JP2013233981A - Cap structure of urea water tank - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cap structure of an urea water tank in which urea is replenished to an urea water tank even though the replenishing nozzle of an urea water can't directly reach a replenishing port of the urea water tank due to the shape of a rack device, and which especially can be used preferably to the urea water tank already disposed in a vehicle.SOLUTION: The cap structure of an urea water tank includes a cap 8 that is engaged with or detached from a replenishing port 31 in an urea water tank 3, a hose 5 which is inserted into the replenishing port 31 and formed with an elastically deformable material, a first flange part 52 at one end of the hose 5 that prevents passing through in the tank inside direction, a second flange part at another end of the hose 5 whose diameter can be reduced and that can be deformed if the urea water passes through the replenishing port 31 and is engaged with the replenishing port 31 after the diameter returns to a normal state in a free condition after the passage of the urea water, and an engaging and releasing mechanism that is provided in the cap 8 and has an operation part where engaging and releasing with/from the cap 8 and the first flange part 52 are performed.

Description

  The present invention relates to a cap structure for a replenishment port of a urea water tank that stores urea water used as a reducing agent for a purification device that purifies exhaust gas discharged from an automobile or the like.

In recent years, urea water has come to be used as a reducing agent for exhaust gas purification devices that purify NOx contained in exhaust gas discharged from internal combustion engines (diesel engines) such as trucks. Such urea water is mounted on the vehicle in a state of being stored in a urea water tank that stores urea water.
As a technique for purifying NOx contained in exhaust gas, means using NOx storage catalyst and HC (fuel) as a reducing agent has been implemented, but recently, urea water can be used as described above. It has become the main means.

Under such circumstances, in the vehicle space design stage, priority is given to the arrangement of fuel tanks mounted on the vehicle, air tanks used for brakes, suspensions, etc., and the arrangement of urea water tanks In most cases, it is determined after these.
For this reason, for example, in a vehicle such as a truck, the vehicle is shipped from a vehicle manufacturer to a bodywork device manufacturer in a so-called chassis with cab in which a driver's seat is mounted on a chassis.
The manufacturer of the body mounting device mounts the body mounting device on the chassis, but the shape of the body mounting device cannot be changed due to the performance of the body mounting device, and sacrifices the ease of supplying urea water to the urea water tank. There is a case.

This is especially the case with short wheel-based vehicles such as small trucks.
For example, in the case of the truck 01 shown in FIG. 8 and the like and the mounting device 02 mounted on the frame 021 has the shape as shown in FIG. 8, that is, above the supply port 031 of the urea water tank 03. When the bodywork device 02 is overhanging, the replenishment nozzle 032 may contact the outer corner portion Z of the bodywork device 02 and the replenishment nozzle 032 may be directly inserted into the replenishment port 031 of the urea water tank 03. There is a situation that cannot be done.

Japanese Utility Model Publication No. 03-108634 Japanese Utility Model Publication No. 04-10091

As prior art relating to a water tank and a fuel tank mounted on a vehicle, there are Patent Documents 1 and 2, but these Patent Documents 1 and 2 are not applicable to tanks already installed in a vehicle.
Furthermore, Patent Document 1 describes a case where water can be supplied without using a bellows-like flexible tube when a bodywork device is mounted on a chassis with a cab-mounted chassis carried from a vehicle manufacturer to a bodybuilder. In this case, a flexible tube is not necessary, and there is a problem in that wasteful cost increases.

  Further, in Patent Document 2, the shape of the fuel tank must be changed depending on the shape of the bodywork device, and there is a problem that the types of fuel tanks increase and the cost increases.

  The present invention has been made in view of the above-described problems of the prior art, and even when the urea water replenishing nozzle does not reach the urea water tank replenishing port directly due to the shape of the bodywork device, the urea water tank is not filled with urea. An object of the present invention is to provide a urea water tank cap structure that can be easily replenished, and that can be suitably applied to a urea water tank that is already installed in a vehicle.

In order to achieve the above object, according to the present invention, in the cap structure of the urea water tank,
A cap detachable from the supply port of the urea water tank;
A hose formed of a material that can be elastically deformed and configured to be insertable into the replenishment port,
A first flange portion provided at one end of the hose to prevent the one end from passing inward of the urea water tank;
Provided at the other end of the hose, and when the other end passes through the supply port when the other end passes through the supply port, the other end is deformable and the other end is the supply. A second flange portion configured to be capable of expanding and deforming in a free state after passing through the mouth and preventing the other end from passing through the outside of the urea water tank;
And an engagement / disengagement device provided with an operation portion for engaging / disengaging the cap and the first flange portion.

According to the present invention, when replenishing the tank with fuel or urea water mounted on the lower side of a bodywork device such as a truck, the refill gun may reach the replenishment port of the urea water tank depending on the shape of the bodywork device. In this case, the other end of the hose is reduced in diameter and inserted into the replenishing port so that it expands in the tank, preventing the other end from passing outside the tank. The engaged hose is pulled out, the cap is removed from the hose, and replenishment with a replenishing gun becomes possible, and since the hose diameter and cap are provided with a hose engaging / disengaging device, it is already installed in the vehicle. It can be suitably applied to a urea water tank.
Furthermore, the urea water can be replenished only by replacing the cap with a hose, and the urea water tank does not need to be replaced, so that the cost can be reduced.

  In the present invention, preferably, the second flange portion is provided with a cut along the axial direction of the hose, and the end edge of the cut is superposed and deformed in the circumferential direction to reduce the diameter.

  With such a configuration, the hose is formed of a material that can be elastically deformed, so the second flange portion is radially reduced in diameter and inserted into the tank from the replenishing port. By expanding the diameter in the tank (when free), it is possible to prevent the second flange portion from engaging with the replenishing port and the second flange portion from passing outside the urea water tank, and to facilitate replenishment work. Can be achieved.

Preferably, in the present invention, the engagement / disengagement device includes the operation portion and an engagement piece that is engaged with the operation portion and engages / disengages with the first flange portion,
It is preferable that the engagement between the first flange portion and the engagement piece is released along with the operation of the operation portion.

  By adopting such a configuration, if the engagement piece does not operate the operation portion, the engagement between the first flange portion and the engagement piece is not released, so the cap is removed from the supply port, and the hose is pulled out together. And replenishment work becomes easier.

  In the present invention, preferably, the engaging / disengaging device is configured such that when the cap is pressed against the first flange portion in the axial direction, the engagement piece expands in a radial direction of the first flange portion. When passing through the first flange portion, the first flange portion and the engagement piece may be engaged by the biasing force of the elastic member.

  By adopting such a configuration, the engagement piece expands in the radial direction of the first flange portion simply by pressing the cap on the first flange portion in the axial direction of the hose. By simply pressing the cap against the first flange portion, the hose and the cap can be coupled, and the operation can be facilitated.

  Preferably, in the present invention, a stopper member formed in a tubular shape with a material that is elastically deformable that is equal to or longer than the axial length is provided on the outer periphery of the cut of the second flange portion in the axial direction. It is good that it is fitted externally.

  With this configuration, when inserting the second flange into the oil filler port, a notch is provided to reduce the diameter, but by providing a stopper member near the second flange, the hose can be removed from the tank. When pulled out, the cut portion can be prevented from being exposed to the outside through the replenishing port, so that the replenisher can be prevented from leaking outside.

  Even if the urea water supply nozzle does not reach the urea water tank supply port directly due to the shape of the bodywork device, urea can be easily supplied to the urea water tank. It has an effect that can be suitably applied to a water tank.

(A) is an installation state explanatory view of a urea water tank in which the present invention is implemented, and (B) is a perspective view of a holder for holding a hose when urea water is replenished. (A) is 1st Embodiment detailed drawing of the hose by which this invention was implemented, (B) shows the top view of a 2nd flange part. (A) is 2nd Embodiment detailed drawing of the hose by which this invention was implemented, (B) is a top view of a 2nd flange part, (C) shows the modification of a 2nd flange. (A) is 3rd Embodiment detailed drawing of the hose by which this invention was implemented, (B) is a top view of a 2nd flange part, (C) shows the perspective view of a tubular stopper member. FIG. 6 shows a detailed view of a fourth embodiment of a cap in which the present invention is implemented. (A) is a detailed view of a fifth embodiment of a cap in which the present invention is implemented, and (B) is a detailed shape diagram of an engagement piece. (A) is an explanatory view of the engagement state of the cap and the first flange, (B) is an explanatory view of a state where the engagement of the cap and the first flange is released, and (C) is an engagement piece of the first flange portion. The state diagram which passes is shown. The attachment state explanatory drawing of the urea water tank by a prior art is shown.

(First embodiment)
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described in this embodiment are not intended to limit the scope of the present invention only to specific examples unless otherwise specifically described. Only.

FIG. 1 (A) is an explanatory view of the installation state of a urea water tank in which the present invention is implemented, and FIG. 1 (B) is a perspective view of a hose holder for holding a hose when urea water is replenished.
In the case of the truck 1, when the mounting device 2 mounted on the frame 21 projects above the supply port 31 of the urea water tank 3, the supply nozzle 32 is placed at the outer corner portion Z of the mounting device 2. In order to prevent contact, the hose 5 formed in a bellows shape built in the urea water tank 3 is pulled out, and the first hose 5 is connected to the hose holder 23 provided in the corner portion Z of the bodywork device 2. The flange 52 side is held.
The tip of the replenishing nozzle 32 is inserted into the first flange 52 held by the hose holder 23, and urea water supply to the urea water tank 3 is started.

As shown in FIG. 1B, the hose holder 23 is a flat base plate 23a attached to the lower surface of the bodywork device 2, one end is fixed to the base plate 23a, and the other end is the bodywork device 2. On the other hand, the holding portion 23b is bent downward (in the direction of gravity) and wound in an annular shape.
A notch m through which the hose 5 passes is formed between the base plate 23a and the edge 23e of the holding portion 23b.
The notch m has a width that allows the bellows valley diameter or the base diameter of the first flange portion 52 to pass therethrough.
The holding portion 23b is formed of a round bar or pipe having a circular cross-sectional shape, and by eliminating the corner portion, the hose 5 is not damaged when the hose 5 is engaged or disengaged.
The first flange 52 side of the hose 5 is held in the hollow portion of the holding portion 23b. Therefore, in order to ensure the holding of the hose 5, the corner portion 23d of the base plate 23a is formed in an R shape (semicircle) in order to secure the cutout portion m in order to leave the annular circumferential portion of the holding portion 23b as much as possible. Shape).

FIG. 2A shows a detailed view of the first embodiment of the hose in which the present invention is implemented, and FIG. 2B shows a plan view of the second flange portion.
The present invention includes a cap 8 that engages with the replenishing port 31 of the urea water tank 3 and a hose 5 that is detachably held by the cap 8.
The hose 5 is formed of a material that can be elastically deformed, and engages with the inside of the urea water tank 3 and the first flange portion 52 that is one end engaged with and disengaged from the cap 8. The second flange portion 53, which is the other end engaged with the replenishing port 31 in the urea water tank 3, and the first flange portion 52 and the second flange portion 53 have bellows-like shapes at both ends so as not to slip out. The main body 51 is configured.
The elastically deformable materials are PP (polypropylene) and PE (polyethylene).
There are rubber materials.

As shown in the plan view of the flange portion in FIG. 2B, the second flange portion 53 is provided with four protrusions 53a at equal intervals on the outer peripheral portion.
The outer diameter (bellows crest) D1 of the main body 51 of the hose 5 is smaller than the inner diameter D4 of the replenishing port 31, and there is a margin that allows the crest D1 of the main body 51 to easily move (withdrawal) in the replenishing port 31. Is formed.
The outer diameter D3 (protrusion tip) of the second flange 53 is formed larger than the inner diameter D4 of the supply port 31.
The second flange portion 53 is inserted from the replenishing port 31 into the urea water tank 3 while being elastically deformed so that the protrusion 53a is folded back to the main body portion 51 side.
When the second flange portion 53 passes through the replenishing port 31 and enters the urea water tank 3, the protrusion 53 a becomes free, expands to the original state, and the hose 5 is moved outward from the urea water tank 3. When pulled out, the protrusion 53a engages with the replenishing port 31 in the urea water tank 3 to prevent the hose 5 from coming out.
Therefore, the existing urea water tank can be easily replenished with the urea by simply replacing the cap 8 and the hose 5 engaged / disengaged with the cap 8 with respect to the cap of the existing urea water tank 3, thereby increasing the cost. Can be expected to have an inhibitory effect.

(Second Embodiment)
Moreover, it demonstrates based on FIG. 3 as 2nd Embodiment of a 2nd flange part.
In addition, the same thing as 1st Embodiment attaches | subjects the same code | symbol, and abbreviate | omits description.
The hose 6 is made of an elastically deformable material and is engaged with the first flange portion 52 and the urea water tank 3 so that the hose 6 does not come out of the urea water tank 3. The tank 3 includes a second flange portion 62 that engages with the replenishing port 31, and a bellows-shaped main body portion 61 having a first flange portion 52 and a second flange portion 62 at both ends.
A notch 63 having a width W and a length N1 is formed along the axis CL of the hose 6 in the second flange portion 62 and the main body portion 61 following the second flange portion 62.
The bottom 64 of the cut 63 is formed in a semicircular shape.
Further, the width W may be increased to be easily elastically deformed when the diameter D6 of the second flange portion 62 is large.
What is necessary is just to determine sequentially considering the rigidity of the 2nd flange part 62, etc.

The second flange portion 62 is inserted from the outside of the supply port 31 by overlapping the edge 65 of the cut 63 in the circumferential direction and reducing the diameter of the hose 6.
When the second flange portion 62 passes through the replenishing port 31 and enters the urea water tank 3, the second flange portion 62 becomes free, expands to the original state, and the hose 6 is connected to the urea water tank 3. When pulled out outward, the second flange portion 62 engages with the supply port 31 in the urea water tank 3 to prevent the hose 6 from coming out.

Since the bottom 64 of the notch 63 is formed in a semicircular shape, the stress generated by the deformation of the bottom can be reduced even if the polymerization margin of the edge 65 is increased to reduce the diameter.
In the present embodiment, the bottom portion 64 of the cut 63 is formed in a semicircular shape, but the cut width W may be eliminated to make it linear.
Since the diameter of the second flange portion 62 is not generally implemented after the hose 6 is inserted into the urea water tank 3, even if high stress is generated in the portion, it is acceptable.
Furthermore, if the second notch 66 (only the flange thickness t) is added at a position rotated by 180 ° in the circumferential direction of the notch 63 of the second flange 62, the diameter of the second flange 62 can be easily reduced.

(Third embodiment)
Moreover, it demonstrates based on FIG. 4 as 3rd Embodiment of a 2nd flange part.
In addition, the same thing as 1st Embodiment attaches | subjects the same code | symbol, and abbreviate | omits description.
The hose 7 is formed of an elastically deformable material, and the first flange portion 52,
A second flange portion 72 inserted into the urea water tank 3 and projecting outward from the hose 7; a bellows-like main body portion 71 having a first flange portion 52 and a second flange portion 72 at both ends; A locking piece 76b that is loosely fitted on the outer periphery of the portion 71 and is sandwiched between the second flange portion 72 and the supply port 31 in the urea water tank 3 so that the second flange portion 72 does not pass through the supply port 31. A notch 73 formed in the sleeve 76 as a stopper member, the second flange portion 72, and the main body portion 71 following the second flange portion 72, having a width W and a length N2 along the axis CL of the hose 6. It consists of and.
The bottom 64 of the cut 63 is formed in a semicircular shape.

A sleeve 76 that is a tubular stopper member is loosely fitted to the main body portion 71 so as to be slidable in the direction of the axis CL of the hose 7.
On the outer peripheral portion of the tubular body 76a of the sleeve 76, a locking piece 76b having a triangular shape when viewed from the side along the axis CL from the second flange 72 side is provided over the entire length of the tubular body 76a. ing.
A plurality of locking pieces 76b are provided at equal intervals in the circumferential direction of the outer peripheral surface of the tubular main body 76a. The distal end 76d side of the locking piece 76b has the same height (height = 0 mm) as the outer peripheral surface of the tubular body 76a, and the outer diameter of the rear end edge 76c on the first flange side is larger than the inner diameter D4 of the supply port 31. Largely formed.
Accordingly, the first flange side end edge 76 c of the locking piece 76 engages with the urea water tank inner side surface 31 b of the replenishing port 31, thereby preventing the hose 7 from coming out of the urea tank 3.

The length N4 of the tubular body 76a of the sleeve 76 is such that the bottom 74 of the notch 73 is not exposed from the tip 31a of the replenishing port 31 when the hose 7 is pulled out of the urea water tank 3 by the full allowable amount. It is necessary to be safe.
That is, the length N4 of the tubular body 76a needs to have the following relationship as the length N3 of the tip 31 of the supply port 31, the inner surface 31b of the supply port 31, and the thickness t of the second flange 72. .
N4> N2- (N3 + t)
t: thickness of the second flange 72
N2: Cutting depth
N3: Length of the tip 31 of the supply port 31 and the inner side surface 31b of the supply port 31

With this structure, the assembly sequence will be described.
The diameter of the second flange portion 72 is reduced, and the sleeve 76 is fitted onto the hose 7. The externally fitted sleeve 76 is slid to the first flange portion 52 side. Next, the second flange portion 72 is again reduced in diameter, inserted into the supply port 31, and inserted up to the intermediate portion in the axial direction CL of the hose 7. Next, the locking piece 76c of the sleeve 76 is pushed in while being elastically deformed. The sleeve 76 is locked in the urea water tank 3 with the distal end 76 d of the sleeve 76 coming into contact with the second flange 72.
Furthermore, when the length N3 of the supply port 31 is short or the cut length is long and the hose 7 is pulled out to the outside of the urea water tank 3, the bottom 74 of the cut 73 is the supply port 31. The urea water can be prevented from leaking outside from the slit 73 when the urea water is replenished by preventing it from being exposed from the tip 31a.

(Fourth embodiment)
A description will be given based on the detailed view of the embodiment of the cap in which the present invention is implemented shown in FIG.
In addition, the same thing as 1st Embodiment attaches | subjects the same code | symbol, and abbreviate | omits description.
Reference numeral 8 denotes a cap that closes the replenishing port of the urea water tank 3. The cap 8 strongly presses the cap body 8 a and the first flange portion 52 of the hose 5 at the end edge 31 a of the replenishing port 31. The pressing portion 8b for maintaining the sealing, the screw portion 8c for maintaining the sealing of the replenishing port 31 by screwing the cap 8 with the screw portion 31b formed on the outer peripheral portion of the replenishing port 31, and the first flange portion 52 as a cap And an engaging / disengaging device 81 held by the motor.

The engagement / disengagement device 81 is an operation portion that is an operation button 82 that slides in the radial direction of the cap 8, and that is engaged with the operation of the operation button 82 to urge the first flange portion 52 toward the pressing portion 8 b. The coupling piece 83 and a coiled torsion spring 84 that urges the engagement piece 83 are configured.
The engagement piece 83 is pivotally attached to a shaft pin 85 erected integrally with the cap main body 8 a so as to be rotatable about an axis (not shown) of the shaft pin 85, and the first flange portion is supported by a torsion spring 85. The first lever 83a that urges the outer peripheral edge 52a of the 52 toward the pressing part 8b, and the second lever 83b that engages and disengages the first lever 83a and the outer peripheral edge 52a by operating the operation button 82 that is an operation part. And have.
At least two engagement / disengagement devices 81 are arranged at equal intervals in the circumferential direction on the outer periphery of the cap body 8a.

With such a structure, the cap 8 is rotated along the screw portion screw portion 31 b (the operation button 82 is not operated), and the cap 8 is removed from the supply port 31.
At this time, the tip of the first lever 83a slides in the circumferential direction on the lower peripheral point P of the outer peripheral edge of the first flange portion 52.
When the cap 8 is removed from the supply port 31, the hose 5 comes out of the supply port 31 while being engaged with the cap 8. In this state, the hose 5 is held (engaged) with the hose holder 23 provided at the corner portion Z of the bodywork device 2 on the first flange 52 side.
Thereafter, when the operation button 82 of the cap 8 is operated to move the first lever 83a from the engagement position to the release position, the cap 8 can be detached from the first flange 52.

In this state, urea water can be replenished, and can be replenished without directly touching the hose 5 wet with urea water, and the first flange portion 52 is held by the hose holder 23, so that the replenishment nozzle 32 is stabilized. It can be inserted into the hose 5 in a state.
When replenishment is complete, engage the first flange 52 while operating (pushing in) the operation button of the cap 8, remove the hose 5 from the hose holder 23, and fasten it to the threaded portion 31 b of the replenishment port 31. To do.

(Fifth embodiment)
FIG. 6 is a detailed view of the embodiment of the cap in which the present invention is implemented, FIG. 7A is an explanatory diagram of the engagement state between the cap and the first flange, and FIG. An explanation will be given based on a state explanatory diagram in which the engagement is released and a state diagram in which the engagement piece of (C) passes through the first flange portion.
In addition, the same thing as 1st Embodiment attaches | subjects the same code | symbol, and abbreviate | omits description.
Moreover, since this embodiment is an invention in which the structure of the engagement / disengagement device 91 is different, the procedure for supplying urea water to the urea water tank 3 has been described in the fourth embodiment, and will be omitted.

  Reference numeral 9 denotes a cap that closes the supply port of the urea water tank 3. The cap 9 seals the supply port 31 by strongly pressing the cap body 9 a and the first flange portion of the hose 5 with the edge 31 a of the supply port 31. The pressing portion 9b for maintaining the supply port, the screw portion 9c for maintaining the sealing of the supply port 31 by screwing the cap 9 with the screw portion 31b formed on the outer peripheral portion of the supply port 31, and the first flange portion 52 are held. It is comprised with the engagement / disengagement apparatus 91. FIG.

The engagement / disengagement device 91 is an operation portion that is an operation portion that is an operation portion that slides in the radial direction of the cap 9 and is engaged with the operation of the operation button 92 to move the first flange portion 52 toward the pressing portion 9b. The engaging piece 93 is configured to be biased, and a coiled torsion spring 94 is used to bias the engaging piece 93.
The engagement piece 93 is formed in a substantially triangular outer shape, and is rotated around the axis (not shown) of the first shaft pin 95 by the first shaft pin 95 erected integrally with the cap body 9a. A first convex portion 93a that is pivotally attached and urges the outer peripheral edge 52a of the first flange portion 52 toward the pressing portion 9b by a torsion spring 94, and extends from the engagement deformation 93 to the operation button 92 side. A passive lever 93b that engages and disengages the first convex portion 93a and the outer peripheral edge portion 52a by operating the operation button 92 is provided.

  As shown in FIG. 6B, the engaging piece 93 is a length N5 of the first shaft pin 95 and the tip of the first convex portion 93a with respect to the shaft pin 95, and the first shaft pin 95 on the opposite side. N6 of the engagement piece 93 and the substantially triangular base side 93c of the engagement piece 93 is N5 >> N6. When the engagement piece 93 is in a free state, the first protrusion 93a side is gravity-rotated downward in the drawing. It is formed as follows.

The operation button 92 which is an operation unit includes a first operation piece 92b in which the button main body 92a slides in the radial direction of the cap 9 and a first end 94a of a torsion spring 94 which will be described later contacts the button main body 92a. A second operating piece 92c that rotates the passive lever 93b of the engaging piece 93 around the uniaxial pin 95 is integrally formed.
The torsion spring 94 has a coil portion pivotally attached to a second shaft pin 96 erected integrally with the cap body 9a so as to be rotatable about an axis (not shown) of the second shaft pin 96. As described above, the first end 94a presses the first operating piece 92b and the second end 94b presses the passive lever 93b.
Further, two engagement / disengagement devices 91 are arranged at equal intervals in the circumferential direction on the outer peripheral portion of the cap body 9a.

FIG. 7A shows a state in which the cap 9 is removed from the supply port 31. That is, the cap 9 and the first flange portion 52 of the hose 5 are twisted with the torsion spring 94 in a state where the first convex portion 93 a of the engagement piece 93 presses the first flange portion 52 of the hose 5 toward the pressing portion 9 b of the cap 9. The state which is engaged by the urging force is shown.
That is, when the first flange portion 52 acts away from the pressing portion 94a, the first end portion 94a and the second end portion 94b of the torsion spring 94 abut against the first operation piece 92b and the second operation piece 92c, respectively. In contact with the first flange portion 52, the torsion spring 94 is opened (increases the angle θ formed by the first end portion 94 a and the second end portion 94 b). Engagement with the joining piece 93 is maintained.

FIG. 7B shows a state in which the engagement piece 3 releases the engagement of the first flange portion 52 of the hose 5 when the hose holder 23 holds the first flange portion 52 of the hose 5. .
That is, when the operation button 92 as an operation unit is pressed in the radial direction of the cap 9, the first end 94a and the second end 94b of the torsion spring 94 are respectively connected to the first operation piece 92a and the second operation piece 92b. The cap 9 slides in the radial direction against the biasing force of the spring. Since the second operating piece 92c rotates the passive lever 93b downward about the first shaft pin 95 in the drawing, the engagement between the cap 9 and the first flange portion 52 is released.

FIG. 7C shows a state in which the cap 9 is attached to the first flange portion 52 after the urea water supply is completed.
That is, when the cap 9 is pressed from above (in the direction of the arrow X) toward the first flange portion 52 (the operation button 92 is not operated), the distal end portion of the first convex portion 93a of the engagement piece 93 becomes the first flange portion 52. The engagement piece 93 rotates in the Y arrow direction around the first shaft pin 95. As the engagement piece 93 rotates in the Y arrow direction, the passive lever 93b also rotates in the Y arrow direction, but the operation button 92 escapes to the outside of the cap 9 by the L dimension in FIG.

Therefore, the tip end portion of the first convex portion 93 a of the engagement piece 93 moves to the lower side of the outer peripheral portion of the first flange portion 52 (the back side of the first flange 52), and the engagement piece 93 moves the first shaft pin 95. With the weight of the engaging piece 93 as the center, it rotates in the direction opposite to the arrow Y.
However, when the tip end portion of the first convex portion 93a moves to a position below the outer peripheral portion of the first flange portion 52, the second end portion 94b of the torsion spring 94 comes into contact with the passive lever 93b, and the first operating piece 92b. The first end portion 94a of the torsion spring 94 comes into contact with the rotation of the engagement piece 93 and stops.
In this state, the engagement / disengagement device 91 enters a state (the state shown in FIG. 9A) in which the first flange portion 52 is engaged.

  With such a structure, the engaging piece 93 expands in the radial direction of the first flange portion 52 simply by pressing the cap 9 against the first flange portion 52 in the axial direction of the hose 5. After completion of the above, the hose 5 and the cap 9 can be coupled simply by pressing the cap against the first flange portion, the replenishment work is easy, and an erroneous operation is unlikely to occur.

  In the present invention, the engagement / disengagement structure between the first flange portion and the cap of the hose and the structure for preventing the second flange portion from coming out from the supply port can be used in appropriate combination, and the same effect can be obtained. .

  The present invention can be applied to a cap structure of a replenishing port of a tank for storing urea water used as a reducing agent for a purification device that purifies exhaust gas discharged from an automobile or the like.

DESCRIPTION OF SYMBOLS 1 Truck 2 Bodywork apparatus 3 Urea water tank 5, 6, 7 Hose 8, 9 Cap 23 Hose holder 31 Supply port 51, 61, 71 Hose body 52 1st flange 53, 63, 73 2nd flange 63, 73 76 Sleeve (stopper member)
81, 91 Engagement / disengagement device 82, 92 Operation buttons (operation unit)
83, 93 engagement piece 84, 94 torsion spring (elastic member)

Claims (5)

In the cap structure of the urea water tank,
A cap detachable from the replenishing port of the tank;
A hose formed of a material that can be elastically deformed and configured to be insertable into the replenishment port,
A first flange portion provided at one end of the hose to prevent the one end from passing inward of the tank;
Provided at the other end of the hose, and when the other end passes through the supply port when the other end passes through the supply port, the other end is deformable and the other end is the supply. A second flange portion configured to be capable of expanding and deforming in a free state after passing through the mouth and preventing the other end from passing through the outside of the tank;
An engagement / disengagement device provided on the cap and having an operation portion for engaging / disengaging the cap and the first flange portion;
A urea water tank cap structure characterized by comprising:   2. The urea water tank cap according to claim 1, wherein the second flange portion is provided with a cut along an axial direction of the hose, and an end edge of the cut is superposed and deformed in a circumferential direction to reduce the diameter. Construction. The engagement / disengagement device includes the operation portion and an engagement piece that is engaged with the operation portion and engages / disengages with the first flange portion,
2. The urea water tank cap structure according to claim 1, wherein the engagement between the first flange portion and the engagement piece is released in accordance with the operation of the operation portion.   When the cap is pressed against the first flange portion in the axial direction, the engagement / disengagement device expands the engagement piece in the radial direction of the first flange portion and passes through the first flange portion. 4. The urea water tank cap structure according to claim 3, wherein the first flange portion and the engagement piece are engaged by an urging force of an elastic member.   On the outer periphery of the notch of the second flange portion, a stopper member formed in a tubular shape with a material that is equal to or longer than the axial length and is elastically deformable is slidably fitted in the axial direction. 3. The urea water tank cap structure according to claim 2, wherein:

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