating part is inclined with respect to the normal posture. In the posture, it has an additional subsidence part (53, 253, 353) that is added to the subsidence part and sinks from the liquid surface to give buoyancy to the movable body. It has an additional levitating portion (54, 254, 354) that floats more and gives weight against the buoyancy of the movable body, and the movable body has the buoyancy provided by the additional subsidence portion and the weight provided by the additional levitating portion. Adjust.

  According to the disclosed fuel control valve, there are a case where the movable body floats in a normal posture and a case where the movable body floats in an inclined posture. The additional floating portion gives weight to the movable body, and the additional subsidence portion gives buoyancy to the movable body. The adjustment shape adjusts these. For this reason, even if the attitude | position of a movable body changes from a normal attitude | position to an inclination attitude | position, the change of the buoyancy of a movable body can be suppressed. As a result, the influence of inclination is suppressed.

  The disclosed embodiments of the present specification employ different technical means to achieve each purpose. The reference numerals in parentheses described in the claims and this section exemplify the correspondence with the embodiments described later, and are not intended to limit the technical scope. The objects, features, and advantages disclosed in this specification will become more apparent with reference to the following detailed description and accompanying drawings.

It is a block diagram of the tank system concerning a 1st embodiment. It is sectional drawing which shows the fuel control valve of 1st Embodiment. It is a perspective view which shows the movable body of 1st Embodiment. It is a side view which shows the movable body of 1st Embodiment. It is sectional drawing which shows the movable body of 1st Embodiment. It is a side view which shows the movable body of 1st Embodiment. It is a perspective view which shows the movable body of 2nd Embodiment. It is a side view which shows the movable body of 2nd Embodiment. It is sectional drawing which shows the movable body of 2nd Embodiment. It is a side view which shows the movable body of 2nd Embodiment. It is a perspective view which shows the movable body of 2nd Embodiment. It is a side view which shows the movable body of 2nd Embodiment. It is sectional drawing which shows the movable body of 2nd Embodiment. It is a side view which shows the movable body of 2nd Embodiment.

  A plurality of embodiments will be described with reference to the drawings. In embodiments, functionally and / or structurally corresponding parts and / or associated parts may be assigned the same reference signs or reference signs that differ by more than a hundred. For the corresponding parts and / or associated parts, the description of other embodiments can be referred to.

First Embodiment In FIG. 1, a tank system 1 has a tank 3 for storing fuel for an engine (ENG) 2. The engine 2 is a power source for vehicles such as vehicles, ships, and aircraft. The tank system 1 is, for example, a vehicle tank system. In this case, the engine 2 is provided by an internal combustion engine. The fuel is supplied to the engine 2 as a liquid. However, fuel can produce fuel vapor. The fuel is gasoline or diesel fuel.

  The tank system 1 includes a fuel supply device 4 between the engine 2 and the tank 3. The fuel supply device 4 can include an in-tank pump, a fuel filter, a fuel injection pump, and a fuel injection valve. The fuel in the tank 3 is supplied to the engine 2 by the fuel supply device 4. The engine 2 provides power by burning fuel.

  The tank system 1 has a fuel vapor purification system 5. The fuel vapor purification system 5 is burned by supplying fuel vapor to the engine 2. The fuel vapor purification system 5 suppresses the discharge of fuel vapor to the atmosphere. The fuel vapor purification system 5 includes a fuel vapor purification device (FVEC) 6. The fuel vapor purification device 6 includes an accumulator that temporarily accumulates fuel vapor and a controller that supplies the accumulated fuel vapor to the engine 2 at a predetermined timing. For example, the accumulator is provided by activated carbon that adsorbs fuel vapor. Further, the controller is provided by an electric control device and a valve for introducing outside air for flushing.

  The fuel vapor purification system 5 has a fuel vapor passage 7 that communicates the cavity in the tank 3 with the fuel vapor purification device 6. The fuel vapor passage 7 guides the fuel vapor generated in the tank 3 to the fuel vapor purification device 6. The fuel vapor passage 7 is also a passage for supplying outside air to the tank 3. The fuel vapor passage 7 extends from the tank 3.

  The fuel vapor purification system 5 has a fuel control valve 8. The fuel control valve 8 allows fuel vapor and air to flow. The fuel control valve 8 suppresses the outflow of the fuel liquid from the tank 3 to the fuel vapor purification device 6. The fuel liquid flowing out into the fuel vapor passage 7 may generate a large amount of fuel vapor. In this case, the fuel vapor purification device 6 may be saturated. Therefore, it is desirable to suppress the outflow of the fuel liquid as much as possible. The fuel control valve 8 is provided in the fuel vapor passage 7. The fuel control valve 8 is fixed to the tank 3. In the figure, the liquid level FL of the fuel liquid is illustrated.

  When the fuel vapor purification device 6 includes a control device, the control device is an electronic control unit. The control device has at least one arithmetic processing unit (CPU) and at least one memory device as a storage medium for storing programs and data. The control device is provided by a microcomputer including a computer-readable storage medium. The storage medium is a non-transitional tangible storage medium that stores a computer-readable program in a non-temporary manner. The storage medium can be provided by a semiconductor memory or a magnetic disk. The controller can be provided by a computer or a set of computer resources linked by a data communication device. The program is executed by the control device to cause the control device to function as the device described in this specification and to cause the control device to perform the method described in this specification.

  The means and / or functions provided by the control device can be provided by software recorded in a substantial memory device and a computer that executes the software, software only, hardware only, or a combination thereof. For example, if the controller is provided by an electronic circuit that is hardware, it can be provided by a digital circuit including a number of logic circuits, or an analog circuit.

  In FIG. 2, the normal posture of the fuel control valve 8 is shown. In the following description, terms such as up, down, up direction UP, and down direction DW are based on regular postures. The fuel control valve 8 is a so-called rollover valve. The fuel control valve 8 is a gravity valve that reacts to gravity. The fuel control valve 8 may be called by various names such as a fuel liquid cutoff valve or a float valve. In the figure, the valve closing state is shown. In the drawing, an upward direction UP and a downward direction DW are shown. In the drawing, the central axis AX of the fuel control valve 8 is shown. In the drawing, an example of the liquid level FL of the fuel is shown.

  The fuel control valve 8 has a case 10 and a movable body 20. Case 10 is made of resin. The case 10 defines a fuel vapor passage 7 extending from the tank 3. Case 10 provides a fixed valve seat surface. The case 10 provides a container that houses the movable body 20. The case 10 is also a guide member that guides the movement of the movable body 20. The case 10 is also a cover that prevents the fuel liquid in the tank 3 from splashing.

  The movable body 20 opens and closes the fuel vapor passage 7. The fuel control valve 8 provides a valve open state and a valve close state according to the position of the movable body 20. When the movable body 20 is in the upper end position, the fuel control valve 8 provides a closed state. When the movable body 20 is in the lower end position, the fuel control valve 8 provides an open state. When the movable body 20 is in a position other than the upper end position, the fuel control valve 8 provides an open state. The movable body 20 is also an operation member that operates the fuel control valve 8 in an open state or a closed state.

  The movable body 20 is made of resin. The movable body 20 is a resin molded product. The resin is a thermoplastic resin. The resin can be provided by polyacetal (POM) or polycarbonate (PC). The movable body 20 is movable in the case 10. The movable body 20 is movable in the vertical direction, that is, along the central axis AX over the movement range ST. The movable body 20 has a valve body surface that opens and closes the fuel vapor passage 7 in contact with or away from the valve seat surface.

  The movable body 20 moves according to the inclination angle of the tank 3, that is, gravity. The movable body 20 has a mass that can be moved by gravity. The movable body 20 can float on the fuel liquid in the illustrated normal posture. The movable body 20 floats in the fuel liquid when at least a part of the movable body 20 is submerged in the fuel liquid. The movable body 20 has an air chamber for floating and moving in the fuel liquid. The movable body 20 is also called a float. The movable body 20 is also called a movable valve body.

  When the inclination angle of the tank 3 is less than a predetermined angle, the fuel control valve 8 provides an open state. When the inclination angle of the tank 3 exceeds a predetermined angle, the fuel control valve 8 provides a closed state. For example, when the vehicle rolls over, the movable body 20 does not float on the fuel liquid. In this case, the fuel control valve 8 provides a closed state.

  When the inclination angle of the tank 3 is below a predetermined angle and the liquid level FL of the fuel liquid is sufficiently low, the fuel control valve 8 provides a valve open state. When the inclination angle of the tank 3 is below a predetermined angle and the liquid level FL of the fuel liquid is sufficiently high, the fuel control valve 8 provides a closed state. Thereby, even when the liquid level FL of the fuel liquid in the tank 3 is high, the outflow of the fuel liquid is suppressed.

  The case 10 includes a first case 11 and a second case 12. The first case 11 is a resin molded product. The first case 11 has a small diameter part 13, a large diameter part 14, and a step part 15. The small diameter portion 13 has a predetermined diameter. The small diameter portion 13 provides an outlet pipe. The small diameter portion 13 is also a portion that provides a valve. The large diameter portion 14 has a larger diameter than the small diameter portion 13. The large-diameter portion 14 accommodates the movable body 29. The large-diameter portion 14 defines a storage chamber 34 that stores the movable body 20. The step portion 15 is a portion connecting the small diameter portion 13 and the large diameter portion 14. The step portion 15 connects the lower end portion of the small diameter portion 13 and the upper end portion of the large diameter portion 14. The step portion 15 closes between the lower end portion of the small diameter portion 13 and the upper end portion of the large diameter portion 14. The first case 11 can include a vent hole.

  The small diameter portion 13 has a partition wall 16. The partition wall 16 is provided in the small diameter portion 13 so as to partition the internal cavity of the small diameter portion 13 vertically. The partition wall 16 is also an inner flange. The small diameter portion 13 has a cylindrical portion 17. The cylindrical portion 17 is supported by the partition wall 16. The cylindrical portion 17 provides a passage extending in the vertical direction. The cylindrical portion 17 is disposed so as to extend downward from the partition wall 16. The cylindrical portion 17 protrudes from the partition wall 16 in the direction of the large diameter portion, that is, in the downward direction DW. This shape assists the return flow of the fuel liquid from above the partition wall 16 into the tubular portion 17.

  The upper end of the cylindrical portion 17 is continuous with the partition wall 16. The lower end of the cylindrical portion 17 opens toward the movable body 20. A fixed valve seat surface 18 is formed inside the lower end of the cylindrical portion 17. The valve seat surface 18 is an inner surface of the cylindrical portion 17. The valve seat surface 18 is an inner enlarged surface that extends downward. The valve seat surface 18 has an inner cone shape whose inner diameter increases toward the tip. The valve seat surface 18 is a tapered surface having a linear inner enlarged surface. The valve seat surface 18 may be a curved surface.

  The small diameter portion 13 is cylindrical. The small diameter portion 13 has a larger inner diameter than the cylindrical portion 17. Therefore, a cylindrical cavity closed by the partition wall 16 is formed between the small diameter portion 13 and the cylindrical portion 17. The small-diameter portion 13 defines a cavity as the outlet passage 31 inside. The outlet passage 31 is formed between the outlet opening 32 and the partition wall 16. The small-diameter portion 13 has a cylindrical shape or a bottomed cylindrical shape with the partition wall 16 as a bottom. The cylindrical portion 17 defines a valve passage 33 that is opened and closed by the fuel control valve 8. The valve passage 33 is partitioned by a convex curved surface. The valve passage 33 has an inner surface that spreads smoothly in the upward direction UP. The valve passage 33 is enlarged by the valve seat surface 18 in the downward direction DW.

  The large diameter portion 14 is cylindrical. The large-diameter portion 14 defines a cavity as a storage chamber 34 inside. The large diameter part 14 accommodates the movable body 20. A second case 12 is provided at the lower end of the large diameter portion 14.

  The second case 12 is provided at the lower end of the first case 11. The second case 12 is connected to the lower end of the large diameter portion 14. In this embodiment, the first case 11 and the second case 12 are connected by snap fit. The first case 11 and the second case 12 may be connected using a connection method such as a screw, a separate retainer, or welding. The second case 12 provides the bottom of the case 10. The second case 12 is disposed so as to cover the lower end of the large diameter portion 14. The second case 12 defines a lower opening 35. The lower opening 35 is a main entrance into the case 10. The lower opening 35 functions as an inlet for the fuel liquid.

  The movable body 20 includes a main body 21, a flange portion 22, and a needle portion 23. The main body 21 is cylindrical. The main body 21 has an upper surface 21a, a lower surface 21b, and an outer surface 21c. The upper surface 21a is inclined so as to be lowered outward in the radial direction. The upper surface 21a corresponds to a liquid level assumed at an inclination angle allowed for the fuel control valve 8.

  The flange portion 22 is located in the upward direction UP from the main body 21. The flange portion 22 is separated from the main body 21. The flange portion 22 is located between the main body 21 and the needle portion 23. The flange portion 22 extends outward in the radial direction at the base portion of the needle portion 23.

  The flange portion 22 has an upper surface 22a, a lower surface 22b, and an outer surface 22c. The upper surface 22a is inclined so as to fall inward in the radial direction. The upper surface 22a corresponds to the liquid level assumed at the inclination angle allowed for the fuel control valve 8. The lower surface 22b extends horizontally in the illustrated normal posture. The diameter of the outer side surface 22 c is smaller than the diameter of the main body 21. The flange portion 22 has a plurality of fuel passages penetrating in the vertical direction. The fuel passage prevents fuel liquid from accumulating on the upper surface 22a. The flange portion 22 is a rotating solid having a triangular cross section.

  The needle portion 23 is tapered toward the upward direction UP. The needle portion 23 has a movable valve body surface 25 provided by a curved surface at the distal end portion. The fuel control valve 8 provides a closed state when the valve seat surface 18 and the valve body surface 25 come into contact with each other. The fuel control valve 8 provides a valve open state by separating the valve seat surface 18 and the valve body surface 25.

  The tip of the needle portion 23 is inserted into the valve seat surface 18. The tip of the needle portion 23 is guided by the valve seat surface 18 and positioned on the central axis AX. Therefore, a range in the vicinity of the open end of the valve seat surface 18 functions as a guide surface for guiding the needle portion 23.

  The main body 21, the flange portion 22, and the needle portion 23 define a float chamber 24 at the center. The float chamber 24 is closed in the upward direction UP. The float chamber 24 is opened to the lower surface 21b in the downward direction DW. The movable body 20 provides a cap-like float that generates buoyancy only in a normal posture.

  The fuel control valve 8 has a support shape 40. The main body 21 can be called a large resin lump. The main body 21 defines a plurality of through holes 41. The support shape 40 is provided by a plurality of through holes 41. The plurality of through holes 41 are dispersed in the main body 21. The plurality of through holes 41 are located in a relatively thick resin. The plurality of through holes 41 extend in the vertical direction. The plurality of through holes 41 communicate with the upper surface 21 a and the lower surface 21 b of the main body 21. The plurality of through holes 41 are open in the upper surface 21a. The plurality of through holes 41 are not opened on the outer surface 21 c of the main body 21. Openings in the upper surface 21 a of the plurality of through holes 41 are located below the flange portion 22. The plurality of through holes 41 are located radially outside the float chamber 24.

  The manufacturing method of the fuel control valve 8 includes a step of molding the movable body 20 with resin. At this stage, the plurality of through holes 41 are formed by a mold. Therefore, the plurality of through holes 41 have a molded shape. The plurality of through holes 41 have molding marks for extracting the molding die.

  The mold located in the plurality of through holes 41 carries out the heat of the resin in the molding stage. The mold located in the plurality of through holes 41 promotes heat release of the resin. For this reason, the movable body 20 is formed by a relatively thick resin layer. The relatively thick resin layer gives the mass required for the movable body 20.

  The plurality of through holes 41 have an annular portion 42 that is continuous in the circumferential direction. The annular part 42 may communicate with the float chamber 24. In this case, the annular portion 42 can function as an auxiliary chamber for the float chamber 24. The annular portion 42 may be used as a storage chamber for storing a spring.

  The plurality of through holes 41 also function as a passage. Part of the air or fuel passes through the plurality of through holes 41. The valve seat surface 18 and the valve body surface 25 provide a valve. The plurality of openings of the plurality of through holes 41 in the upper surface 21a are separated from the valve in the vertical direction. For this reason, the spray of fuel is difficult to reach the valve.

  A flange portion 22 is provided between the plurality of openings of the plurality of through holes 41 and the valve. The flange portion 22 provides a barrier member that suppresses the arrival of the fuel liquid blown out from the plurality of through holes 41 to the valve. For this reason, the spray of fuel is difficult to reach the valve.

  A plurality of openings of the plurality of through holes 41 in the upper surface 21 a are opened radially outward from the float chamber 24. For this reason, the plurality of openings of the plurality of through holes 41 in the upper surface 21a are separated from the valve in the radial direction. For this reason, the spray of fuel is difficult to reach the valve. Further, the upper surface 21a is inclined toward the radially outer side. For this reason, the spray of fuel is difficult to reach the valve.

  In the above-described viewpoint, the support shape 40 supports resin molding of the movable body 20. The support shape 40 facilitates resin molding of the movable body 20. In another aspect, the support shape 40 supports a function of suppressing the arrival of fuel splashes on the valve. Thus, the support shape 40 supports the resin molding process and / or the fuel outflow suppression.

  The fuel control valve 8 has a buoyancy adjustment mechanism 50. The buoyancy adjusting mechanism 50 is mainly provided by the flange portion 22. The buoyancy adjusting mechanism 50 adjusts the buoyancy of the movable body 20 when the movable body 20 functions as a float. The flange portion 22 adjusts the buoyancy of the movable body 20 from a plurality of viewpoints.

  First, the flange portion 22 improves the stability at the liquid level FL when the movable body 20 functions as a float. In other words, the sensitivity of the movable body 20 is adjusted. The flange portion 22 is positioned so that the flange portion 22 is positioned over the liquid surface FL when the movable body 20 floats on the liquid surface FL.

  The flange portion 22 causes a relatively large volume movement above the liquid level FL when the movable body 20 moves above the liquid level FL. For this reason, the movable body 20 loses its buoyancy by increasing the weight acting on the downward direction DW so as to counter the upward movement. When the movable body 20 moves below the liquid level FL, the flange portion 22 causes a relatively large volume movement below the liquid level FL. For this reason, the movable body 20 is reduced in weight acting on the downward direction DW so as to oppose movement in the downward direction DW, and obtains buoyancy. In this way, the buoyancy of the movable body 20 is adjusted so as to counter the floating and sinking of the movable body 20. When the flange portion 22 is not provided, the buoyancy change accompanying the floating and sinking of the movable body 20 depends on the volume change generated by the needle portion 23 with respect to the liquid level FL. For this reason, the amount of adjustment of buoyancy is small. On the other hand, since the flange part 22 is thicker than the needle part 23, the flange part 22 produces a comparatively large volume change. As a result, the position of the movable body 20 on the liquid level FL is stabilized.

  Next, the flange part 22 suppresses the buoyancy change resulting from the inclination angle when the movable body 20 functions as a float. When the inclination angle of the central axis AX increases, one portion of the flange portion 22 additionally floats on the liquid level FL. At the same time, the other portion of the flange portion 22 additionally sinks below the liquid level FL. At this time, the movable body 20 increases the weight acting in the downward direction DW according to the volume of the additional floating portion, and loses buoyancy. At the same time, the movable body 20 gains buoyancy by reducing the weight acting in the downward direction DW according to the volume of the additional settlement portion. The shape of the flange portion 22 defined by the upper surface 22a, the lower surface 22b, and the outer surface 22c is set so that the additional floating portion and the additional subsidence portion are balanced.

  The fuel control valve 8 has a barrier mechanism 60. The barrier mechanism 60 includes a plurality of barriers 61 and a plurality of barrier passages 62. The plurality of barriers 61 are plate-shaped members. The plurality of barriers 61 define a plurality of barrier passages 62 between them. The plurality of barriers 61 are formed inside the first case 11. The plurality of barriers 61 are resin-molded integrally with the first case 11. The plurality of barriers 61 are also called a plurality of wave-dissipating plates or a plurality of baffle plates.

  The plurality of barriers 61 extend from the radially inner side of the small diameter portion 13 in the vertical direction, that is, along the central axis AX. The plurality of barriers 61 extend from the small diameter portion 13 and the step portion 15 in the downward direction DW.

  Further, the plurality of barriers 61 are located between the case 10 and the movable body 20. The plurality of barriers 61 extend to face the movable body 20. The plurality of barriers 61 extend so as to contact the movable body 20 in the valve-closed state or form a minute gap with the movable body 20 in the valve-closed state with respect to the vertical direction. The plurality of barriers 61 are opposed to the upper surface 22a via minute gaps in the vertical direction. The plurality of barriers 61 are formed to allow movement of the movable body 20 between the valve open state and the valve closed state. The plurality of barriers 61 are formed so as to be located in the cavity between the case 10 and the movable body 20 in the vicinity of the valve closed state.

  The small diameter portion 13 and the step portion 15 are connected by a smooth curved surface. The plurality of barriers 61 extend along this curved surface. The plurality of barriers 61 slightly protrude from the inner surface of the small diameter portion 13 toward the radially inner side. The plurality of barriers 61 are separated from the cylindrical portion 17. The plurality of barriers 61 extend from the inside of the small diameter portion 13 in the radial direction. The plurality of barriers 61 extend along the step portion 15 in the radial direction. The plurality of barriers 61 extend within the range of the step portion 15 in the radial direction. The plurality of barriers 61 do not reach the large diameter portion 14 in the radial direction. The plurality of barriers 61 are located on the radially outer side from the cylindrical portion 17. The plurality of barriers 61 overlap each other in the radial direction. The barrier 61 is also a barrier member that inhibits a linear flow from the radially outer side to the radially inner side.

  The plurality of barriers 61 define a plurality of barrier passages 62 therebetween. The barrier passage 62 extends from the radially outer side toward the radially inner side with respect to the central axis AX.

  The fuel control valve 8 has a flow rate adjusting mechanism 70. The flow rate adjustment mechanism 70 gives a rapid increase in the flow rate when the movable body 20 moves from the closed state to the open state. That is, the movable body 20 provides a large increase in flow rate by only a slight movement from the closed state. The flow rate adjusting mechanism 70 provides a large opening area in the valve open state.

  The flow rate adjusting mechanism 70 has a plurality of grooves 71 formed in the cylindrical portion 17. The plurality of grooves 71 are disposed at the open end of the valve seat surface 18. The plurality of grooves 71 are disposed only at the open end of the valve seat surface 18. The plurality of grooves 71 are disposed on the open end side of the valve seat surface 18 with respect to the seal line in contact with the valve body surface 25. The plurality of grooves 71 do not reach the seal line. As a result, the flow through the plurality of grooves 71 is permitted only by slightly lifting the valve body surface 25 from the valve seat surface 18. Since not only the flow along the valve seat surface 18 but also the flow through the plurality of grooves 71 is allowed, a large increase in the flow rate can be obtained. Conversely, when the valve body surface 25 approaches toward the valve seat surface 18, the flow is suddenly interrupted from a large flow rate.

  The plurality of grooves 71 divide the edge of the opening end of the valve seat surface 18 into a plurality of convex portions 72. The plurality of convex portions 72 are in contact with the needle portion 23. The plurality of convex portions 72 guide the needle portion 23. From this viewpoint, the flow rate adjusting mechanism 70 is also a guide mechanism. The plurality of convex portions 72 guide the valve body surface 25 to a seal line on the valve seat surface 18.

  The buoyancy adjustment mechanism 50 will be described in detail with reference to FIGS. 3, 4, 5, and 6. These drawings show the movable body 20. The movable body 20 has a buoyancy adjustment mechanism 50. The buoyancy adjustment mechanism 50 suppresses the influence of inclination.

  In FIG. 4, one liquid level FL0 of the fuel liquid is shown. The liquid level of the fuel liquid moves up and down in the case 10. When the liquid level gradually rises, the movable body 20 floats on the liquid fuel when it reaches the height illustrated by the liquid level FL0 with respect to the movable body 20. In this embodiment, since the moving range of the movable body 20 is limited within the case 10, the liquid level may further rise. Therefore, the liquid level FL0 is the lowest height at which the movable body 20 can freely float on the fuel liquid. The liquid level FL0 is also called a floating liquid level. As shown in the figure, a state in which the central axis AX of the movable body 20 coincides with the up and down directions UP and DW can be called a normal posture of the movable body 20. The liquid level FL0 is defined by the buoyancy applied to the movable body 20 in the normal posture. The position of the liquid level FL0 can be adjusted by the weight of the movable body 20, the amount of drainage of the movable body 20, the volume of the air chamber including the float chamber 24, and the like.

  The movable body 20 has a sinking portion 51 that sinks from the liquid level FL0 in a normal posture. In other words, the movable body 20 has a sinking portion 51 that sinks below the liquid level FL0 and defines the amount of drainage when the movable body 20 floats on the fuel liquid. The sinking portion 51 includes the movable body 20, and the sinking portion 51 includes the main body 21. The subsidence portion 51 is located below the flange portion 22.

  The subsidence portion 51 has a first portion 51a. The first portion 51a has a predetermined diameter D1. The first portion 51a may be a polygon. As illustrated, the liquid level FL0 in the normal posture passes through the first portion 51a. In other words, when the movable body 20 is floating on the liquid level FL0, the liquid level FL0 is located in the first portion 51a. The diameter D1 is the diameter of the intersection of the liquid level FL0 and the movable body 20 when the movable body 20 in the normal posture freely floats on the fuel liquid. The diameter D1 defines the area of the movable body 20 that intersects the liquid level FL0. The first portion 51a is a cylindrical portion having the float chamber 24 inside.

  The subsidence portion 51 has a second portion 51b located below the first portion 51a. The second portion 51b has a diameter D2 that is equal to or larger than the diameter of the first portion 51a (D1 ≦ D2). The second part 51 b is provided by the main body 21. The second portion 51b is below the liquid level FL0 by the length of the first portion 51a.

  The diameter D2 of the second portion 51b is larger than the diameter D1 of the first portion 51a (D1 <D2). Therefore, the second portion 51b has a shoulder. The distance between the first portion 51a and the shoulder portion suppresses the floating of the shoulder portion above the liquid level FL0 when the movable body 20 is inclined from the normal posture. The second portion 51b has an upper surface 21a. The upper surface 21a is a truncated cone that extends downward. The inclination of the upper surface 21a from the liquid level FL0 suppresses the floating of the subsidence portion 51 above the liquid level FL0. The inclination of the upper surface 21a corresponds to the maximum inclination angle that can suppress the floating of the shoulder.

  The movable body 20 has a floating portion 52 that floats from the liquid level FL0 in the normal posture. In other words, the movable body 20 has a floating portion 52 that protrudes above the liquid level FL0 when the movable body 20 floats on the fuel liquid. The floating portion 52 is located above the first portion 51a. The floating portion 52 has the flange portion 22. The floating portion 52 has a needle portion 23. The flange portion 22 has a diameter D3 that is equal to or larger than the diameter D1 of the first portion 51a (D1 <D3). The diameter D3 of the flange portion 22 is smaller than the diameter D2 of the second portion 51b (D3 <D2).

  The flange portion 22 is located immediately above the liquid level FL0. The liquid level FL0 is in contact with the lower surface 22b. The liquid level FL0 may be positioned slightly above or slightly below the lower surface 22b. The liquid level FL0 is positioned in the vicinity of the lower surface 22b. The flange portion 22 generates buoyancy so as to resist the force that moves the entire movable body 20 downward. Consider the case where the movable body 20 moves in the downward direction DW from the state shown in the figure. In this case, the volume defined by the diameter D3 of the flange portion 22 sinks in the fuel liquid. That is, the amount of drainage increases. For this reason, the buoyancy which resists the movement to the downward direction DW is newly produced | generated by the movable body 20. FIG. Therefore, the size of the liquid level FL0 affects the stability of the movable body 20. In this embodiment, since the flange portion 22 is positioned immediately above the liquid level FL0, the flange portion 22 provides buoyancy that resists movement in the downward direction DW. When the movable body 20 moves in the downward direction DW, the buoyancy generated by the first portion 51a is small. However, the buoyancy generated by the flange portion 22 supplements the buoyancy generated by the first portion 51 a and contributes to improving the stability of the movable body 20. For this reason, it is desirable that the diameter D3 of the flange portion 22 is larger than the diameter D1 of the first portion 51a.

  In FIG. 5, the upper surface 22a of the flange portion 22 has a funnel shape. The upper surface 22a has an inner cone shape whose inner diameter decreases downward. The flange portion 22 has a lower surface 22b. The lower surface 22b is a horizontal plane parallel to the liquid level FL0. The flange portion 22 has an outer surface 22c. The outer side surface 22c is a cylindrical outer surface. The flange portion 22 has a plurality of grooves 22d for discharging liquid fuel from a dish-shaped portion defined by the upper surface 22a.

  FIG. 6 shows an inclined posture in which the movable body 20 is inclined from the normal state by the inclination angle TLmax. The central axis AX is inclined by the inclination angle TLmax from the central axis AX0 in the normal state. The inclination posture corresponds to the maximum allowable inclination required for the fuel control valve 8. Therefore, the fuel control valve 8 is required to satisfy a predetermined function up to the inclination angle TLmax.

  In the inclined posture, the illustrated liquid level FL1 intersects the movable body 20. The liquid level FL1 passes above the upper surface 21a. The liquid level FL1 passes through a portion located in the downward direction DW of the flange portion 22 in the inclined posture. The liquid surface FL1 in the inclined posture is located along the upper surface 21a and the upper surface 22a. On the floating side where the sinking portion 51 approaches the liquid level FL1, the liquid level FL1 is located along the upper surface 21a. On the sinking side where the floating portion 52 approaches the liquid level FL1, the liquid level FL1 is located along the upper surface 22a.

  The upper surface 21a extends in a truncated cone shape so as to connect the first portion 51a and the second portion 51b. Regardless of the posture of the movable body 20, the upper surface 21a is at a position below the liquid level FL1 or at the same position as the liquid level FL1. The upper surface 21a is an inclined surface that is inclined with respect to the vertical direction. The upper surface 21a can be provided by various surfaces such as a stepped surface and a concave curved surface.

  The floating portion 52 has an additional sinking portion 53 that sinks from the liquid level FL1 in addition to the sinking portion 51 in the inclined posture. The additional subsidence portion 53 is provided by the flange portion 22. The additional subsidence portion 53 is provided by the radially outer portion of the flange portion 22. The additional subsidence portion 53 includes the lower surface 22 b of the flange portion 22. The additional subsidence portion 53 is a portion above the lower surface 22 b of the flange portion 22. The additional subsidence portion 53 is a portion of the flange portion 22 that has submerged below the liquid level FL1. The additional subsidence portion 53 is a wedge-shaped solid. The additional subsidence portion 53 supplements buoyancy to the entire movable body 20 by sinking below the liquid level FL1.

  The sinking portion 51 has an additional floating portion 54 that floats above the liquid level FL0 in addition to the floating portion 52 in the inclined posture. The additional levitation portion 54 is provided by the first portion 51 a of the subsidence portion 51. The additional floating portion 54 has a wedge shape. The additional floating portion 54 gives the movable body 20 a weight that resists the buoyancy of the movable body 20. As a result, the weight of the additional floating portion 54 tends to sink the entire movable body 20. The additional floating portion 54 has the float chamber 24 therein. The additional floating portion 54 is provided by a part of the cylindrical first portion 51a. Therefore, the weight of the additional floating portion 54 is smaller than that of the solid bar.

  It can be said that the movable body 20 has an adjustment shape that adjusts the buoyancy provided by the additional sinking portion 53 and the weight provided by the additional floating portion 54. The adjustment shape is provided in the subsidence portion 51 and has an upper surface 21a whose outer diameter decreases toward the liquid level FL0 in the normal posture. The adjustment shape is positioned on the floating portion 52 and has a flange portion 22 that extends radially outward and provides an additional subsidence portion 53. The adjustment shape is provided by the upper surface 21 a and the flange portion 22.

  The adjustment shape adjusts the buoyancy provided by the additional subsidence portion 53 to be greater than the weight provided by the additional levitation portion 54. In other words, the buoyancy provided by the additional subsidence portion 53 is greater than the weight provided by the additional levitation portion 54. Thereby, the movable body 20 tends to float in the inclined posture rather than the normal posture or as it moves from the normal posture to the inclined posture. Therefore, the change in the open / close state of the valve by the movable body 20 is suppressed.

  The buoyancy adjustment mechanism 50 is provided by an adjustment shape. The adjustment shape has a stepped shape 55 provided on the movable body 20. The stepped shape 55 is provided by the first portion 51 a, the upper surface 21 a, and the flange portion 22. The stepped shape 55 suppresses the increase in the volume of the additional floating portion 54 and increases the volume of the additional subsidence portion 53 while the liquid level changes from the liquid level FL0 to the liquid level FL1. The increase in the volume of the additional subsidence portion 53 is suppressed from the increase in the volume of the additional floating portion 54. The diameter D1 of the first portion 51a and the diameter D3 of the flange portion 22 realize the above relationship. The liquid level FL0 passes through the narrow portion provided by the stepped shape 55 in the normal posture.

  The movable body 20 has a constriction between the main body 21 and the flange portion 22. The stepped shape 55 is also called a constricted shape. The adjustment shape is provided at a boundary portion between the sinking portion 51 and the floating portion 52.

  When the movable body 20 is tilted, the fuel liquid enters the air chamber including the float chamber 24. For this reason, the amount of drainage of the movable body 20 is reduced, and the buoyancy is reduced. In this embodiment, the volume of the additional subsidence portion 53 suppresses the vertical movement of the movable body 20 against the decrease in the amount of drainage of the movable body 20.

  According to this embodiment, there are a case where the movable body 20 floats in a normal posture and a case where the movable body 20 floats in an inclined posture. When the movable body 20 floats in the normal posture, the liquid level is positioned on the first portion 51a. A second portion 51b is located below the first portion 51a. The diameter D2 of the second portion 51b is not less than the diameter D1 of the first portion 51a. When the case 10 and the movable body 20 are inclined, the liquid level FL moves with respect to the movable body 20. As a result, the radially outer portion of the second portion 51b tends to float above the liquid surface. However, since the second portion 51b is below the first portion 51a, the volume of the second portion 51b that rises from the liquid surface is suppressed. Moreover, since the diameter D2 of the second portion 51b is equal to or greater than the diameter D1 of the first portion 51a, the volume of the first portion 51a that floats from the liquid surface due to the inclination is also suppressed. As a result, the influence of inclination is suppressed.

Second Embodiment This embodiment is a modified example based on the preceding embodiment. In the above embodiment, the outer surface 22c is provided by a cylindrical outer surface. Instead, in this embodiment, the flange portion 22 does not include the outer surface 22c. In addition, in the above embodiment, the plurality of through holes 41 are open in the upper surface 21a. Instead, in this embodiment, the plurality of through holes 241 are open at the boundary portion between the main body 21 and the flange portion 22.

  In FIG. 7, the flange portion 22 has an upward-opening collar shape. The flange portion 22 has a lower surface 222b. The lower surface 222b has an inclination angle larger than the inclination angle of the upper surface 21a. The lower surface 222b is provided by a downwardly facing partial conical surface. The upper surface 22a has an inclination angle corresponding to the inclination angle of the upper surface 21a. The inclination angle of the upper surface 22a is smaller than the inclination angle of the lower surface 222b. As a result, the flange portion 22 is a rotating body having a top at the radially outer side as a vertex. In other words, the flange portion 22 does not include the outer side surface 22c.

  The movable body 20 defines a plurality of through holes 241. The plurality of through holes 241 extend from the main body 21 to the intersection of the upper surface 21a and the lower surface 222b. The plurality of through holes 241 are opened at this intersection. The plurality of through holes 241 open from both the upper surface 21a to the lower surface 222b. Also in this embodiment, the plurality of through holes 241 are open in the upper surface 21a. The flange portion 22 is provided between the upper surface 21 a and the valve body surface 25.

  Since the openings of the plurality of through holes 241 extend over both the upper surface 21a and the lower surface 222b, they are directed radially outward. When the fuel liquid blows up through the plurality of through holes 241, the liquid fuel is blown out between the lower surface 222b and the upper surface 21a. The flow of the fuel liquid is directed radially outward as indicated by an arrow by the lower surface 222b. In other words, the liquid fuel is blown out radially outward. Also in this embodiment, the flange portion 22 provides a passage that is directed radially outward.

  In FIG. 8, the flange portion 22 has a portion above the liquid level FL0 and a portion below the liquid level FL0. The lower surface 222b extends both above and below the liquid level FL0. In other words, a part of the flange portion 22 extends to the subsidence portion 51. A lower portion of the flange portion 22 provides a first portion 51a. Therefore, most of the flange portion 22 is still in the floating portion 52.

  The movable body 20 has a sinking portion 51 and a floating portion 52. The subsidence portion 51 has a first portion 51a and a second portion 51b. The first portion 51 a is continuously connected to the floating portion 52.

  The liquid level FL0 in the normal posture of the movable body 20 is illustrated. When the movable body 20 floats freely in the fuel liquid, the liquid level FL0 spreads to the illustrated position. The first portion 51a where the liquid level FL0 is located in the normal posture has a diameter D1. The second portion 51b has a diameter D2. The liquid level FL0 crosses the first portion 51a. The flange part 22 has the largest diameter D3 in the uppermost part. The liquid level FL0 intersects the lower surface 222b. Such a shape increases the amount of drainage according to the inclination of the lower surface 222b when the movable body 20 moves in the downward direction DW. Therefore, the movable body 20 on the liquid level FL0 is stabilized.

  The movable body 20 has a stepped shape 55 at the boundary portion between the sinking portion 51 and the floating portion 52. The liquid level FL0 passes through the stepped shape 55. The liquid level FL0 is positioned above the boundary portion. The liquid level FL0 is located in the range of the lower surface 222b, the portion of the stepped shape 55 whose diameter decreases downward. The stepped shape 55 provides an adjustment shape.

  In FIG. 9, the through hole 241 opens at a boundary portion between the upper surface 21a and the lower surface 222b.

  FIG. 10 shows an inclined posture in which the movable body 20 is inclined from the normal state by the inclination angle TLmax. The floating portion 52 has an additional subsidence portion 253 that sinks from the liquid level FL1 in addition to the subsidence portion 51 in the inclined posture. The additional subsidence portion 253 supplements the entire movable body 20 with buoyancy by sinking below the liquid level FL1.

  The sinking portion 51 has an additional floating portion 254 that floats above the liquid level FL0 in addition to the floating portion 52 in the inclined posture. The additional floating portion 254 is provided by a portion of the first portion 51a. The first portion 51a has an inverted truncated cone shape. The additional floating portion 254 has a wedge shape that occupies the circumferential range of the first portion 51a.

  It can be said that the movable body 20 has an adjustment shape that adjusts the buoyancy provided by the additional sinking portion 253 and the weight provided by the additional floating portion 254. The adjustment shape is provided by the upper surface 21 a and the flange portion 22. The adjustment shape is also a stepped shape 55. The adjustment shape adjusts the buoyancy provided by the additional sinking portion 253 to be greater than the weight provided by the additional floating portion 254. In other words, the buoyancy provided by the additional sinking portion 253 is greater than the weight provided by the additional flying portion 254. Thereby, the change of the opening-and-closing state of the valve resulting from inclination is suppressed. According to this embodiment, the influence of inclination is suppressed.

Third Embodiment This embodiment is a modification in which the preceding embodiment is a basic form. In the above embodiment, the movable body 20 includes the flange portion 22. Instead, in this embodiment, the movable body 20 does not include the flange portion 22. In addition, in the above-described embodiment, the plurality of through holes 41 are located on the annular portion 42. Instead, in this embodiment, a communication portion 343 is formed between the plurality of through holes 341 and the annular portion 42.

  In FIG. 11, the movable body 20 includes a main body 21 and a needle portion 23. The movable body 20 does not include the flange portion 22. The needle portion 23 extends from the main body 21. The movable body 20 defines a plurality of through holes 341. The plurality of through holes 341 extend through the main body 21. The plurality of through holes 341 are opened in the upper surface 21a and the lower surface 21b.

  In FIG. 12, the movable body 20 has a sinking portion 51 and a floating portion 52. The subsidence portion 51 has a first portion 51a and a second portion 51b. The first portion 51a has a diameter D1. The diameter D1 is the diameter of the intersection with the liquid level FL0. The second portion 51b has a diameter D2.

  In FIG. 13, the plurality of through holes 341 are open on the radially outer side. A plurality of communication portions 343 are provided between the annular portion 42 and the plurality of through holes 341. Thereby, even when liquid fuel blows out from the plurality of through holes 341, the liquid fuel is discharged to the outside in the radial direction away from the valve body surface 25. The plurality of through holes 341 are arranged on a circle having a radius R41. The radius R41 is larger than ½ of the radius R20 of the main body 21.

  FIG. 14 shows an inclined posture in which the movable body 20 is inclined from the normal state by the inclination angle TLmax. The floating part 52 has an additional subsidence part 353 that sinks from the liquid level FL1 in addition to the subsidence part 51 in the inclined posture. The additional subsidence portion 353 sinks below the liquid level FL1, thereby supplementing the entire movable body 20 with buoyancy. The additional subsidence portion 353 has the float chamber 24 therein. For this reason, it is lighter than a solid bar. The additional subsidence portion 353 gives the movable body 20 buoyancy corresponding to the amount of drainage while being lightweight.

  The sinking portion 51 has an additional floating portion 354 that floats above the liquid level FL0 in addition to the floating portion 52 in the inclined posture. The additional floating portion 354 is provided by a portion of the first portion 51a. The first portion 51a is cylindrical. The additional floating portion 354 has a wedge shape that occupies the circumferential range of the first portion 51a. The additional floating portion 354 has the float chamber 24 therein. For this reason, it is lighter than a solid bar.

  It can be said that the movable body 20 has an adjustment shape that adjusts the buoyancy provided by the additional sinking portion 353 and the weight provided by the additional floating portion 354. The adjusting shape is provided by the upper surface 21a. The adjustment shape is also a stepped shape 55. The adjustment shape adjusts the buoyancy provided by the additional sinking portion 353 to be greater than the weight provided by the additional floating portion 354. In other words, the buoyancy provided by the additional sinking portion 353 is greater than the weight provided by the additional flying portion 354. Thereby, the change of the opening-and-closing state of the valve resulting from inclination is suppressed. According to this embodiment, the influence of inclination is suppressed.

Other Embodiments The disclosure herein is not limited to the illustrated embodiments. The disclosure encompasses the illustrated embodiments and variations by those skilled in the art based thereon. For example, the disclosure is not limited to the combinations of parts and / or elements shown in the embodiments. The disclosure can be implemented in various combinations. The disclosure may have additional parts that can be added to the embodiments. The disclosure includes those in which parts and / or elements of the embodiments are omitted. The disclosure encompasses the replacement or combination of parts and / or elements between one embodiment and another. The technical scope disclosed is not limited to the description of the embodiments. The several technical scopes disclosed are indicated by the description of the claims, and should be understood to include all modifications within the meaning and scope equivalent to the description of the claims.

  In the above embodiment, the fuel control valve 8 does not include a spring that biases the movable body 20 upward, that is, in the valve closing direction. Alternatively, the fuel control valve 8 may have a spring. The spring may be disposed between the case 10 and the movable body 20 in a compressed state.

  In the above embodiment, the fuel control valve 8 is attached to the tank 3. Alternatively, the fuel control valve 8 may be provided in the fuel vapor passage 7 when the fuel liquid can be returned to the tank 3.

  In the above embodiment, the valve body surface 25 is formed integrally with the movable body 20. Instead of this, the movable body 20 and the valve body surface 25 may be formed as separate members. For example, the valve body surface 25 may be configured to be movable with respect to the movable body 20 by a predetermined movement amount. Such a predetermined movement amount is also called play. The predetermined movement amount contributes to give a hysteresis characteristic to the valve opening characteristic. Moreover, you may form the valve body surface 25 in the elastic member with elasticity.

1 tank system, 2 engine, 3 tank,
4 fuel supply device, 5 fuel vapor purification system,
6 Fuel vapor purification equipment, 7 Fuel vapor passage, 8 Fuel control valve,
10 cases, 11 first cases, 12 second cases,
13 Small diameter part, 14 Large diameter part, 15 Step part,
16 partition wall, 17 cylindrical part, 18 valve seat surface,
20 movable body, 21 body, 22 flange part,
23 Needle part, 24 Float chamber, 25 Valve body surface,
31 outlet passage, 32 outlet opening, 33 valve passage,
34 containment chamber, 35 lower opening,
40 support shape, 41 through hole, 42 annular part,
50 buoyancy adjustment mechanism, 51 subsidence part, 51a first part,
51b second part, 52 floating part, 53 additional sinking part,
54 Additional floating part, 55 Stepped shape,
60 barrier mechanism, 61 barrier, 62 barrier passage,
70 flow rate adjusting mechanism, 71 groove,
253 Additional sinking part, 254 Additional floating part,
353 Additional subsidence part, 354 Additional surfacing part,
AX center axis, FL liquid level, ST moving range,
UP Up, DW Down, D1, D2, D3 Diameter.

Claims (10)

A case (10) providing a passage extending from a tank for storing fuel;
A float that is movably accommodated in the case and floats on a liquid level (FL) of the liquid fuel, and includes a movable body (20) that opens and closes the passage;
The movable body has a subsidence part (51) that sinks from the liquid level in a regular normal posture,
The subsidence portion is
A first portion (51a) having a predetermined diameter (D1) and through which the liquid surface in the normal posture passes;
A fuel control valve having a second portion (51b) positioned below the first portion and having a diameter (D2) equal to or greater than the diameter of the first portion. The subsidence part has an upper surface (21a) connecting the first part and the second part,
2. The fuel control valve according to claim 1, wherein the upper surface is at a position below the liquid level or at the same position as the liquid level regardless of the posture of the movable body.   The fuel control valve according to claim 2, wherein the upper surface is an inclined surface inclined with respect to the vertical direction. The movable body has a floating portion (52) that floats from the liquid surface in the normal posture,
The floating portion has an additional subsidence portion (53, 253, 353) that sinks from the liquid level in addition to the subsidence portion in an inclined posture inclined with respect to the normal posture,
The fuel control according to any one of claims 1 to 3, wherein the subsidence portion has an additional floating portion (54, 254, 354) that floats from the liquid surface in addition to the floating portion in the inclined posture. valve. The floating portion has a flange portion (22) spread outward in the radial direction having a diameter (D3) equal to or larger than the diameter of the first portion,
The fuel control valve according to claim 4, wherein the flange portion provides the additional subsidence portion. A case (10) providing a passage extending from a tank for storing fuel;
A float that is movably accommodated in the case and floats on a liquid level (FL) of the liquid fuel, and includes a movable body (20) that opens and closes the passage;
The movable body is
A subsidence part (51) that sinks from the liquid surface in a normal normal posture;
A floating portion (52) that floats above the liquid level in the normal posture;
The levitation portion has an additional subsidence portion (53, 253, 353) which, in addition to the subsidence portion, sinks from the liquid surface and gives buoyancy to the movable body in an inclined posture inclined with respect to the normal posture. ,
The subsidence part has an additional floating part (54, 254, 354) that is added to the floating part and gives a weight against the buoyancy of the movable body in addition to the floating part in the inclined posture,
The said movable body is a fuel control valve which has an adjustment shape (21a, 22) which adjusts the buoyancy provided by the said additional subsidence part, and the weight provided by the said additional floating part.   The fuel control valve according to claim 6, wherein the adjustment shape adjusts a buoyancy provided by the additional subsidence portion to be greater than a weight provided by the additional levitation portion.   The fuel control valve according to claim 6 or 7, wherein the adjustment shape is a stepped shape (55) provided at a boundary portion between the floating portion and the sinking portion and through which the liquid level passes in the normal posture. .   The fuel control valve according to any one of claims 6 to 8, wherein the adjustment shape has an upper surface (21a) that is provided in the subsidence portion and has an outer diameter that decreases toward the liquid surface in the normal posture.   The fuel control valve according to any one of claims 6 to 9, wherein the adjustment shape is positioned on the floating portion, extends radially outward, and has a flange portion (22) that provides the additional subsidence portion. .

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