JP2016159909A - Tank - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fuel tank capable of preventing looseness of a cap while suppressing an increase in the number of components.SOLUTION: A fuel tank 1 comprises: a projection part 7 which is provided at a position different from a male screw part 4 of an outer peripheral part of a neck part 3 of a tank body 2, and projects outward in a radial direction of the neck part 3; and a plate spring 20 having a projection 22 which is fixed at a position different from a female screw part 14 of an inner peripheral part of a cap 10, and projects inward in a radial direction of the cap 10. The projection 22 rides over the projection part 7 when the cap 10 is rotated in a fastening direction D and screwed to the neck part 3. The projection part 7 restricts rotation in an opposite direction from the fastening direction D of the cap 10 by coming into contact with the projection 22.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a tank provided with a screw-in type cap.

  As such a technique, for example, a container described in Patent Document 1 is known. This container for storing kerosene is provided with an oil supply port for supplying oil to the container and an injection nozzle for supplying oil from the container to the combustion device at the top of the container main body. A screw-in type cap is attached to each of the oil supply port and the tip of the injection nozzle. The container is provided with a band-shaped connecting band for holding the cap, and a ring-shaped portion at the center is attached to the fuel filler opening, and two ring-shaped portions connected to both sides via the band are provided. The two caps are respectively fitted. Thus, the cap is prevented from being lost by holding the cap with the connecting band attached to the container body.

Japanese Utility Model Publication No. 61-14611

  FIG. 9 shows a fuel tank 100 in which a structure similar to the above-described cap holding structure is employed. The tank body 101 has a cylindrical neck portion 101a for injecting fuel, and a fuel supply port 103 is provided at the tip of the neck portion 101a. A female screw is formed on the inner peripheral portion of the cap 102 attached to the oil filler port 103, and a male screw is formed on the outer peripheral portion of the neck portion 101a. The operator grips the outer periphery of the cap 102 and turns the cap 102 to screw and fix the cap 102 to the neck portion 101 a of the tank body 101.

  The fuel tank 100 is provided with a retainer 104 for preventing the cap 102 from falling off. The retainer 104 has a structure in which a ring-shaped first plate 105 and a ring-shaped second plate 106 are connected by a connecting band 107 having a predetermined length. The first plate 105 is mounted so as to be caught by the male screw of the neck portion 101 a, and the second plate 106 is mounted on the lower end of the outer peripheral portion of the cap 102. When the cap 102 is removed from the tank body 101, the cap 102 is held by the retainer 104, and the cap 102 is prevented from falling off.

  The first plate 105 is rotatably attached to the neck portion 101a, and the second plate 106 is rotatably attached to the cap 102. Therefore, there is no function to prevent the cap 102 from loosening when the cap 102 is attached. Therefore, an object of the present invention is to provide a fuel tank that can prevent the cap from loosening while suppressing an increase in the number of parts.

  According to the present invention, a male thread part (4) is formed on the outer peripheral part of the cylindrical neck part (3) of the tank body (2), and a female thread part (14) is formed on the inner peripheral part of the cap (10). In the tank (1, 1A) which closes the opening (3a) formed at the tip of the neck (3) by screwing (10) into the neck (3) and fixing it, the external thread portion of the outer periphery of the neck (3) The protrusion (7, 7A) provided at a position different from (4) and protruding radially outward of the neck (3) is different from the female thread (14) of the inner periphery of the cap (10). A leaf spring (20) fixed in position and having a protrusion (22) projecting radially inward of the cap (10), and the cap (10) is rotated in the tightening direction (D) and the neck ( When the screw is screwed into 3), the protrusion (22) abuts the protrusion (7, 7A) and By applying a screwing force to the cap (10), it is possible to get over the protrusion (7, 7A), and the protrusion (7, 7A) contacts the protrusion (22) from the direction opposite to the tightening direction (D). By doing so, the rotation in the reverse direction is restricted.

  In this tank (1, 1A), when the cap (10) is screwed into the neck (3), the protrusion (22) of the cap (10) is projected to the protrusion (7, 7A) provided on the neck (3). Abut. At this time, when a screwing force is further applied to the cap (10), the protrusion (22) receives a reaction force from the protrusions (7, 7A) and moves in the outer peripheral direction by the elasticity of the leaf spring (20). 7,7A) is overcome in the tightening direction (D). Thereby, the cap (10) can be screwed in until the opening (3a) is closed and fixed to the neck (3). When the cap (10) is loosened in the direction opposite to the tightening direction (D) from the state in which the protrusion (22) gets over the protruding portion (7, 7A), the protrusion (22) is moved from the opposite direction. It will contact | abut to a protrusion part (7, 7A), and the rotation to the said reverse direction, ie, loosening direction, of a cap (10) is controlled. This prevents the cap (10) from being loosened or dropped off. Further, since the projecting portion (7, 7A) is provided on the neck portion (3) and the leaf spring (20) is provided on the cap (10), an increase in the number of parts is suppressed. When the protrusion (22) gets over the protrusion (7, 7A) due to the elasticity of the leaf spring (20), the threaded state of the male thread (4) of the neck (3) and the female thread (14) of the cap (10) There is no such thing as shifting, and the tightening operation can be performed without any trouble.

  The leaf spring (20) has an arc shape, and when the leaf spring (20) is in a free state, the outer diameter of the leaf spring (20) is an arc shape leaf spring formed on the inner peripheral portion of the cap (10). The leaf spring (20) is deformed and accommodated in the leaf spring accommodating portion (16), and is fixed by its urging force. By utilizing the urging force of the leaf spring (20) itself, the leaf spring (20) can be easily attached, and another component for fixing is unnecessary.

  The leaf spring (20) has hook portions (23) provided at both ends of the arcuate body portion (21) and extending radially inward of the body portion (21). An engagement portion (18) that engages with the hook portion (23) is provided on the inner peripheral portion, and the leaf spring (20) is engaged by the engagement between the hook portion (23) and the engagement portion (18). Is not allowed to rotate relative to the cap (10). According to this structure, since the hook part (23) of a leaf | plate spring (20) engages with an engaging part (18), a leaf | plate spring (20) becomes non-rotatable with respect to a cap (10), The leaf spring (20) can be fixed with a simple configuration.

  The protrusions (7, 7A) are provided at positions where they come into contact with the protrusions (22) in a state where the cap (10) is separated from the seal surface (3b) provided at the tip of the neck (3). According to this configuration, the cap (10) is prevented from rotating in the loosening direction while the cap (10) is being separated from the seal surface (3b), and the cap (10) is prevented from falling off. The Before the tightening of the cap (10) was completed, the cap (10) was easy to drop off, so this configuration is effective for preventing the cap (10) from falling off during the tightening. In this state, since the opening (3a) of the neck (3) is not completely closed by the cap (10), the passage through which gas such as air inside the tank (1, 1A) passes is the cap (10). It is formed between the necks (3) and can also function as a vent.

  The protrusion (7) has a first inclined surface (7a) that contacts when the protrusion (22) moves in the tightening direction (D), and the protrusion (22) moves in a direction opposite to the tightening direction (D). The second inclined surface (7b) is in contact with the second inclined surface (7b), and the inclined angle (θ2) of the second inclined surface (7b) is the first inclined surface with respect to the tangent at the position where the protruding portion (7) is provided. It is larger than the inclination angle (θ1) of (7a). According to this configuration, when the cap (10) is rotated in the tightening direction (D), the protrusion (22) easily gets over the protrusion (7), and the resistance by the protrusion (7) is relatively low. small. On the other hand, when the cap (10) tries to rotate in the loosening direction, the protrusion (22) is difficult to get over the protrusion (7), and the resistance by the protrusion (7) is relatively large. In this way, the tightening operation is not hindered, while the effect of preventing loosening is enhanced.

  A plurality of protrusions (7) are provided so as to be aligned in the circumferential direction of the outer peripheral portion of the neck (3). According to this configuration, when the cap (10) is tightened, the protrusion (22) continuously gets over the plurality of protrusions (7). As a result, the effect of preventing loosening and preventing falling off is enhanced. In addition, because of the elasticity of the leaf spring (20), a click feeling is transmitted to the hand tightening the cap (10), and a sound like a ratchet mechanism is continuously generated, so that the tightening condition of the cap (10) is better sensed. it can.

  According to the present invention, loosening of the cap (10) can be prevented while suppressing an increase in the number of parts.

It is a perspective view which shows the tank which concerns on one Embodiment of this invention. It is sectional drawing which follows the axis line of the neck part in FIG. It is sectional drawing in the state where the cap was fixed. It is a perspective view which shows the leaf | plate spring shown by FIG.2 and FIG.3. It is a perspective view which shows the neck part of a tank main body. It is sectional drawing which follows the VI-VI line of FIG. It is sectional drawing which expands and shows a part of FIG. It is sectional drawing in other embodiment, and is a figure corresponding to FIG. It is a perspective view which shows the conventional tank provided with the retainer for prevention of drop-off of a cap.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant descriptions are omitted.

  With reference to FIG. 1 and FIG. 2, the fuel tank 1 which is the tank which concerns on one Embodiment is demonstrated. As shown in FIG. 1, the fuel tank 1 is a tank used for general-purpose engine products such as a brush cutter, a hedge trimmer, or a power sprayer. The fuel tank 1 includes a tank main body 2 that is a container for storing fuel, and a cap 10 that is attached to the neck 3 of the tank main body 2. The tank body 2 stores fuel such as gasoline. The neck 3 extends obliquely upward from the fuel storage space in the tank body 2. A circular fueling port 3a is formed at the upper end of the neck portion 3, and fuel is supplied into the tank body 2 through the fueling port 3a.

  The cap 10 includes a cylindrical portion 11 that is screwed around the neck portion 3, and a disc portion 12 that is connected to the upper surface of the cylindrical portion 11 and closes the oil supply port 3 a. The outer peripheral portion of the cylindrical portion 11 is gripped by an operator when the cap 10 is attached and detached.

  As shown in FIGS. 1 and 2, a male screw portion 4 is formed on the outer peripheral portion of the cylindrical neck portion 3 of the tank body 2. On the other hand, an internal thread portion 14 is formed on the inner peripheral portion of the cylindrical portion 11 of the cap 10. The neck portion 3 is arranged so that the axis L of the neck portion 3 is at the center, and the cap 10 is screwed into the neck portion 3, whereby the cap 10 is fixed. Thus, the cap 10 is a so-called screw cap. The disc portion 12 of the cap 10 faces the annular seal surface 3 b that is the upper end surface of the neck portion 3. An annular packing 19 is disposed on the back surface side of the disc portion 12. When the cap 10 is tightened and the disc portion 12 is seated on the seal surface 3b, the oil filler 3a is closed by the cap 10 and the packing 19, and the sealing function is exhibited (see FIG. 3).

  In the fuel tank 1 of the present embodiment, the cap 10 is prevented from loosening and falling off. That is, in the fuel tank 1, the mounting structure X of the cap 10 that does not require the conventional retainer 104 (see FIG. 9) or the like is applied. Hereinafter, the attachment structure X of the cap 10 applied to the fuel tank 1 will be described with reference to FIGS.

  As shown in FIG. 2, an arcuate leaf spring accommodating portion 16 that is recessed in the radial direction is formed at the lower end portion of the cylindrical portion 11 of the cap 10. More specifically, the leaf spring accommodating portion 16 is formed in a groove shape between the female screw portion 14 and the open end portion 11 a of the cylindrical portion 11. The leaf spring accommodating portion 16 is located immediately above the opening end portion 11a. As described above, the leaf spring accommodating portion 16 is formed at a position different from the internal thread portion 14.

  As shown in FIG. 6, a plurality of (two in the example shown in FIG. 6) projections 17 projecting radially inward and two projecting radially inward are formed on the inner peripheral surface of the cylindrical portion 11. An engaging portion 18 is provided. The protrusions 17 and the engaging portions 18 are disposed in the leaf spring accommodating portion 16. The leaf spring accommodating portion 16 is formed in an arcuate region excluding the region where the two engaging portions 18 are provided in the circumferential direction. The protrusion 17 has, for example, a semi-cylindrical shape. The engaging portion 18 has a wall surface extending in the radial direction and the axis L direction.

  As shown in FIGS. 2 to 3, a leaf spring 20 having an arc shape (that is, an arch shape) is accommodated in the leaf spring accommodating portion 16 of the cap 10. The leaf spring 20 is made of a steel material having elasticity. The leaf spring 20 has an arcuate body portion 21 corresponding to the leaf spring accommodating portion 16 and two hook portions 23 provided at both ends of the body portion 21. The main body portion 21 and the hook portion 23 are plate materials having a thickness in the radial direction with respect to the axis L, and are formed, for example, by bending a single long plate material. The main body portion 21 and the hook portion 23 have a certain width (height) in the axis L direction.

  The main body 21 has an opening 21a (see FIG. 4) in a part in the circumferential direction. The two engaging portions 18 of the cap 10 described above are disposed in the opening 21a. The hook portion 23 extends linearly inward in the radial direction. In other words, the hook portion 23 is bent at a substantially right angle with respect to the longitudinal direction of the main body portion 21 that is a spring material.

  As shown in FIGS. 4 and 6, a single protrusion 22 that protrudes radially inward is provided at the center of the main body 21. The protrusion 22 has a mountain shape. The protrusion 22 includes a downstream slope 22a and an upstream slope 22b with reference to the tightening direction D of the cap 10. A top portion 22c is formed between the downstream side slope 22a and the upstream side slope 22b. The top portion 22c extends in parallel with the axis L direction. The shapes of the downstream side slope 22a and the upstream side slope 22b are substantially symmetric with respect to a plane that passes through the top portion 22c and extends in the radial direction. It should be noted that the position where the protrusion 22 is provided may be in the central portion of the main body portion 21 or near one of the hook portions 23. The protrusion 22 may have a shape different from the mountain shape. A plurality of protrusions 22 may be provided at different positions in the circumferential direction.

  The outer diameter of the leaf spring 20 is larger than the inner diameter of the leaf spring accommodating portion 16 in the free state. The outer diameter of the leaf spring 20 is larger than the inner diameter of the bottom portion of the groove-like leaf spring accommodating portion 16, and is larger than the diameter of a virtual circle connecting the top portions of the plurality of protrusions 17. The leaf spring 20 is housed in the leaf spring housing portion 16 in a contracted state, that is, in a state in which the leaf spring 20 is deformed in a direction in which the opening 21a is narrowed. The leaf spring 20 is fixed in the leaf spring accommodating portion 16 by an urging force of the leaf spring 20 itself (a force to spread in a free state). In the present embodiment, the plurality of protrusions 17 are in contact with the main body portion 21 of the leaf spring 20. Therefore, an arc-shaped gap is formed between the main body portion 21 and the bottom portion of the leaf spring accommodating portion 16 in the region where the protrusion 17 is provided.

  Further, the two hook portions 23 of the leaf spring 20 are pressed against the circumferential side surface of the engaging portion 18. The hook portion 23 is engaged with the engaging portion 18 by the urging force of the leaf spring 20. The leaf spring 20 is not rotatable with respect to the cap 10 by the engagement of the hook portion 23 and the engaging portion 18.

  As described above, the cap 10 to which the leaf spring 20 is fixed includes the protrusion 22 that protrudes inward in the radial direction at a position different from the internally threaded portion 14. The protrusion 22 is provided between the female screw portion 14 and the opening end portion 11a.

  As shown in FIGS. 2 and 5, the base portion of the neck portion 3 of the tank body 2 is provided with a plurality of protruding portions 7 that protrude outward in the radial direction. More specifically, the plurality of protruding portions 7 are provided so as to be arranged at equal intervals in the circumferential direction of the outer peripheral portion of the neck portion 3. For example, about 10 to 20 protrusions 7 are provided, and are formed in a wavy shape below the male screw portion 4. Each protrusion 7 has the same shape and size, for example. The plurality of protrusions 7 constitute a wave-like protrusion 6. As described above, the plurality of protrusions 7 (that is, the wave-like protrusions 6 constituted by these) are provided at positions different from the male screw part 4. The corrugated protrusion 6 is integrally formed with, for example, the neck 3 when the tank body 2 is formed.

  As shown in FIG. 7, each protrusion 7 has a mountain shape. The protrusion 7 includes a first inclined surface 7a directed upstream and a second inclined surface 7b directed downstream based on the tightening direction D of the cap 10. A top portion 7c is formed between the first inclined surface 7a and the second inclined surface 7b. The top portion 7c extends in parallel to the axis L direction. A trough 7d is formed between the adjacent protrusions 7 and 7. The shapes of the first inclined surface 7a and the second inclined surface 7b are asymmetric with respect to a plane that passes through the top portion 7c and extends along the radial direction. More specifically, the first inclined surface 7a forms an acute first inclination angle θ1 with respect to the tangential direction passing through the lowest end of the first inclined surface 7a, and the second inclined surface 7b is the second inclined surface. An acute second inclination angle θ2 is formed with respect to a tangential direction passing through the lowest end of 7b. The second inclination angle θ2 is larger than the first inclination angle θ1.

  When the neck 3 is arranged so that the axis L of the neck 3 is centered and the cap 10 is rotated in the tightening direction D and screwed into the neck 3, the protrusion 22 moves in the tightening direction D. At this time, the downstream slope 22 a of the protrusion 22 abuts on the first inclined surface 7 a of each protrusion 7 of the wave-like protrusion 6. By applying a rotational force (that is, screwing force) in the tightening direction D to the cap 10, the top portion 22 c of the protrusion 22 can get over the top portion 7 c of the protruding portion 7. When the protrusion 22 gets over the protrusion 7, a click feeling is transmitted to the hand of the operator holding the cap 10. Further, since the plurality of protruding portions 7 are formed at equal intervals, a sound similar to that of the ratchet mechanism is generated with the rotation of the cap 10.

  Further, when the cap 10 is rotated in the direction opposite to the tightening direction D, that is, in the loosening direction, the protrusion 22 moves in the loosening direction. At this time, the upstream inclined surface 22 b of the protrusion 22 contacts the second inclined surface 7 b of each protrusion 7 of the wave-like protrusion 6. When a rotational force in the loosening direction is applied to the cap 10, the top 22 c of the protrusion 22 gets over the top 7 c of the protrusion 7. At this time, since the second inclination angle θ2 of the second inclined surface 7b is large (a steep inclination), the rotational force is larger than when the cap 10 is rotated in the tightening direction D. In other words, the resistance when the top 22c gets over the top 7c is increased. In other words, according to the wavy protrusion 6, the loosening torque is larger than the tightening torque. The click feeling and the ratchet sound described above are the same as when the cap 10 is rotated in the tightening direction D.

  As described above, the wavy protrusion 6 provided on the neck 3 can be latched with the protrusion 22 of the leaf spring 20 fixed to the cap 10. Once the protrusion 22 of the leaf spring 20 gets over the protrusion 7, the wavy protrusion 6 enters and fits into the valley 7 d due to the elasticity of the leaf spring 20. Then, the protrusion 7 is brought into contact with the protrusion 22, whereby the rotation of the cap 10 in the loosening direction is restricted. This prevents the cap 10 from falling off or loosening.

  With reference to FIG. 2 and FIG. 3, the height in which the wavelike protrusion part 6 is provided is demonstrated. The wavy protrusions 6, that is, the plurality of protrusions 7, are fitted into the protrusions 22 in a state where the disk portion 12 of the cap 10 is separated from the seal surface 3 b at the tip of the neck 3 (that is, in the middle of tightening). Is provided. In other words, the length from the sealing surface 3 b to the wave-like protrusion 6 is shorter than the length from the back surface of the disc portion 12 to the leaf spring 20. As a result, the protrusion 22 comes into contact with the corrugated protrusion 6 in a state in which the female thread portion 14 of the cap 10 starts to be screwed into the male thread portion 4 of the neck 3 but the tightening is not completed, thereby preventing the corrugated protrusion 6 from coming off. Function is demonstrated.

  In a state where the tightening of the cap 10 is not completed, a slight gap is formed between the cap 10 and the neck portion 3. This gap can function as a vent (that is, an air passage) for introducing air into the tank body 2 when the fuel in the tank body 2 decreases.

  The wavy protrusion 6, that is, the plurality of protrusions 7, is configured so that the disk portion 12 of the cap 10 does not fit the protrusion 22 in a state where the disc portion 12 is seated on the seal surface 3 b at the tip of the neck 3 via the packing 19. Can do. In other words, the length from the sealing surface 3 b to the lower end of the wave-like protrusion 6 can be made shorter than the length from the back surface of the disc portion 12 to the upper end of the leaf spring 20. In this case, in a state where the tightening of the cap 10 is completed, that is, in a state where the sealing and sealing properties by the cap 10 are exhibited, the protrusion 22 is positioned below the wave-like protrusion 6, and these fitting states are It has been released. In addition, the length from the sealing surface 3b to the lower end of the wavy protrusion 6 may be equal to or longer than the length from the back surface of the disc portion 12 to the upper end of the leaf spring 20. In that case, even when the tightening of the cap 10 is completed, the protrusion 22 is fitted to the wave-like protrusion 6.

  In the tank 1 of the present embodiment, when the cap 10 is screwed into the neck portion 3, the protrusion 22 of the cap 10 comes into contact with the protruding portion 7 provided on the neck portion 3. When a screwing force is further applied to the cap 10, the protrusion 22 receives a reaction force from the protruding portion 7 and moves in the outer peripheral direction by the elasticity of the leaf spring 20, and gets over the protruding portion 7 in the tightening direction D. Thereby, the cap 10 is screwed in until the fuel filler opening 3a is closed, and is fixed to the neck portion 3. On the other hand, when the cap 10 is loosened in the direction opposite to the tightening direction D from the state in which the protrusion 22 gets over the protruding portion 7, the protrusion 22 comes into contact with the protruding portion 7 from the opposite direction, and the cap 10 The rotation in the reverse direction, that is, the loosening direction is restricted. Thereby, the cap 10 is prevented from being loosened or dropped off. Since the projecting portion 7 is provided on the neck portion 3 and the leaf spring 20 is provided on the cap 10, an increase in the number of components is suppressed. Due to the elasticity of the leaf spring 20, when the protrusion 22 gets over the protruding portion 7, the screwed state of the male screw portion 4 of the neck portion 3 and the female screw portion of the cap 10 is not shifted, and the tightening operation can be performed without any trouble. . Moreover, when the protrusion 22 gets over the protrusion 7, a sound like a ratchet mechanism is generated, and the operator can sense the tightening condition of the cap 10. In the conventional configuration in which the retainer 104 is used (see FIG. 9), since the second plate 106 is mounted on the outer periphery of the cap 102, the second plate 106 tends to interfere with the hand of the operator. The grip of 102 was easily disturbed. On the other hand, in the fuel tank 1, the gripping of the cap 10 is not hindered, and thus the tightening torque of the cap 10 is easily increased. As a result, the cap 10 is difficult to loosen. In addition, in order to make it easy to hold | grip the cap 10, the structure which enlarges the grip part of the cap 10 can be considered, but in that case, it will lead to an increase in weight. According to the fuel tank 1 of the present embodiment, the cap 10 is prevented from loosening and falling off with a simple configuration without significantly increasing the weight.

  In the fuel tank 1, prevention of looseness and prevention of falling off are achieved at the same time by the leaf spring 20 which is a single component. Since the leaf spring 20 is fixed inside the cap 10, it does not adversely affect the gripping of the cap 10. Moreover, in the attachment structure X, there is no cost increase compared with the past.

  By utilizing the urging force of the leaf spring 20 itself, the leaf spring 20 is easily attached, and another component for fixing is unnecessary.

  Since the hook portion 23 of the leaf spring 20 is engaged with the engaging portion 18, the leaf spring 20 is not rotatable with respect to the cap 10, and thus the leaf spring 20 is fixed with a simple configuration.

  Further, in the middle of tightening in which the disc portion 12 of the cap 10 is separated from the seal surface 3b, the cap 10 is prevented from rotating in the loosening direction, and the cap 10 is prevented from falling off. Usually, until the tightening of the cap 10 is completed, the cap 10 is likely to fall off. The attachment structure X of the fuel tank 1 is effective for preventing the cap 10 from falling off during tightening. Further, in this state, the oil filler port 3a of the neck 3 is not completely closed by the cap 10, so that a passage through which a gas such as air inside the tank passes is formed between the cap 10 and the neck 3 as a vent. Can be obtained.

  Since the second inclination angle θ2 is larger than the first inclination angle θ1, when the cap 10 is rotated in the tightening direction D, the protrusion 22 can easily get over the protrusion 7 and the resistance by the protrusion 7 is increased. Is relatively small. On the other hand, when the cap 10 is about to rotate in the loosening direction, the protrusion 22 is difficult to get over the protrusion 7, and the resistance by the protrusion 7 is relatively large. Therefore, the tightening operation of the cap 10 is not hindered, while the effect of preventing the cap 10 from being loosened is enhanced.

  According to the wavy protrusion 6, when the cap 10 is tightened, the protrusion 22 continuously gets over the plurality of protrusions 7. Thereby, the effect of preventing the cap 10 from loosening and preventing the cap 10 from falling off is enhanced. Further, because of the elasticity of the leaf spring 20, a click feeling is transmitted to the hand tightening the cap 10, and a sound like a ratchet mechanism is continuously generated, so that the operator can better sense the tightening condition of the cap 10.

  A fuel tank 1A according to another embodiment will be described with reference to FIG. The neck 3 of the fuel tank 1A shown in FIG. 8 does not have the wavy protrusion 6 but has one protrusion 7A. The protrusion 7A is rounded in a cross section perpendicular to the axis L. 7 A of protrusion parts are larger than each protrusion part 7 of the wavelike protrusion part 6. FIG. The radial position and the protruding length of the protruding portion 7 </ b> A are substantially the same as the protruding portions 7 of the wavy protruding portion 6. In the fuel tank 1A provided with such a protruding portion 7A, the cap 10 can be prevented from being loosened and prevented from falling off as described above. Before the tightening of the cap 10 is completed, the protrusion 22 is engaged with the protrusion 7A, whereby a vent function is obtained.

  Although the embodiment of the present invention has been described, the present invention is not limited to the above embodiment. The structure of the protrusion part 7 is not restricted to the above-mentioned wavelike protrusion part 6 and protrusion part 7A. For example, a triangular or rectangular protrusion may be employed. A dome-shaped protrusion may be employed. The configuration of the leaf spring is not limited to the leaf spring 20 described above. The leaf spring 20 is not limited to an arch shape with a central angle of 180 degrees or more, but may have an arch shape with a central angle of less than 180 degrees. The protrusion 22 is not limited to being formed by bending the main body portion 21, and another member may be joined to the inner peripheral surface of the main body portion 21 by welding or adhesion. It is not restricted to the aspect in which the leaf | plate spring 20 is provided with the hook part 23, The both ends of the main-body part 21 may be fixed to the inner peripheral part of the cylindrical part 11 by another method. The first inclination angle θ1 and the second inclination angle θ2 may be substantially equal.

  Further, in the above-described embodiment, the embodiment in which the retainer 104 (see FIG. 9) is not provided has been described. However, the retainer 104 may be used in combination after the attachment structure X is applied. It is needless to say that the embodiment in which the retainer 104 is used in combination is also included in the technical scope of the present invention as long as the tank has the constituent elements described in the claims.

  Although the case where the present invention is applied to the fuel tank 1 has been described in the above embodiment, the present invention is not limited to this. The present invention can also be applied to, for example, a drug tank that stores liquid, powder, granules, and the like. The tank is not limited to a tank applied to a farm machine, and may be applied to a tank for other purposes including a screw-in type cap.

  DESCRIPTION OF SYMBOLS 1 ... Fuel tank (tank), 2 ... Tank main body, 3 ... Neck part, 3a ... Filling opening (opening), 3b ... Sealing surface, 4 ... Male thread part, 6 ... Wave-like protrusion part, 7 ... Projection part, 7a ... 1st Inclined surface, 7b ... second inclined surface, 10 ... cap, 14 ... internal thread portion, 16 ... leaf spring accommodating portion, 18 ... engaging portion, 20 ... leaf spring, 21 ... main body portion, 22 ... projection, 23 ... hook portion , L... Axis (of neck 3), X... Mounting structure (of cap 10), .theta.1 .first inclination angle, .theta.2 .second inclination angle.

Claims (6)

A male screw part (4) is formed on the outer peripheral part of the cylindrical neck part (3) of the tank body (2), and a female screw part (14) is formed on the inner peripheral part of the cap (10). In the tank (1, 1A) that closes the opening (3a) formed at the tip of the neck (3) by screwing and fixing it to the neck (3),
Protruding portions (7, 7A) provided at positions different from the male screw portion (4) on the outer peripheral portion of the neck portion (3) and projecting radially outward of the neck portion (3);
A leaf spring (20) having a protrusion (22) that is fixed in a position different from the female thread portion (14) on the inner peripheral portion of the cap (10) and projects radially inward of the cap (10); With
When the cap (10) is rotated in the tightening direction (D) and screwed into the neck (3), the protrusion (22) abuts against the protrusion (7, 7A) and is attached to the cap (10). By applying a screwing force, the protrusion (7, 7A) can be overcome, and the protrusion (7, 7A) is brought into contact with the protrusion (22) from a direction opposite to the tightening direction (D). The tank is characterized by restricting the rotation in the reverse direction. The leaf spring (20) has an arc shape, and in the free state of the leaf spring (20), the outer diameter of the leaf spring (20) is a circle formed on the inner peripheral portion of the cap (10). It is larger than the inner diameter of the arc-shaped leaf spring accommodating portion (16),
The tank according to claim 1, wherein the leaf spring (20) is deformed and accommodated in the leaf spring accommodating portion (16), and is fixed by an urging force thereof. The leaf spring (20) has hook portions (23) provided at both ends of a main body portion (21) extending in an arc shape and extending radially inward of the main body portion (21),
An engagement portion (18) that engages with the hook portion (23) is provided on the inner peripheral portion of the cap (10),
2. The leaf spring (20) cannot be rotated relative to the cap (10) by the engagement between the hook portion (23) and the engagement portion (18). Or the tank of 2.   The protrusions (7, 7A) are provided at positions where they abut against the protrusions (22) in a state where the cap (10) is separated from a seal surface (3b) provided at the tip of the neck (3). The tank according to any one of claims 1 to 3, wherein the tank is provided. The protrusion (7) includes a first inclined surface (7a) that contacts when the protrusion (22) moves in the tightening direction (D), and the protrusion (22) is defined as the tightening direction (D). A second inclined surface (7b) that contacts when moving in the opposite direction,
The inclination angle (θ2) of the second inclined surface (7b) is larger than the inclination angle (θ1) of the first inclined surface (7a) with respect to the tangent at the position where the protrusion (7) is provided. The tank according to claim 1, wherein the tank is a tank.   The said protrusion part (7) is provided with two or more so that it may rank in the circumferential direction of the outer peripheral part of the said neck part (3), The tank as described in any one of Claims 1-5 characterized by the above-mentioned.

Images