JP5223891B2 - Tank oil filler structure and oil cap cover - Google Patents

Description

  The present invention relates to a fuel filler structure for a tank provided with a fuel cap with a vent hole, and a fuel cap cover used in the structure.

  8 and 9 show a conventional fuel filler structure in a fuel tank for a hydraulic excavator.

The fuel tank 1 has a cylindrical filler neck (fuel filler port) 2 on the upper surface, and a fuel cap 3 is detachably attached to the upper end opening of the filler neck 2 by a screw fitting structure or the like (
(See Patent Documents 1 and 2).

The fuel filler cap 3 is provided with a vent hole 4 communicating with the inside and outside of the tank, for example, in an L shape on the inner peripheral side of the cap. The vent hole 4 allows the air to enter and exit the tank according to the increase or decrease of fuel (
Air breather action) is performed (see Patent Document 2).

  On the other hand, in an internally-fitted oil cap that is applied to a lubricating oil case such as a gear case, a vent hole is provided on the lower surface of the head of the headed shaft-shaped cap, while a ring-shaped protrusion is provided on the outer periphery of the shaft. A plurality of air gaps are provided at intervals in the vertical direction, and notches are provided in the outer peripheral portion of the convex portion so as to be alternately displaced in the circumferential direction, thereby forming a labyrinth-structured air passage leading to the air holes, and tilting and vibration of the aircraft Therefore, a technique for preventing the oil in the tank from spilling out from the vent hole is known (see Patent Document 3).

JP 2009-166807 A Japanese Patent Laid-Open No. 9-290854 JP-A-8-28782

  According to the known technology in which the ventilation hole 4 of the oil filler cap 3 is formed as a linear or L-shaped groove on the inner peripheral side of the cap, the hydraulic excavator is used in a site full of dust or a site where a large amount of sand dust dances. The air vents were often clogged with dust (including sand dust, the same applies hereinafter), and dust was sucked into the tank and mixed into the fuel as a previous step.

  By the way, when the known technique described in Patent Document 3 is applied to the tank, it is considered that a certain effect can be obtained in terms of preventing dust from entering the tank by the labyrinth structure.

  However, since the air passage hole itself is formed in a straight line and directly opens to the outside, it is not possible to prevent this air hole from being clogged with dust.

  Further, since the dust is damped by the labyrinth structure on the inner peripheral side of the filler neck, the damped dust may gradually descend the air passage due to the vibration of the airframe and fall into the tank.

Furthermore, in order to add a labyrinth structure to the oil cap itself, prepare two types of oil caps with a labyrinth structure and less expensive regular oil caps depending on the dusty site and the other sites, and use them properly This is disadvantageous in terms of cost and management because it is not necessary and the oil cap itself must be replaced for the existing tank.

Accordingly, the present invention provides a tank filler port structure and a filler cap cover that can reliably prevent dust clogging in the vent holes and dust from entering the tank and can be retrofitted to an existing tank with a filler cap. It is to provide.
Providing construction machinery.

The invention according to claim 1 (tank filling port structure) is a tank filling port structure in which a filler cap is provided in a filler neck of the tank, and a vent hole for introducing outside air is provided in the filling cap.
(A) An oil supply cap cover made of an elastic material such as rubber is fitted on the oil supply cap,
(B) The fuel cap cover, the fuel supply cap and the cover body for covering and the filler neck,-rings-shaped seal portion projecting from the inner inwardly periphery of the portion covering the filler neck in the cover body And
(C) The seal portion has a projecting dimension at which the tip can be elastically adhered to the outer peripheral surface of the filler neck in a lapped state at a plurality of positions in the height direction of the cover body, and a ventilation groove between adjacent ones. Are formed independently in parallel in a state where
(D) Notches that allow the ventilation grooves to communicate with each other in a part of the circumferential direction of each of the seal portions are provided alternately displaced in the circumferential direction.
(E) The ventilation groove and the notch form a ventilation path that moves between the front end opening of the oil supply cap cover and the ventilation hole while swirling air around the filler neck .

The invention according to claim 2 is a tank oil cap cover fitted to an oil cap provided on the filler neck of the tank, wherein the cover body covers the oil cap and the filler neck with an elastic material such as rubber. And a ring-shaped seal portion projecting inwardly from the inner periphery of the portion covering the filler neck in the cover body, and the seal portion has a tip at a plurality of positions in the height direction of the cover body. Are provided in parallel with each other with a projecting dimension capable of elastically adhering to the outer peripheral surface of the filler neck in a wrap state, and with a ventilation groove formed between adjacent ones, A notch is formed in a part of the air passage to allow the air vents to communicate with each other and move the air around the filler neck while moving the air between the cover tip opening and the air vent. Road those were found provided displaced in the circumferential direction alternately in a state of forming a.

  According to the present invention, a cap cover is placed on an oil filler cap provided with a vent hole in a state of covering the cap and the filler neck so as to cover them, and a ring-like shape that adheres closely to the outer periphery of the filler neck on the inner periphery of the cap cover. In order to form a ventilation path that protrudes inward at a plurality of locations in the cover height direction and moves the air between the cover tip opening and the vent hole while swirling air around the filler neck. While the air passage and the air holes allow the air to flow, dust in the air can be blocked in the air passage by the labyrinth effect in the air passage.

In addition, the dammed dust can be dropped to the lower end side of the cap by its own weight or vibration, and can be discharged naturally from the air passage. That is, unlike the case where a labyrinth structure is added to the fuel cap itself, there is no possibility that the dammed dust will fall into the tank.

  Furthermore, the attached dust can be removed cleanly by removing the cap cover and washing it at an appropriate time.

  In this way, it is possible to reliably prevent dust from clogging in the air holes and intrusion of dust into the tank while ensuring the air breather function of the fuel cap.

  Moreover, since the oil cap is covered with a separate cap cover, the existing tank with the oil cap can be retrofitted as necessary.

  That is, it is only necessary to attach the cover to an existing oil cap as an option only for a tank of a machine that is used at a site where there is a high risk of dust clogging or dust mixing.

  For this reason, it becomes advantageous in terms of cost and management as compared with the case of replacing the fuel cap itself.

Here, the seal portions are provided independently and in parallel with each other in a state where a ventilation groove is formed between them, and notches that allow the ventilation grooves to communicate with each other are alternately provided in the circumferential direction. As a result, the air repeatedly swirls and moves in the length direction of the filler neck to reach the vent hole from the outside.

  Accordingly, the effect of stopping dust in the maze is remarkable.

In addition, since each seal part is in close contact with the outer peripheral surface of the filler neck, the sealing effect is higher than when simply contacting them, and even if dust is not leaked, it is reliable over a long period of time. You can stop coughing.

It is sectional drawing which shows the fuel filler structure which concerns on 1st Embodiment of this invention. (a) is the aa line of FIG. 1, (b) is each bb sectional drawing of FIG. It is the perspective view seen from the lower side of the oiling cap cover. FIG. 2 is a partially enlarged view of FIG. 1. It is a figure which expand | deploys and shows the internal peripheral surface of a fueling cap cover. It is a figure which shows the experimental result for demonstrating the dust damping effect by the cover. FIG. 6 is a view corresponding to FIG. 5 showing a reference form. It is sectional drawing which shows the conventional oil filler opening structure. FIG. 9 is a partially enlarged view of FIG. 8.

Describing embodiments of the present invention by Figures 1-6.

FIG. 7 shows a reference form.

In the following embodiments, a fuel tank mounted on a hydraulic excavator is applied to the description of the background art .

In the implementation form,
(i) The fuel tank 11 includes a cylindrical filler neck (fuel filler port) 12 on the upper surface, and a fuel cap 13 is detachably attached to the upper end opening of the filler neck 12 by a screw-fitting structure or the like.
(ii) The fuel filler cap 13 is provided with a vent hole 14 communicating with the inside and outside of the tank as an L-shaped groove on the inner peripheral side of the cap. The vent hole 14 allows the air to enter and exit the tank according to the increase or decrease of fuel ( Air breather action) that is performed is the same as the conventional filler opening structure shown in FIGS. 8 and 9.

In implementation embodiment, fuel cap cover 15 made of an elastic material such as rubber or elastic plastic, are fitted detachably by retrofit to an existing filler cap 13.

  This oiling cap cover (hereinafter simply referred to as a cap cover) 15 includes a cylindrical cover body 16 that covers the upper and side surfaces of the oiling cap 13 and the upper outer peripheral surface of the filler neck 12, and a cover body 16 Ring-shaped seal portions 17 projecting inward at a plurality of locations in the height direction of the main body are integrally formed on the inner periphery of the lower half portion covering the filler neck upper outer peripheral surface.

  The seal portions 17 are independent from each other in a state in which the tip portion is elastically adhered to the outer peripheral surface of the filler neck when the cover is fitted, and a ventilation groove 18 is formed between the upper and lower adjacent members in the above-mentioned adhesion state. Are provided in parallel.

  In this case, as shown in FIG. 4, each seal portion 17 is provided with a projecting dimension L at which the tip can be in close contact with the outer peripheral surface of the filler neck in a lapped state.

Further, in the seal portion 17..., Notches 19 for communicating the adjacent ventilation grooves 18, 18 are alternately provided in the circumferential direction at a part in the circumferential direction (two symmetrical places with an interval of 180 ° in the illustrated example). At a certain angle (90 °).

  The ventilation groove 18 and the notch 19 form a ventilation path 20 that connects the outside and the ventilation hole 14, and air enters and exits through the ventilation path 20 and the ventilation hole 14 as shown in FIGS.

  According to this fuel filler opening structure, air in and out of the tank is allowed to flow through the air passage 20 and the air holes 14, and dust in the air can be dammed in the air passage 20 by the labyrinth effect in the air passage 20.

  Further, the dammed dust falls to the lower end of the cap due to its own weight or vibration, and is naturally discharged from the air passage to the outside. In other words, there is no possibility that the dammed dust will fall into the tank as in the case where a labyrinth structure is added to the fuel cap itself.

  Furthermore, the attached dust can be removed cleanly by removing the cap cover and washing it at an appropriate time.

  In this way, while ensuring the air breather function of the fuel filler cap 13, dust can be prevented from entering the vent hole 14 from the outside, and dust clogging in the vent hole 14 and mixing of dust into the fuel in the tank can be reliably prevented. .

In particular, according to this fuel filler structure , the air passage 20 is formed in a labyrinth shape by the horizontal ring-shaped air groove 18 and the vertical notch 19 so that the air is swung horizontally and the filler neck length direction (
Since it flows while repeating the movement (up and down direction), the dust damming effect becomes remarkable.

Further, since each seal portion 17 is in close contact with the filler neck outer peripheral surface in a state where the tip wraps, the sealing effect is enhanced as compared with the case of simply contacting, and fine dust does not leak, and for a long time. Can be surely stopped.

  FIG. 6 shows the results of experiments conducted by the present inventor regarding the dust damming effect of the cap cover 15.

Experiments, A without a cap cover as illustrated (conventional filler opening structure of FIG. 8, 9), B provided with the cap cover without sealing portion, the implementation form of the seal portion with the cap cover (sealing tip 1.0mm wrap) and C, which has a seal part, but D is provided with a cap cover where the tip does not wrap around the outer peripheral surface of the filler neck. Accelerated test to be generated, specifically, the time when the air in which the dust is floating is sucked into the tank and then the air in the tank is sucked out at MAX 3 liters / min with a vacuum pump, and the tank internal pressure reaches -10.1 kPa Was measured as a clogging time of the vent hole.

As a result, clogging time of type C according to the implementation form, is about 11 times the type A without the cap cover, dust clogging prevention effect was remarkably appeared.

  Further, it has been clarified that, even in the type D where the seal portion is not wrapped, the dust clogging preventing effect is obtained as compared with the types A and B, although it is inferior to the type C.

  In FIG. 6, the hatching of each type A to D and the reference numerals of the respective parts are omitted.

  On the other hand, according to this fuel filler opening structure, since the oil cap 13 is covered with a separate cap cover 15, an existing tank with a fuel cap can be retrofitted as necessary.

  In other words, this cap cover 15 may be retrofitted as an option to an existing oiling cap 13 only in a tank of a machine used at a site where there is a high risk of dust clogging or dust mixing.

  For this reason, it becomes advantageous in terms of cost and management as compared with the case of replacing the fuel cap itself.

Reference form (see Fig. 7)
Only differences from the implementation embodiment will be described.

In the reference form, each seal portion 21 of the cap cover 15 is continuously provided in a thread shape, and a spiral ventilation groove 22 is formed between the seal portions.

In the case of this reference form, this spiral ventilation groove 22 becomes the ventilation path as it is, and the air flow becomes a simple spiral flow as shown in the figure.

Thus, dust is to move air passage to a certain depth riding the helical flow, the point where essentially seal portion 21 is a barrier not a same as implementation form.

  By the way, in the said embodiment, although the oil supply cap 13 of the simplest structure provided with the L-shaped ventilation hole 14 in the inner periphery was illustrated, this invention is an oil supply cap provided with the ventilation hole whatever the structure. Can also be applied.

  Further, the present invention can be applied not only to a fuel tank of a hydraulic excavator but also to a fuel tank of another construction machine. Further, the present invention can be applied not only to the fuel tank but also to various oil tanks in which a filler cap with a vent hole is provided in the filler neck.

DESCRIPTION OF SYMBOLS 11 Fuel tank 12 Filler neck 13 Refueling cap 14 Ventilation hole 15 Refueling cap cover 16 Cover main body 17 Seal part 18 Ventilation groove 19 Notch 20 Ventilation path

Claims (2)

In the tank filler port structure in which a filler cap is provided in the filler neck of the tank, and a vent hole for introducing outside air is provided in the filler cap,
(A) An oil supply cap cover made of an elastic material such as rubber is fitted on the oil supply cap,
(B) The fuel cap cover, the fuel supply cap and the cover body for covering and the filler neck,-rings-shaped seal portion projecting from the inner inwardly periphery of the portion covering the filler neck in the cover body And
(C) The seal portion has a projecting dimension at which the tip can be elastically adhered to the outer peripheral surface of the filler neck in a lapped state at a plurality of positions in the height direction of the cover body, and a ventilation groove between adjacent ones. Are formed independently in parallel in a state where
(D) Notches that allow the ventilation grooves to communicate with each other in a part of the circumferential direction of each of the seal portions are provided alternately displaced in the circumferential direction.
(E) The tank is characterized in that the vent groove and the notch form an air passage that moves between the front end opening of the oil supply cap cover and the vent hole while turning air around the filler neck . Filling port structure. A tank refueling cap cover fitted to a fuel cap provided on a filler neck of the tank, the cover main body covering the oil replenishing cap and the filler neck with an elastic material such as rubber, and the cover body in the cover main body Ring-shaped seals projecting inward from the inner periphery of the portion covering the filler neck are integrally formed, and the seal portions are wrapped at the filler neck outer peripheral surface at a plurality of locations in the height direction of the cover body. Protruding dimensions that can be elastically adhered in the state, and provided in parallel independently in a state in which a ventilation groove is formed between adjacent ones, a notch in a part of the circumferential direction of each of the seal parts, A state in which a ventilation path is formed to move between the opening of the cover tip and the ventilation hole while allowing the ventilation grooves to communicate with each other and swirling the air around the filler neck. Features and to filter fuel cap cover link that was displaced in the circumferential direction was found alternately provided.

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