JP6208034B2 - Fuel supply device - Google Patents

Description

  The present invention relates to a fuel supply device that uses a nozzle to supply fuel to a fuel tank to be supplied with fuel, and in preparation for the start of a fuel supply operation, a nozzle storage portion and nozzles stored and held in the nozzle storage portion. The present invention relates to a fuel supply device including a protection mechanism.

  As an example of a fuel supply device provided in a fuel supply station, a fuel supply device that is provided in a so-called gasoline station and supplies fuel such as gasoline or light oil to a fuel tank of a vehicle to be supplied with fuel is known. In the fuel supply apparatus including this fuel supply apparatus, the fuel supply work is performed by the fuel supply station employee or the customer himself / herself operating the nozzles stored and held in the nozzle storage section of the apparatus main body. It has become.

  By the way, such a fuel supply device is normally installed outdoors because of the relationship with the fuel supply target, etc., for example, in a fuel supply station in a cold region where wind and snow are severe, it was stored in the nozzle storage unit. Snow or the like adheres to the nozzle in the state. As a result, snow adhering to the nozzles stored in the nozzle storage unit may interfere with nozzle operation during fuel supply operations, for example, when the nozzle is removed from the nozzle storage unit. Further, when the nozzle is wet due to rain as well as snow, the operator may feel uncomfortable by touching the wet nozzle.

  The present invention relates to a fuel supply device installed in a fuel supply station in a cold region where wind and snow are severe. Patent Document 1 discloses that a nozzle storage unit is used to prevent snow or the like from adhering to a nozzle stored in the nozzle storage unit. A fuel supply device including a nozzle cover that can be opened and closed (the main body and the discharge pipe can be exposed / shielded) that can cover the main body of the nozzle and the discharge pipe, excluding the grip portion of the nozzle, is described. Yes.

  In addition, Patent Document 1 discloses that the nozzle cover is locked to the cover closed position (the shielding position of the nozzle storage portion) by the weight of the nozzle while the nozzle is stored in the nozzle storage portion, while the nozzle is stored in the nozzle storage portion. There is also described a lock mechanism that can automatically release the locking of the nozzle cover at the cover closed position by simply lifting the nozzle when taking it out of the part. In addition, this lock mechanism causes the nozzle cover in the closed state to be lifted by strong winds without impairing the operability when removing the nozzle from the nozzle housing, and the nozzle cover vibrates and generates noise. It is described that this can be prevented.

JP 2011-240971 A

  By the way, in the fuel supply device described in Patent Document 1 described above, when the fuel supply operation is started, when the nozzle is lifted and taken out from the nozzle housing portion at the start of the operation, at that time, the nozzle cover once opened. The cover of the nozzle cover is open until the fuel is supplied to the fuel tank from the discharge pipe inserted into the liquid supply port until the nozzle is stored in the nozzle storage section after the fuel supply operation is completed. And the release state of the lock mechanism is maintained.

  For this reason, when the amount of fuel supply is large, or when a customer who is unfamiliar with nozzle operation by self-service performs the fuel supply operation, etc., the standby state for the fuel supply operation in which the nozzle is stored in the nozzle storage unit Compared to a short time, the time from when the nozzle is removed from the nozzle housing until the nozzle is housed in the nozzle housing becomes longer. During this time, it is possible to allow snow or the like to adhere to the nozzle housing. become.

  Therefore, after the nozzle is lifted and removed from the nozzle housing, the nozzle cover is temporarily operated to close the cover and the lock mechanism is locked, while the nozzle is being removed from the nozzle housing. However, in reality, it is easy to forget the cover closing operation of the nozzle cover and the locking operation of the lock mechanism after removing the nozzle. .

  Therefore, the present invention has been made in view of the above-described problems, and the nozzle is a nozzle without impairing the workability when the nozzle is taken out from the nozzle storage portion and when the nozzle is stored in the nozzle storage. It is an object of the present invention to provide a fuel supply device in which snow or the like hardly adheres to the nozzle housing part even after the nozzle is taken out from the housing part until the nozzle is housed in the nozzle housing part.

  In order to solve the above-described problem, the fuel supply device according to the present invention is provided with a nozzle that does not impair workability when the nozzle is taken out from the nozzle storage portion and when the nozzle is stored in the nozzle storage portion. The nozzle cover that is in the cover open state (exposed state of the nozzle storage section) when the nozzle is removed from the nozzle storage section after the nozzle is removed from the storage section After taking out, the cover is automatically returned to the closed state (the concealed state of the nozzle storage portion).

  For this purpose, the present invention provides a nozzle that is connected to a fuel supply port of a fuel supply target and supplies fuel to the fuel supply target, a fuel supply path that supplies fuel to the nozzle, and a housing having the fuel supply path A fuel supply device comprising: a nozzle storage portion that stores a nozzle; and a nozzle cover that is formed so as to cover the nozzle storage portion and that can be opened and closed with respect to the nozzle storage portion. A reduction mechanism is provided that reduces the cover moving speed when the nozzle cover in the open state is in the cover closed state with respect to the cover moving speed generated based on the gravitational acceleration in the cover open state.

  When the operator opens the nozzle cover to remove the nozzle from the nozzle housing, the nozzle cover automatically decelerates and slowly moves to the cover closed position even if the operator releases the nozzle cover. Therefore, the operator can take out the nozzle from the nozzle housing portion with the hand separating the nozzle cover during that time, and the workability is not impaired.

  Problems, configurations, and effects other than those described above will become apparent from the following description of embodiments.

1 is a front view of a fuel supply device as an embodiment of a fuel supply device according to the present invention. It is a perspective view which shows the structure of the nozzle accommodating part to which the nozzle cover was attached. It is a block diagram of a nozzle cover. It is explanatory drawing of the rotation mechanism attached to the nozzle accommodating part of a nozzle cover so that rotation is possible. It is a block diagram of one Example of the deceleration shaft with which the deceleration shaft mechanism part of the rotation mechanism was equipped. It is the figure which showed the state of the nozzle cover and rotation mechanism in the cover closed position of a nozzle cover. It is the figure which showed the state of the nozzle cover and rotation mechanism in the cover half-closed (cover half-open) position of a nozzle cover. It is the figure which showed the state of the nozzle cover and rotation mechanism in the cover open position of a nozzle cover.

  An embodiment of a fuel supply device according to the present invention will be described with reference to the drawings.

  In the following, an embodiment of a fuel supply device according to the present invention will be described taking a fuel supply device provided in a gas station as a fuel supply station as an example. The fuel supply device according to the present invention is not limited to the fuel supply device. For example, LPG (liquefied petroleum gas), LNG (liquefied natural gas), CNG (compressed natural gas), or hydrogen used as fuel for the fuel cell The present invention is applicable to any device that supplies fuel to a fuel supply target by operating a nozzle, such as a gas filling device that fills fuel gas.

  FIG. 1 is a front view of a fuel supply apparatus as an embodiment of a fuel supply apparatus according to the present invention.

  The refueling device 10 is provided in a so-called gas station, and a stand employee or a customer himself / herself operates a refueling nozzle 30 housed and held in a nozzle housing portion 40 of the device body 11 so as to supply fuel to the vehicle. A fuel supply device for supplying gasoline or light oil to a fuel tank or the like.

  In FIG. 1, the oil supply device 10 includes a device main body 11 and a plurality of oil supply hoses 20 that are led out from the device main body 11 and are each provided with a fuel supply nozzle 30 at the tip. Each oil supply nozzle 30 constitutes an oil supply system together with the corresponding oil supply hose 20. For example, in the illustrated example, the fueling device 10 is configured to include three fueling systems having different oil types such as regular gasoline, high-octane gasoline, and light oil.

  In FIG. 1, the apparatus main body 11 includes an apparatus storage section 12 in which each apparatus constituting the oil supply system together with the oil supply nozzle 30 and the oil supply hose 20 is stored, and a display apparatus storage section 13 in which a display and a control device are stored. It is prepared for. The device storage unit 12 and the display device storage unit 13 are configured such that a panel, a partition plate, and the like are attached to the frame of the apparatus main body 11 and are partitioned from each other.

  Inside the device storage unit 12, a liquid supply device 21 such as a pump of each oil supply system, and a flow rate measurement device 22 such as a flow meter that measures the amount of oil supplied to the oil supply nozzle 30 by driving the liquid supply device 21. However, each is stored. The pump suction side of the liquid feeding device 21 of each of the oil supply systems is connected to the underground oil storage tanks of regular gasoline, high-octane gasoline, and light oil via pipes, and the pump discharge side is connected to the inflow side of the corresponding flow rate measuring device 22. The outflow side of each flow measuring device 22 is configured to communicate with the base end side of the corresponding oil supply hose 20 via a pipe.

  In addition, the housing surface of the device storage unit 12 is provided with a nozzle storage unit 40 for holding the fuel supply nozzle 30 when not in use for each fuel supply system. Each nozzle storage unit 40 is provided with a nozzle switch 23 for detecting a storage state / non-storage state of the fuel supply nozzle 30 with respect to the nozzle storage unit 40 or a change in the state thereof. And since the oil supply device 10 shown in the figure has a plurality of oil supply systems, the supply oil type for each oil supply system is provided on the housing surface of each nozzle storage unit 40 or the device storage unit 12 in the vicinity of each nozzle storage unit 40. A displayed oil type display panel is also provided.

  On the other hand, in the display device storage unit 13 defined as such a device storage unit 12, an oil supply indicator 24 that displays fuel supply information such as the amount of oil supply is exposed to the outside of the apparatus body 11. It is not provided. A fuel supply control device 25 for controlling the operation of each part of the fuel supply device including the fuel supply indicator 24 is accommodated inside the display device storage unit 13.

  The oil supply control device 25 is constituted by a microcomputer provided with a CPU, RAM, ROM, an input / output interface for connected devices, a communication interface for communication with other devices, and the like. The oil supply control device 25 is connected to the liquid feeding device 21, the flow rate measuring device 22, the nozzle switch 23, and the oil supply indicator 24 by signal connection or data connection, and the point-of-sale management provided in the gas station together with the oil supply device 10. A refueling terminal (not shown) of the system (filling station POS) is also connected for communication so that signals and data can be transmitted and received with each other. Further, in the self-service type gas station where the customer himself operates the fuel supply nozzle 30 to perform the fuel supply operation, the fuel supply control device 25 is connected to a fuel supply management machine (not shown) provided in the gas station office, respectively. Communication connection is made so that signals and data can be transmitted and received.

  The refueling control device 25 receives the refueling work conditions set by the refueling terminal at the start of the refueling work from the refueling terminal, and receives the refueling permission supplied from the refueling terminal or the refueling management machine. In order to perform the refueling operation of the set oil type included in the work conditions, each part of the oil supply system corresponding to the set oil type and the oil supply indicator 24 are controlled to operate.

  Therefore, in the refueling work, when the refueling terminal sets the refueling work conditions at the start of the work and the refueling control device 25 receives the permission, the worker who is an employee or customer of the fuel supply station If the oil supply nozzle 30 is taken out from the nozzle housing part 40, the nozzle tip is inserted into the oil supply port of the vehicle or the like and the operation lever is opened, the oil liquid is discharged and the fuel is supplied to the fuel tank of the vehicle or the like. Can do.

  At this time, when the oil supply nozzle 30 of the set oil type is taken out from the nozzle storage unit 40, the detection signal in the non-storage state is supplied from the nozzle switch 23. The oil supply control device 25 starts the fuel supply to the taken-out oil supply nozzle 30 by operating the liquid supply device 21 of the oil supply system corresponding to the set oil type according to the detection signal of the non-storage state. As a result, when the operator opens the operation lever of the fuel supply nozzle 30, the oil liquid is discharged from the tip of the nozzle cylinder, and the fuel supply to the fuel tank is started. In this manner, the amount of fuel liquid supplied from the fueling nozzle 30 to the fuel tank of the vehicle or the like is measured by the flow rate measuring device 22 and is displayed on the fueling indicator 24 as needed by the fueling control device 25.

  Thereafter, when refueling to the fuel tank of the vehicle or the like is completed, the operator closes the operation lever of the refueling nozzle 30 and returns the refueling nozzle 30 to the nozzle storage unit 40 for storage. The oil supply control device 25 determines the end of the oil supply operation based on the storage state detection signal supplied from the nozzle switch 23 when the oil supply nozzle 30 is stored in the nozzle storage unit 40. For example, if the liquid supply device 21 is not stopped at the end of automatic control stop refueling such as preset fuel supply, the oil supply control device 25 stops the operation of the liquid supply device 21 and then supplies oil. The amount of refueling work data is transmitted to the refueling terminal, and a slip is issued for the current refueling fraud work.

  As described above, in the refueling operation using the refueling device 10, the nozzle operation by the operator is indispensable, and it is indispensable to take out the refueling nozzle 30 from the nozzle storage unit 40 and hang it back (storage) to the nozzle storage unit 40. It becomes. However, in a gas station in a cold region where wind and snow are severe, the oil supply nozzle 30 cannot be taken out and returned when it is frozen by snow or the like attached to the nozzle while being stored in the nozzle storage unit 40. There arises a problem that the nozzle switch 23 thus made does not respond to taking out or hooking of the fuel nozzle 30.

  Therefore, in the fuel supply apparatus 10 according to this embodiment shown in FIG. 1, the nozzle storage unit 40 includes a nozzle storage unit 40 and a nozzle cover 60 that can be opened and closed to cover the fuel supply nozzle 30 stored in the nozzle storage unit 40. Is attached.

  FIG. 2 is a perspective view illustrating a configuration of a nozzle housing portion to which a nozzle cover is attached.

  In FIG. 2, for the sake of convenience, the portion that appears outside the apparatus main body is represented by a solid line, and the portion that is located inside the apparatus main body 11 and does not appear outside the apparatus main body is represented by a dotted line. FIG. 2 shows a cover open state in which the nozzle cover 60 is opened by an operator, and the fuel nozzle 30 stored in the nozzle storage unit 40 appears outside and can be taken out. The oil supply nozzle 30 is represented by omitting the oil supply hose 20.

  Normally, as shown in FIG. 2, the oil supply nozzle 30 is configured to include a main body accommodating portion 31, a discharge pipe 32, a gripping portion 33, and a lever guard portion 34.

  The main body accommodating portion 31 accommodates a nozzle valve mechanism including an on-off valve (main valve) that responds to the operation of the operation lever 35. The discharge pipe 32 is an insertion portion into the fuel filler port of the fuel tank, extends from the main body housing portion 31 and constitutes the nozzle tip side. The gripping portion 33 is a portion where the operator grips the fueling nozzle 30 during the fueling operation, and extends from the main body accommodating portion 31 in a direction different from the extending direction of the discharge pipe 32, and constitutes the nozzle base end side. . The lever guard 34 is a protective frame for protecting the operation lever 35 that opens and closes the main valve of the nozzle valve mechanism, and is attached to the main body housing 31 and the grip 33.

  In order to accommodate and hold the fuel filler nozzle 30, the nozzle accommodating portion 40 is configured to include a discharge pipe accommodating portion 41 and a placement portion 42 in the illustrated example.

  The discharge pipe accommodating portion 41 includes a nozzle boot portion 41a in which the discharge pipe 32 on the nozzle tip side is inserted and accommodated. When the nozzle storage portion 40 is attached to the apparatus main body 11, the nozzle boot portion 41 a of the discharge pipe storage portion 41 protrudes into the apparatus main body and faces the outside of the apparatus main body so as to face the opening and the inside of the nozzle boot portion 41 a. A peripheral surface appears.

  The mounting portion 42 supports the oil supply nozzle 30 in which the discharge pipe 32 is accommodated in the discharge pipe accommodation portion 41, and the posture state of the supported oil supply nozzle 30 is around the axis of the discharge pipe 32 and the grip portion 33. Hold it so that it does not rotate. In the illustrated example, the mounting portion 42 includes a support groove 42 a in which specific portions of the main body housing portion 31 and the lever guard portion 34 of the fuel supply nozzle 30 are loosely fitted. The bottom surface of the support groove 42 a serves as a support portion for the oil supply nozzle 30, and the groove side surface serves as a holding portion for the posture state of the oil supply nozzle 30. Although not shown, the mounting portion 42 is also provided with a nozzle switch 23 for detecting the storage state / non-storage state of the fuel supply nozzle 30, or an operating piece and a detection portion of the nozzle switch 23.

  In the illustrated example, the nozzle storage portion 40 is configured to be attached to an attachment hole formed in the main body panel of the apparatus main body 11 via a frame member 50. The frame member 50 includes a discharge pipe insertion port 51 for allowing the opening of the nozzle boot portion 41a to face the outside of the apparatus main body, and a mounting portion fitting for fitting the mounting portion 42 so that the support groove 42a faces the outside of the apparatus main body. And a joint portion 52.

  In attaching the nozzle storage unit 40 to the apparatus main body 11, the discharge pipe storage unit 41 is previously attached to the frame member 50 by aligning the opening of the nozzle boot portion 41 a with the discharge pipe insertion port 51 of the frame member 50 in advance. It is fixed. On the other hand, the mounting portion 42 is attached and fixed to the frame of the apparatus main body 11 in advance. In addition, the nozzle storage section 40 is assembled by assembling the frame member 50 integrated with the discharge pipe storage section 41 into the mounting hole of the main body panel of the apparatus main body 11 and assembling the main body panel to the frame of the apparatus main body 11. The support groove 42a of the mounting portion 42 faces the outside of the apparatus main body from the mounting portion fitting portion 52 of the frame member 50, and the discharge pipe accommodating portion 41 and the mounting portion 42 are integrated via the frame member 50. Thus, the nozzle housing 40 is attached and fixed to the apparatus main body 11 (for details, see Japanese Patent Application Laid-Open No. 2004-123120 (Patent No. 4101007) filed earlier by the applicant of the present application).

  In the present embodiment, the frame member 50 that integrates the discharge pipe storage portion 41 and the mounting portion 42 that constitute the nozzle storage portion 40 is an attachment destination of the nozzle cover 60. Therefore, the frame member 50 is also formed with an attachment positioning portion 53 of the nozzle cover 60, a cover inner surface regulating portion 54, and the like.

  FIG. 3 is a configuration diagram of the nozzle cover. FIG. 3A is a front view of the nozzle cover when the apparatus main body is viewed from the front facing the refueling indicator, FIG. 3B is a right side view of the nozzle cover, and FIG. The top view of a nozzle cover is shown, respectively.

  The nozzle cover 60 is formed by molding a resin material, for example, and is transparent or semi-transparent so that the oil supply nozzle 30 in the storage state in the nozzle storage portion 40 can be visually recognized. In the illustrated example, the nozzle cover 60 is attached to a frame member 50 that is integrated with the discharge pipe accommodating portion 41 and the placement portion 42 to form the nozzle accommodating portion 40 so as to be freely opened and closed.

  The nozzle cover 60 includes a front portion of the oil supply nozzle 30 when the device main body 11 is viewed from the front in a state where the oil supply nozzle 30 is shielded by the nozzle storage portion 40, and a discharge pipe of the nozzle storage portion 40 including the frame member 50. A cover front portion 60t that covers the front portion of the storage portion 41 and the mounting portion 42, and each portion 31, 32, 33, 34 of the fuel supply nozzle 30 that protrudes in the front direction from the main body panel surface of the apparatus main body 11 in the storage state. The side surface portion and the cover peripheral portion 60s that covers the discharge pipe housing portion 41 of the nozzle housing portion 40 and the side surface portion of the mounting portion 42 have a composite curved surface structure formed integrally. As a result, the nozzle cover 60 accommodates the portions of the oil supply nozzle 30 and the nozzle storage portion 40 that protrude in the front direction from the main body panel surface of the device main body 11 on the back side viewed from the front side in a non-contact state with the cover closed. It is the structure which forms the hollow accommodation space 61 for doing.

  In addition, the upper cover portion 60u when the nozzle cover 60 is viewed from the front, surrounded by a one-dot chain line in the drawing, has an attachment portion 62 for attaching the nozzle cover 60 to the nozzle storage portion 40 so as to be rotatable. It is formed in the cover peripheral part 60s. The upper cover portion 60u has a shape that does not hinder the cover from rotating so that the nozzle cover 60 is in the cover open (cover open) state when the cover is closed after being attached to the nozzle storage portion 40.

  Similarly, in the drawing, the lower cover portion 60d when the nozzle cover 60 is viewed from the front, surrounded by a one-dot chain line, is connected to the revolving hose 20 or the revolving joint of the refueling nozzle 30 to which the refueling hose 20 is connected. Is formed between the inside and outside of the nozzle cover 60.

  Further, the cover inner surface restricting portion 54 of the frame member 50 and the inner surface of the cover come into contact with the nozzle cover 60 when the cover is closed after being attached to the nozzle storage portion 40, and the nozzle cover 60 is closed when the cover is closed. A cover closing posture restricting portion 64 for uniformly defining the posture so as to have no difference is also formed.

  Next, the attachment structure with respect to the nozzle accommodating part 40 of the nozzle cover 60 is demonstrated based on FIG.4 and FIG.5.

  FIG. 4 is an explanatory diagram of a rotation mechanism that rotatably attaches the nozzle cover to the nozzle storage portion. FIG. 4A is a perspective view of the nozzle storage portion with the nozzle cover removed, and FIG. 4B is a configuration diagram of each part constituting the rotation mechanism. FIG. 4C is a view showing a rotation restriction state related to the cover opening direction of the nozzle cover in the rotation mechanism. In FIG. 4A, the discharge pipe accommodating portion 41 of the nozzle accommodating portion 40 is not shown.

  As shown in FIG. 4 (A), a discharge pipe insertion port that is an upper part when viewed from the front of a frame member 50 for integrating the discharge pipe housing part 41 and the mounting part 42 to form the nozzle housing part 40. An attachment hole 55 on the nozzle storage portion 40 side of the rotation mechanism 70 is formed at the end portion on the 51 side or its peripheral portion. The attachment hole 55 also serves as an attachment positioning portion 53 for the nozzle cover 60 with respect to the nozzle storage portion 40.

  When the nozzle cover 60 moves (displaces) from the cover open position to the cover close position, in other words, the rotation mechanism 70 moves the cover when the nozzle cover 60 in the cover open state is in the cover closed state (cover displacement). It is configured to include a deceleration function unit that reduces the speed) with respect to the cover moving speed (cover displacement speed) generated based on the gravitational acceleration in the open position (cover open state) at that time. The deceleration function unit of the rotation mechanism 70 is a lock function unit that prevents the nozzle cover 60 in a closed state from being rattled by being lifted by a strong wind, or the nozzle cover 60 from vibrating and generating noise. It also has a function.

  In the illustrated example, the rotation mechanism 70 connects the mounting fixing plate 71 on the nozzle housing 40 side, the mounting fixing plate 72 on the nozzle cover 60 side, and both the mounting fixing plates 71 and 72 so as to be able to rotate, and decelerates. And a speed reduction shaft mechanism portion 80 that constitutes a functional portion and a lock functional portion.

  The mounting fixing plate 71 on the nozzle housing portion 40 side is formed of a rigid plate material bent in an L shape. A bent portion on one side of the mounting fixing plate 71 serves as an mounting fixing portion 71a for the frame member 50 of the nozzle housing portion 40, and is positioned and tightened such as a screw or a bolt according to the mounting hole 55 formed in the frame member 50. An attachment hole for the attachment member 73 is formed. The bent portion on the other side of the mounting fixing plate 71 serves as a fixed connecting portion 71b for the speed reduction shaft mechanism portion 80, and is connected to the nozzle storage portion side fixing portion 81 of the speed reduction shaft mechanism portion 80 by a fastening member such as a screw or a bolt. Fixed. The mounting and fixing plate 71 on the nozzle housing 40 side is positioned and fixed to the frame member 50 by the positioning and fastening member 73, and the rotation of the plate surface of the fixed connecting portion 71 b is related to the opening direction of the nozzle cover 60. It becomes surface 74.

  On the other hand, the attachment fixing plate 72 on the nozzle cover 60 side is constituted by a rigid member bent in an L shape at a plurality of locations. The mounting fixing plate 72 is bent in an L shape with respect to the fixed connecting portion 72a with respect to the reduction shaft mechanism portion 80 formed of a bent portion on one side bent in an L shape. A relay part 72b composed of another bent part, a pair of nozzle cover fixing parts 72c extending from both sides in the width direction of the relay part 72b and folded into an L shape with respect to the relay part 72b, and in a bent state Each nozzle cover fixing portion 72c has a pair of rotation restricting pieces 72d extending so as to protrude from the plate surface of the fixed connecting portion 72a. The fixed connecting portion 72a is fixed to the nozzle cover side fixing portion 82 of the reduction shaft mechanism portion 80 by a fastening member such as a screw or a bolt, for example. A pair of nozzle cover fixing | fixed part 72c is fixed by fitting the attaching part 62 of the nozzle cover 60, and the positioning fixing member 75 to both. The pair of nozzle cover fixing portions 72 c defines the mounting posture state of the nozzle cover 60 with respect to the nozzle cover side fixing portion 82 of the reduction shaft mechanism portion 80. As the nozzle cover 60 rotates, the rotation restricting piece 72d abuts against the rotation restricting surface 74 of the mounting fixing plate 71 on the nozzle housing portion 40 side as shown in FIG. The rotation posture in the cover opening direction is regulated in cooperation.

  The reduction shaft mechanism unit 80 has a nozzle housing portion side fixing portion 81, a nozzle cover side fixing portion 82, and a reduction shaft 83.

  The nozzle housing portion side fixing portion 81 has a fixing plate mounting surface 81 a formed on one side and the other side serving as a fixing mounting portion 81 b of the reduction shaft 83. The nozzle cover side fixing portion 82 has a fixing plate attachment surface 82 a formed on one side, and the other side is an engagement attachment portion 82 b with the reduction shaft 83. The speed reduction shaft 83 regulates a relative rotation range between the nozzle storage portion side fixing portion 81 and the nozzle cover side fixing portion 82, that is, a relative rotation range of the nozzle cover 60 with respect to the nozzle storage portion 40. Both are pivotally supported.

  FIG. 5 is a configuration diagram of an embodiment of a reduction shaft provided in the reduction shaft mechanism portion of the rotation mechanism. 5A is a perspective view showing the external configuration of the reduction shaft, FIG. 5B is a perspective view showing the internal configuration of the bearing housing of the reduction shaft, and FIG. 5C is a view of the shaft member. FIG. 5D is a perspective view showing an external configuration, and FIG. 5D is a cross-sectional view showing a cross-sectional configuration perpendicular to the extending direction of the reduction shaft.

  The speed reduction shaft 83 is configured by assembling a shaft member 85 to a bearing housing 84 shown in FIG. 5B so as to be rotatable within a predetermined rotation range as shown in FIG. 5D.

  As shown in FIG. 5 (B), the bearing housing 84 has a small-diameter shaft support hole 84a at both ends in the axial direction, and a shaft support hole 84a between the shaft support holes 84a on both ends. In addition, a liquid storage hole 84b for storing an incompressible fluid having a large diameter (for example, oil for generating hydraulic pressure, not shown) is formed. The shaft support holes 84a and the liquid storage holes 84b are coaxially connected along the axial direction, and the shaft support holes 84a open from the axial end surface of the bearing housing 84 to the outside. As a result, the bearing housing 84 is configured such that one shaft support hole 84a, the liquid storage hole 84b, and the other shaft support hole 84a are sequentially arranged along the axial direction, and the shaft member through hole is provided therethrough. It has a structured.

  In addition, the liquid storage hole 84b of the bearing housing 84 protrudes from a predetermined angular position on the inner peripheral surface thereof in the radial direction so as to slide with a shaft main body portion 85a described later of the shaft member 85. And the rotation control part 86 which controls the rotation range of the shaft member 85 is formed.

  Thereby, the inner peripheral surface of each shaft support hole 84a of the bearing housing 84 becomes a shaft support portion 87 that rotatably supports the shaft member 85 via a seal member (not shown), and a rotation restricting portion 86 is formed. The liquid storage hole 84b thus formed serves as a resistance generator 88 that generates resistance when the speed reduction shaft 83 rotates.

  On the other hand, the shaft member 85 is configured to include a shaft main body portion 85a and a partition wall portion 85b. The shaft body 85a is rotatably supported by the shaft support 87 of the bearing housing 84 and penetrates the shaft member through hole. The partition wall portion 85b extends radially outward from a predetermined angular position on the outer peripheral surface of the shaft main body 85a over the axial length position of the shaft main body portion 85a corresponding to the liquid storage hole 84b of the bearing housing 84. The bearing housing 84 protrudes from the inner periphery of the liquid storage hole 84b and divides the liquid storage hole 84b of the bearing housing 84 into two chambers. The partition wall portion 85b increases in volume when the cover is opened, while the first liquid storage chamber 91 is reduced in volume when the cover is closed, and increases in volume when the cover is closed, while the volume is reduced when the cover is moved. A second liquid storage chamber 92 is formed.

  Furthermore, a check valve 93 and an orifice 94 are provided in the partition wall portion 85b so as to communicate between the first liquid storage chamber 91 and the second liquid storage chamber 92.

  The check valve 93 moves the cover opening movement of the incompressible fluid stored in the second liquid storage chamber 92 whose volume is increased when the cover is closed from the cover opening position of the nozzle cover 60 to the cover closing position. When the hydraulic pressure value of the incompressible fluid stored in the second liquid storage chamber 92 becomes equal to or higher than a predetermined pressure in conjunction with the (cover opening displacement), the valve closing state is changed to the valve opening state. The check valve 93 is configured to allow the incompressible fluid stored in the second liquid storage chamber 92 to flow into the first liquid storage chamber 91 side. In other words, the check valve 93 stores the inflow of the incompressible fluid stored in the second liquid storage chamber 92 toward the first liquid storage chamber 91 in the second liquid storage chamber 92. It is configured to block regardless of the hydraulic state of the incompressible fluid.

  On the other hand, the orifice 94 always communicates between the first liquid storage chamber 91 and the second liquid storage chamber 92.

  In the rotation mechanism 70 configured as described above, the bearing housing 84 of the speed reduction shaft 83 is attached and fixed to the nozzle storage portion side fixing portion 81 of the speed reduction shaft mechanism portion 80, and as a result, the nozzle storage portion side fixing portion 81. And is fixedly attached to the frame member 50 of the nozzle housing 40 via the. On the other hand, the shaft member 85 of the speed reduction shaft 83 is engaged and fixed to the nozzle cover side fixing portion 82 of the speed reduction shaft mechanism portion 80, and as a result, is engaged and fixed to the nozzle cover 60 via the nozzle cover side fixing portion 82. ing.

  Thereby, in the rotation mechanism 70, the shaft member 85 of the speed reduction shaft 83 is linked to the rotation of the nozzle cover 60 when the nozzle cover 60 is moved and when the cover is closed. An attempt is made to rotationally displace the body 84. At that time, the incompressible fluid stored in the volume-reducing side of either the first liquid storage chamber 91 or the second liquid storage chamber 92 tries to rotate the nozzle cover 60. It is pressed by the partition wall portion 85b of the shaft member 85 with the operating force. This pressing increases the hydraulic pressure on the side where the volume is reduced. As a result, the incompressible fluid stored on the side whose volume is reduced by the rotation of the nozzle cover 60 passes through the orifice 94 provided on the partition wall portion 85b of the shaft member 85 or the check valve 93 and the orifice 94. Then, it flows into the other side of the first liquid storage chamber 91 or the second liquid storage chamber 92 that is not pressed through the partition wall portion 85b and whose volume is enlarged. In this way, the shaft member 85 of the deceleration shaft 83 tries to suppress an increase in the hydraulic pressure of the incompressible fluid stored on the side whose volume is reduced by the rotation of the nozzle cover 60.

  FIG. 6 is a diagram illustrating a state of the nozzle cover and the rotation mechanism at the cover closed position of the nozzle cover.

  FIG. 7 is a view showing a state of the nozzle cover and the rotation mechanism at the cover half-closed (cover half-open) position of the nozzle cover.

  FIG. 8 is a diagram illustrating a state of the nozzle cover and the rotation mechanism at the cover open position of the nozzle cover.

  6, 7, and 8, (A) is an external perspective view of the nozzle housing portion at each movement position with the nozzle cover attached, and (B) is each movement. FIG. 8C is a diagram showing the state of the first liquid storage chamber and the second liquid storage chamber in the rotation mechanism at each movement position.

  As a result, when the nozzle cover 60 is moved open, the volume in the first liquid storage chamber 91 is reduced and the volume in the second liquid storage chamber 92 is expanded from the first liquid storage chamber 91 side. The check valve opened due to the increase in the hydraulic pressure in the first liquid storage chamber 91 is the distribution movement of the incompressible fluid stored in the first liquid storage chamber 91 to the second liquid storage chamber 92 side. 93 and the orifice 94. Accordingly, since the flow of the incompressible fluid is performed by both the check valve 93 and the orifice 94, when the nozzle cover 60 is moved from the closed state to the open state, the operator can perform the opening operation without any burden. it can.

  Conversely, when the nozzle cover 60 is closed, the volume in the second liquid storage chamber 92 is reduced and the volume in the first liquid storage chamber 91 is increased from the second liquid storage chamber 92 side. The movement of the incompressible fluid stored in the second liquid storage chamber 92 toward the first liquid storage chamber 91 is caused by the check valve 93 even if the liquid pressure in the second liquid storage chamber 92 increases. Since the valve remains closed, the operation is performed only through the orifice 94.

  Therefore, if the valve opening pressure of the check valve 93 is appropriately set, when the operator performs the cover opening operation of the nozzle cover 60, the check valve 93 is opened, and the second storage chamber 91 side opens the second liquid storage chamber 91 side. The distribution movement of the incompressible fluid stored in the first liquid storage chamber 91 toward the liquid storage chamber 92 is performed through both the opened check valve 93 and the orifice 94. As a result, the incompressible fluid that is stored in the first liquid storage chamber 91 and whose hydraulic pressure increases when the operator opens the cover of the nozzle cover 60 causes the check valve 93 to be opened once the check valve 93 is opened. As much as the valve is opened, a large amount can be discharged from the first liquid storage chamber 91, and the shaft member 85 can be smoothly rotated in the bearing housing 84. As a result, even though the rotational force acting on the nozzle cover 60 is the same, the rotational speed of the shaft member 85 in the bearing housing 84, that is, the nozzle cover, compared to the case where only the orifice 94 is communicated. The rotational speed of 60 can be increased, and the nozzle cover 60 can be smoothly moved open. In addition, since only the orifice 94 is in communication until the incompressible fluid stored in the first liquid storage chamber 91 reaches a hydraulic pressure at which the check valve 93 is opened, the check valve 93 is opened. Compared to the case, the flow rate of the incompressible fluid flowing out from the first liquid storage chamber 91 to the second liquid storage chamber 92 is limited.

  Thereby, it is possible to simultaneously prevent the nozzle cover 60 in the closed state from being loosened by strong wind.

  On the other hand, if the valve opening pressure of the check valve 93 is appropriately set, the cover closing operation when the operator releases the hand from the nozzle cover 60 causes the first pressure by the pressing force based on the gravitational acceleration due to the weight of the nozzle cover 60. Even if the hydraulic pressure of the incompressible fluid in the second liquid storage chamber 92 increases, the check valve 93 does not open, and the second liquid storage chamber 92 side to the first liquid storage chamber 91 side The distribution movement of the incompressible fluid stored in the second liquid storage chamber 92 is performed only through the orifice 94.

  As a result, even though the rotational force acting on the nozzle cover 60 is the same, the shaft member in the bearing housing 84 is compared to the case where both the orifice 94 and the opened check valve 93 communicate with each other. The rotational speed of 85, that is, the rotational speed of the nozzle cover 60 can be slowed down, and the opening movement of the nozzle cover 60 can be stagnated.

  As a result, even if the hand is released from the nozzle cover 60 in the cover open state, while the nozzle cover 60 moves slowly to the cover closing position, the grip part 33 of the oil supply nozzle 30 is gripped by the hand released from the cover, and the oil supply is performed. The nozzle 30 can be taken out from the nozzle accommodating portion 40.

  Therefore, even if the nozzle cover 60 is configured so as to cover the entire portion including the gripping portion 33 of the fuel filler nozzle 30, the gripping portion 33 is supported by the other hand while supporting the nozzle cover 60 so as not to return to the cover closed state with one hand. Even if the hand is not taken out from the nozzle housing part 40 of the refueling nozzle 30, the hand is released from the opened nozzle cover 60, and while the nozzle cover 60 moves slowly to the cover closing position, The oil supply nozzle 30 can be taken out from the nozzle housing part 40 by grasping the grip part 33 of the oil supply nozzle 30.

  As a result, even if the nozzle cover 60 can be entirely covered, including the gripping portion 33 of the fuel nozzle 30, the operator can open the nozzle cover 60 with only one hand and place the fuel nozzle 30 in the nozzle housing 40. Can be taken out from. Therefore, even in a cold region where wind and snow are severe, the snow does not adhere to the grip portion 33 of the fueling nozzle 30, and the operational comfort of the fueling nozzle 30 is not impaired.

  Further, when the fuel supply nozzle 30 is taken out from the nozzle housing portion 40, the nozzle cover 60 that is in the cover open state is connected only through the orifice 94 from the second liquid storage chamber 92 side to the first liquid storage chamber 91 side. Since the nozzle cover 60 automatically returns to the closed state by the cover closing movement, snow or the like on the nozzle storage portion is also taken from when the nozzle is taken out of the nozzle storage portion until the nozzle is stored in the nozzle storage portion. Can be prevented, and the nozzle cover can also be prevented from rattling due to strong winds.

DESCRIPTION OF SYMBOLS 10 Oil supply apparatus, 11 apparatus main body, 12 apparatus accommodating part, 13 display apparatus accommodating part,
20 Refueling hose, 21 Liquid feeding device, 22 Flow rate measuring device,
23 nozzle switch, 24 lubrication indicator, 25 lubrication control device,
30 refueling nozzle, 31 body housing, 32 discharge pipe,
33 gripping part, 34 lever guard part, 40 nozzle storage part,
41 discharge pipe housing part, 41a nozzle boot part,
42 mounting portion, 42a support groove 50 frame member, 51 discharge pipe insertion port,
52 mounting section fitting section, 53 mounting positioning section, 54 cover inner surface regulating section,
55 mounting hole, 60 nozzle cover, 60t cover front part,
60s cover peripheral part, 60u upper cover part, 60d lower cover part,
61 hollow housing space, 62 mounting portion, 63 passage port,
64 cover closing posture restricting portion, 70 rotating mechanism 71 mounting fixing plate, 71a mounting fixing portion, 71b fixing connecting portion,
72 mounting fixing plate, 72a fixed connecting portion, 72b relay portion,
72c Nozzle cover fixing part, 72d rotation restricting piece, 73 positioning fastening member,
74 rotation restricting surface, 75 positioning fixing member, 80 decelerating shaft mechanism,
81 Nozzle housing side fixing portion, 81a Fixing plate mounting surface, 81b Fixing mounting portion,
82 nozzle cover side fixing portion, 82a fixing plate mounting surface, 82b engagement mounting portion,
83 Deceleration shaft, 84 Bearing housing, 84a Shaft support hole, 84b Liquid storage hole,
85 shaft member, 85a shaft body portion, 86 rotation restricting portion, 85b partition wall portion,
87 shaft support, 88 resistance generator, 91 first liquid storage chamber,
92 Second storage chamber, 93 Check valve, 94 Orifice

Claims (3)

A nozzle connected to the fuel supply port of the fuel supply target and supplying fuel to the fuel supply target;
A fuel supply path for supplying fuel to the nozzle;
A nozzle housing part that is provided in a housing having the fuel supply path and houses the nozzle;
In a fuel supply device comprising a nozzle cover that is formed so as to cover the nozzle housing part and that can be opened and closed with respect to the nozzle housing part,
A reduction mechanism is provided for reducing the cover moving speed when the nozzle cover in the cover open state is in the cover closed state with respect to the cover moving speed generated based on the gravitational acceleration in the cover open state at that time. A fuel supply device. The deceleration mechanism is
A first and a second liquid storage chamber in which the volume is reciprocally expanded or contracted according to the cover open state or the closed state, and incompressible liquid is stored;
A check valve and an orifice provided to communicate the first and second liquid storage chambers;
Have
When the cover of the nozzle cover is in a closed state, the check valve causes the incompressible liquid stored in the liquid storage chamber in the expanded state among the first and second liquid storage chambers to close the cover of the nozzle cover. 2. The fuel supply device according to claim 1, wherein the fuel supply device is provided so as to be blocked from flowing into the liquid storage chamber in a contracted state by movement. In the deceleration mechanism,
3. The fuel supply device according to claim 1, wherein a restriction portion that restricts a rotation range of the nozzle cover with respect to the nozzle housing portion is formed.

Images