JP7256966B2 - Nozzle hook for lubricator - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a nozzle hook for a fueling device that supplies fuel oil or the like to a vehicle or the like. More particularly, the present invention relates to a nozzle hanger provided with a nozzle switch that operates (turns on and off) in conjunction with hooking and unhooking of a fuel nozzle, and relates to a nozzle hanger of a fueling device that can always operate the nozzle switch accurately.

In a refueling device installed at a refueling station or the like, a refueling nozzle provided at the tip of a refueling hose is removed from a nozzle hook, and the refueling nozzle is inserted into a refueling port of a vehicle to refuel the fuel tank.
The nozzle hook of the fueling device is provided with a nozzle switch that detects whether the fueling nozzle is engaged (engaged) or disengaged. Starts or stops the lubrication pump and controls the return to zero of the indicator.
As a conventional technique, a non-contact nozzle switch using magnetic lines of force or light has been proposed (see Patent Document 1).

In the prior art (Patent Document 1), a non-contact nozzle switch using a magnet is disclosed. The lines of magnetic force decreased, and the decrease in the lines of magnetic force degraded the detection accuracy for detecting that the nozzle switch is in the "on" state. There is a danger of being lost.
On the other hand, when the prior art (Patent Document 1) is applied in an extremely cold region, the magnetic lines of force emitted from the magnet increase or rise due to the decrease in the temperature of the magnet, and as a result, the nozzle switch is in the "OFF" state. There is a possibility that the detection accuracy for detecting this will be lowered and the fuel pump will not be able to be stopped.
In addition, there is a device containing a magnetic material around the nozzle switch, such as the housing body of a lubricating device. There is also the possibility that the detection accuracy will deteriorate.

Furthermore, since the nozzle switch is arranged on the front side of the frame on the side surface of the housing main body (the side away from the fuel supply device), the nozzle switch projects to the front side of the frame. Therefore, during maintenance work or the like, a worker may be injured by contacting the protruding nozzle switch.

International Publication WO2018/025455A1

The present invention has been proposed in view of the above-mentioned problems of the prior art. To provide a nozzle hanger for a lubricating device in which a line of magnetic force is reliably transmitted to or interrupted from a switch part, whereby the nozzle switch always operates accurately.

The nozzle hanger (1) of the lubricating device (100) of the present invention is
a hood (2) holding a discharge pipe (21) of a fuel nozzle (20);
Having a receiving portion (3) for holding a lever guard (22) of the fuel nozzle (20),
The lever switch (15) abutting on the lever guard (22) has a switch operating piece (16), and the switch operating piece (16) is interlocked with the engagement/disengagement of the fuel nozzle (20). ) and has a switch portion (4) that operates when the switch actuation piece (16) is pressed,
The switch section (4) has a non-detection section (5) that emits magnetic lines of force and a detection section (6) that detects the magnetic lines of force emitted from the non-detection section (5). and the detection part (6) are disposed at positions facing each other with a gap in the nozzle hook (1) of the fueling device (100),
When the refueling nozzle (20) is removed from the nozzle hook (1), a conductive member (7 ) activates the switch section (4),
The conducting member (7) is movable to a position adjacent to the non-detecting part (5) and is made of a ferromagnetic material. an attached bolt (9) and a second folding member (10) attached to the bolt (9) and made of a ferromagnetic material and movable to a position adjacent to the detection part (6). equipped with
When the refueling nozzle (20) is disengaged from the nozzle hook (1), the lines of magnetic force emitted from the non-detecting portion (5) are directed to the first bending member (8), the bolt (9) and the second bending member (8). is transmitted to the detector (6) via the bending member (10) .

In the present invention, a rotating member (11) is provided, and the rotating member (11) is in a state in which the fuel nozzle (20) is locked to the nozzle hook (1) and/or is connected to the panel (100) from the fueling device (100). 18) is removed (when the panel 18 is open), it is located between the non-detecting part (5) and the detecting part (6), and the non-detecting part of the rotating member (11) It is preferable that ferromagnetic bodies (11A, 11B) are arranged at locations adjacent to (5).
Here, the cross-sectional area of the ferromagnetic material is preferably larger than that of the ferromagnetic material in the prior art (Patent Document 1), preferably 1.8 times or more.

In the present invention, a member (mechanical part for a switch) for blocking magnetic lines of force from the non-detecting portion (5) to the detecting portion (6) in a state where the fuel nozzle (20) is engaged with the nozzle hook (1). and a member ( mechanical parts for maintenance) are integrated as a rotating member (11), and the nozzle switch (4) is arranged on the back of the frame (19) (for example, on the side) of the housing body of the oil supply device (100). is preferred.

In the present invention, the rotary member (11) is rotated by pressing the switch operating piece (16) against the lever switch (15)
a first position where (the rotating member 11) is not pressed when the panel (18) is removed from the fueling device (100) (the panel 18 is open);
From the state of the first position, when the panel (18) is attached to the fueling device (100) (the panel 18 is closed) and the fueling nozzle (20) is removed from the nozzle hook (1), the switch actuating piece a second position where the first pressing piece (16A) at the tip of (16) presses the first pressure receiving piece (11C) of the rotating member (11);
When the fuel nozzle (20) is engaged with the nozzle hook (1) from the second position, the second pressing piece (16B) of the switch operating piece (16) is pushed to the second position of the rotating member (11). The rotating member (11) rotates to the third position for pressing the pressure receiving piece (11D) of
A stopper (17) is preferably provided for stopping the rotating member (11) at the third position.

According to the present invention having the above-described configuration, the conductive member (7) is provided at a location different from the detection section (6), and the line of magnetic force emitted from the non-detection section (5) is transmitted in the conductive section. can be strengthened, the lines of magnetic force emitted from the non-detecting portion (5) can be transmitted to the detecting portion (6) via the conducting member (7). Therefore, even if the temperature of the magnet of the nozzle switch (4) rises and the lines of magnetic force emitted from the non-detection part (5) decrease, the on/off state of the nozzle switch (4) can be reliably detected. Therefore, it is possible to accurately drive and stop the oil supply pump and perform the work necessary for oil supply.

In the present invention, the conducting member (7) includes a first bending member (8) which is movable to a position adjacent to the non-detecting portion (5) and which is made of a ferromagnetic material, and a first bending member (8). a bolt (9) attached to (8) and a second folding member (10) attached to the bolt (9) and made of ferromagnetic material and movable to a position adjacent to the detector. When the fuel nozzle (20) is disengaged from the nozzle hook (1), the magnetic lines of force emitted from the non-detecting portion (5) are directed to the first bending member (8), the bolt (9 ), if it is configured to be transmitted to the detection unit (6) via the second bending member (10), not only the temperature change of the magnet but also the magnetic material around the nozzle switch (4) Even if the configured member exists, the magnetic lines of force generated in the non-detecting portion (5) are reliably transmitted to the detecting portion (6) through the conducting portion (conducting member 7) adjacent to the non-detecting portion (5). It is possible to reliably detect whether the nozzle switch (4) is turned on or off. In other words, even if the magnetic lines of force emitted from the non-detecting portion (5) are weakened and become unstable, since the conducting portion (conducting member 7) is adjacent to the non-detecting portion (5), the first The lines of magnetic force can be reliably transmitted to the detecting section (6) via the bending member (8), the bolt (9), and the second bending member (10).
Here, if the conductive portion (conductive member 7) is provided in the direction in which the magnetic lines of force are emitted from the non-detecting portion (5), the magnetic lines of force are more reliably transmitted to the detecting portion (6).

In the present invention, a rotating member (11) is provided, and the rotating member (11) is in a state in which the fueling nozzle (20) is locked to the nozzle hook (11) and/or from the fueling device (100) to the panel ( 18) is removed (when the panel 18 is open), it is located between the non-detecting part (5) and the detecting part (6), and the non-detecting part of the rotating member (11) If a ferromagnetic material is placed adjacent to (5), for example, even if the magnetic lines of force emitted from the permanent magnet become strong in a cold region, the magnetic lines of force emitted from the non-detecting part (5) are blocked by the ferromagnetic material. and prevents it from reaching the detector (6), so that it can be reliably detected that the nozzle switch (4) is "off".
In addition, in the present invention, the rotating member (11) is capable of rotating the non-detecting part (5) and the detecting part (5) even when the panel (18) is removed from the fueling device (100) (when the panel 18 is open). 6), when the panel (18) is removed from the lubricating device (100) (when the panel 18 is open), the non-detecting part (5 ) can prevent the magnetic lines of force emanating from the non-detecting part (5) from reaching the detecting part (6), so that the panel (18) is open. It is possible to reliably prevent the start of refueling at .
Here, if the cross-sectional area of the ferromagnetic material is larger than the cross-sectional area of the ferromagnetic material in the conventional technology (Patent Document 1), preferably 1.8 times or more, the non-detecting part (5) emits The effect of blocking the lines of magnetic force by the ferromagnetic material becomes more reliable.

In the present invention, a member (mechanical part for a switch) for blocking magnetic lines of force from the non-detecting portion (5) to the detecting portion (6) in a state where the fuel nozzle (20) is engaged with the nozzle hook (1). and a member ( If the maintenance mechanical parts) are integrated as the rotating member (11), when the panel (18) is removed from the fueling device (100) during maintenance or the like, the fueling nozzle (20) is removed from the nozzle hook (1). erroneously determined to be in a refuelable state due to the removal of the
Since the nozzle switch (4) is arranged on the rear surface of the frame (19) (for example, on the side) of the housing body of the lubricating device (100), the panel (18) can be attached to the lubricating device (100) as in maintenance. When removed from the frame (19), the nozzle switch (4) located on the back side of the frame (19) is less likely to come into contact with the operator.
Furthermore, since the switch mechanical parts and the maintenance mechanical parts are integrated as the rotary member (11), the number of parts is reduced and assembly is facilitated. In addition, by integrating the rotating member (11) of the mechanical parts for switch and the mechanical parts for maintenance, it is possible to eliminate misjudgment that the nozzle is detached during maintenance (in a state where oil can be supplied) due to a defect in the mechanical parts for maintenance. . Since the nozzle switch (4) is arranged on the side surface of the housing body of the lubrication device (100) and on the rear surface of the frame (19), the risk of a worker contacting the nozzle switch (4) during maintenance is reduced. can be done. Furthermore, integration reduces the number of parts and facilitates assembly.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows the oil supply apparatus to which this invention is applied. It is explanatory drawing which shows the cross section and switch part of a nozzle hanger in the state which removed the panel and removed the fuel supply nozzle from the nozzle hanger. FIG. 3 is an enlarged explanatory view showing the relative positional relationship between the switch portion and the rotating member in the state of FIG. 2; FIG. 4 is an enlarged explanatory view of the relative positional relationship between the switch portion and the rotary member in the state of FIG. 2 as viewed from the direction of arrow A4 in FIG. 3; FIG. 10 is an explanatory perspective view showing the nozzle hanger and the switch section in a state in which the panel is closed and the fuel nozzle is removed from the nozzle hanger; It is explanatory drawing which shows the cross section and switch part of nozzle hanging in the state of FIG. FIG. 7 is an enlarged explanatory view showing the relative positional relationship between the switch section and the rotary member in the states of FIGS. 5 and 6; 7. It is an enlarged explanatory view of the relative positional relationship between the switch portion and the rotating member in the states of FIGS. 5 and 6, viewed from the direction of arrow A8 in FIG. FIG. 10 is an explanatory perspective view showing the nozzle hanger and the switch section in a state in which the panel is closed and the fuel nozzle is locked to the nozzle hanger; FIG. 10 is an explanatory diagram showing a cross-section of a nozzle hanger and a switch portion in the state of FIG. 9; 11 is an enlarged explanatory view showing the relative positional relationship between the switch section and the rotating member in the states of FIGS. 9 and 10; FIG. FIG. 11 is an enlarged explanatory view of the relative positional relationship between the switch portion and the rotary member in the states of FIGS. 9 and 10, viewed from the direction of arrow A12 in FIG. 11; It is an explanatory perspective view showing a state in which the panel is removed. FIG. 10 is an explanatory perspective view showing the nozzle switch with the panel removed;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
In FIG. 1, the entire fueling device to which the nozzle hook 1 of the present invention is applied is indicated by reference numeral 100, and the nozzle hook 1 has a fueling nozzle 20 (see FIGS. 9 and 10: not shown in FIG. 1). is unhooked. Refueling nozzle 20 is provided at the tip of a refueling hose (not shown). When refueling a vehicle (not shown), the refueling nozzle 20 is removed from the nozzle hook 1, the refueling nozzle 20 is inserted into a refueling opening (not shown) of the vehicle, and the fuel tank of the vehicle is refueled.
As will be described later, the nozzle hook 1 of the fueling device 100 is provided with a switch portion 4 (nozzle switch: for example, see FIG. 2; not shown in FIG. 1). It is detected that the fuel nozzle 20 is engaged with the hook 1 or that the fuel nozzle 20 is removed from the nozzle hook 1. - 特許庁Based on the ON/OFF state of the switch unit 4, a control unit (not shown) controls the starting and stopping of a fuel pump (not shown; installed in the fuel supply device 100).
In FIG. 1, a fueling device 100 is provided with three nozzle hooks 1 for locking fueling nozzles (not shown in FIG. 1) of three types of oil provided for different types of oil.
In FIG. 1, the panel 18 is detachably attached to the fuel supply system 100. As shown in FIG. A state in which the panel 18 is removed from the fueling device 100 is shown in FIG. 13, for example.

Next, the nozzle hanger 1 and the switch section 4 in the illustrated embodiment will be described with reference to FIGS. 2 to 14. FIG.
First, referring to FIGS. 2 to 4, the panel 18 is removed (see FIG. 13), and the fuel nozzle 20 (see FIGS. 9 and 10; not shown in FIG. 2) is attached to the nozzle hook 1. I will explain the state removed from.
In FIG. 2, the nozzle hook 1 holds a hood portion 2 that holds a discharge pipe 21 (not shown in FIG. 2) of the fuel nozzle 20, and a lever guard 22 (not shown in FIG. 2) of the fuel nozzle 20. and a switch portion (nozzle switch) generally indicated by reference numeral 4 .
The hood portion 2 is provided in an area above the nozzle hook 1, and the surface of the main body of the nozzle hook 1 is configured by a smoothly curved surface from the hood portion 2 downward.
A claw piece 3A is provided on the receiving portion 3, and the claw piece 3A is urged to protrude (upward in FIGS. 2 and 6) by an unillustrated urging means. When the fuel nozzle 20 is hooked, the claw piece 3A is fitted into a locking hole (not shown) on the lever guard 22 side, and the fuel nozzle 20 is stably held by the nozzle hook 1. As shown in FIG.
The main body of the nozzle hanger 1 and the receiving portion 3 are fixed to the panel 18 (FIGS. 1 and 13) of the fueling device 100 (FIG. 1) by fastening means (not shown). 2, 6 and 10, the panel 18 is arranged to extend in a direction perpendicular to the drawings.

In FIG. 2, the switch section 4 has a non-detecting section 5 that emits magnetic lines of force and a detecting section 6 that detects the magnetic lines of force emitted from the non-detecting section 5. The non-detecting section 5 and the detecting section 6 are spaced apart. are disposed at positions facing each other. The switch portion 4 (the non-detecting portion 5 and the detecting portion 6) is fixed to the housing of the oil supply device 100 (FIG. 1) by fastening means (not shown).
The switch section 4 has a rotating member 11 having a portion extending in the direction of approximately the intermediate position between the non-detecting section 5 and the detecting section 6. The rotating member 11 includes a rotating shaft 11E (constituting a conduction member 7 described later). It rotates (pivots) with respect to the bolt 9 that holds the bolt 9 and maintains a predetermined rotational position. As the predetermined rotational position of the rotating member 11 , a position that does not prevent the magnetic lines of force emitted from the non-detecting portion 5 from reaching the detecting portion 6 (that is, a position where the switch 4 is turned “ON”), and A position that prevents the magnetic lines of force from reaching the detector 6 (that is, a position where the switch 4 is "OFF") is selected.
The configuration and operation of the switch section (4) will be described with reference to FIGS. 3 and 4. FIG.

2 (and FIG. 6), the lever switch 15 rotatably supported by the shaft portion 14 is pushed out of the nozzle hook 1 from the opening 1A of the main body of the nozzle hook 1 by the repulsive force of the biasing means (not shown). It protrudes in the direction (to the left in FIG. 2). Reference numerals 15A and 15B denote stopper portions for locking the lever switch 15 to the main body of the nozzle hanger 1 when the lever switch 15 protrudes.
2 (and FIG. 6), when a fuel nozzle (not shown) is hooked to the nozzle hook 1, the lever guard 21 (not shown in FIG. 2) of the fuel nozzle presses the lever switch 15 in the direction of arrow A1, It rotates counterclockwise (in the direction of arrow A2) about 14, and stops at a position within the opening 1A of the nozzle hanger 1. As shown in FIG. FIG. 10 (and FIG. 9) shows a state in which the lever switch 15 is accommodated within the opening 1A of the nozzle hook 1. In FIG. , the lever guard 22 is shown.

In FIG. 2, lever switch 15 has a switch actuating piece 16 . Here, in FIG. 2 (and FIG. 6), the switch operating piece 16 is arranged so as to come into contact with the lever guard of the refueling nozzle (not shown). As also shown in FIG. 5, the switch operating piece 16 is constructed by combining approximately L-shaped members, and includes a first pressing piece 16A and a second pressing piece 16B. 2 (and FIGS. 6 and 10), the switch actuating piece 16 is shown blacked out.
The switch operating piece 16 is pressed by the lever switch 15 in conjunction with the opening and closing of the panel 18 on which the nozzle hook 1 is arranged and the disengagement of the fuel nozzle 20 from the nozzle hook 1 (locking: see FIG. 10). Activate part 4. When pressed by the lever switch 15, the first pressing piece 16A of the switch operating piece 16 presses the first pressure receiving piece 11C of the rotating member 11 of the switch section 4, and the second pressing piece of the switch operating piece 16 presses. 16B presses the second pressure receiving piece 11D of the rotating member 11;
FIG. 2 shows a state in which the panel 18 on which the nozzle hanger 1 is arranged is opened (a state in which the panel 18 is removed from the fueling device 100). Nevertheless, the switch portion 4 fixed to the immovable member (frame) is positioned apart from the switch operating piece 16 . In this case, the switch operating piece 16 (the first pressing piece 16A and the second pressing piece 16B) does not press the pressure receiving pieces 11C and 11D of the rotary member 11 of the switch section 4. As shown in FIG.
In FIG. 2 (and FIGS. 6 and 10), reference numeral 6A denotes a cable for transmitting the detection result of the detector 6 to a control device (not shown).

3 and 4 showing the details of the switch portion 4 with the panel 18 opened, the non-detecting portion 5 emitting magnetic lines of force M (FIG. 4) and the detecting portion 6 detecting the magnetic lines of force emitted from the non-detecting portion 5 are shown. , are arranged at opposite positions with a predetermined interval therebetween as shown in FIG. The non-detecting portion 5 and the detecting portion 6 are integrally formed.
The switch portion 4 is provided with a fixing member 12 (FIG. 4) made of a non-magnetic material and having an approximately U-shaped cross section. It is fixed to the housing of the oil supply device 100 via the member 12 by fastening means (not shown). A rotating member 11 is rotatably supported by a bolt 9 (see FIG. 3) on the fixed member 12. In the illustrated embodiment, the bolt 9 is included in the rotating shaft 11E.

In FIGS. 3 and 4, the rotating member 11 is arranged at an intermediate position between the non-detecting section 5 and the detecting section 6, and is provided rotatably (rotatably). The main body of the rotating member 11 is made of a non-magnetic material, but ferromagnetic materials (for example, permanent magnets) are arranged at two locations. The position where the ferromagnetic body is arranged is a position adjacent to the non-detecting portion 5 in the position where the panel 18 is open and/or the position where the fuel nozzle is locked by the nozzle hook 1. is. The two ferromagnetic bodies are composed of a first ferromagnetic body portion 11A and a second ferromagnetic body portion 11B. Here, the cross-sectional areas of the first and second ferromagnetic portions 11A and 11B are larger than the cross-sectional area of the ferromagnetic material in the prior art (Patent Document 1). is set to be 1.8 times or more the cross-sectional area of the ferromagnetic material in .
Further, the rotary member 11 has the first pressure-receiving piece 11C and the second pressure-receiving piece 11D as described above. In conjunction with the opening and closing of the panel 18 (attachment and detachment to the fuel supply device 100), or the attachment and detachment of the fuel nozzle 20 (see FIG. 10) to the nozzle hook 1 (locking and unlocking), the first pressure receiving The piece 11C is pressed by the first pressing piece 16A (FIG. 2) of the switch operating piece 16, and the second pressure receiving piece 11D is pressed by the second pressing piece 16B (FIG. 2) (see FIG. 5). As shown in FIGS. 3 to 5, the first pressure receiving piece 11C and the second pressure receiving piece 11D are composed of substantially L-shaped members.
The switch part 4 has a conducting member 7, which consists of a first bending member 8 (FIGS. 7 and 8), a bolt 9, and a second bending member 10 (FIGS. 7 and 8). Consists of The first folding member 8 is arranged on a rotating member 11 and the second folding member 10 is arranged on a stationary member 12 . The conductive member 7 will be described later with reference to FIGS. 7 and 8. FIG.

3 and 4 show the switch portion 4 in a state in which the panel 18 is opened (a state in which the panel 18 is removed from the fueling device 100), and in the state shown in FIG. 2), the pressure-receiving pieces (first pressure-receiving piece 11C, second pressure-receiving piece 11D) of the rotating member 11 of the switch section 4 are separated from the switch operating pieces 16 (first pressing piece 16A, second pressure-receiving piece 16A, second It is not pressed by the pressing piece 16B). The position of the rotating member 11 in this state is described as "first position".
The rotating member 11 rotatably supported by the rotating shaft 11E (in which the bolt 9 is contained) is in a state in which it is not pressed by the switch operating piece 16 due to the repulsive force of the biasing means (not shown) (see FIG. 2). ), the states shown in FIGS. 3 and 4 are maintained. That is, as shown in FIG. 2, the rotating member 11 does not contact the switch operating piece 16 and maintains a position where it is not pressed by the switch operating piece 16 .
When the rotating member 11 is not in contact with the switch operating piece 16 and is not pressed by the switch operating piece 16 and the rotating member 11 is positioned at the “first position”, the rotating member 11 is in the non-detecting portion 5 . and the detecting portion 6, and adjacent to the non-detecting portion 5, a first ferromagnetic portion 11A in which a ferromagnetic material is arranged is positioned.
Therefore, for example, even if the magnetic lines of force emitted from the permanent magnet become stronger at low temperatures such as in winter in cold regions, the magnetic lines of force emitted from the non-detecting portion 5 (arrow M, FIG. 4) are It is completely cut off and can be prevented from reaching the detection unit 6 . Therefore, it is possible to reliably detect that the nozzle switch 4 is in the "OFF" state, and to reliably prevent refueling from being started while the panel 18 is open.
3 and 4, since the conducting member 7 is separated from the non-detecting portion 5, the magnetic lines of force emitted from the non-detecting portion 5 do not reach the detecting portion 6 via the conducting member 7. .

Next, with reference to FIGS. 5 to 8, a state in which the panel 18 is attached to the fueling device 100 (the panel 18 is closed) and the fueling nozzle 20 is removed from the nozzle hook 1 will be described.
5 and 6, the nozzle hook 1 is the same as described above.
By closing the panel 18 (attaching the panel 18 to the lubricating device), the nozzle hook 1 rotates about a panel rotating shaft (not shown) positioned below the nozzle hook 1 (lower side in FIGS. 5 and 6), The nozzle hanger 1 is closer to the switch section 4 than in the state of FIG. 2 (the state in which the panel 18 is open). At that time, the first pressing piece 16A of the switch operating piece 16 connected to the lever switch 15 presses the first pressure receiving piece 11C of the rotating member 11 of the switch section 4. As shown in FIG.
When the first pressing piece 16A of the switch operating piece 16 presses the first pressure receiving piece 11C of the rotating member 11, the rotating member 11 rotates to the position shown in FIGS. is maintained. The position of the rotating member 11 in the state shown in FIGS. 5 and 6 (the state in which the panel 18 is attached to the fueling device 100 and the fueling nozzle 20 is detached from the nozzle hook 1) is referred to as the "second position".

7 and 8 show the details of the switch portion 4 when the rotating member 11 is at the second position in FIGS.
7 and 8, the switch portion 4 is in the second position, and the first ferromagnetic portion 11A and the second ferromagnetic portion 11B of the rotating member 11 are connected to the non-detecting portion 5 and the detecting portion 6. not located between In FIGS. 7 and 8, the main body (non-magnetic) of the rotating member 11, in which the intermediate portion 11F (FIG. 8) between the first ferromagnetic portion 11A and the second ferromagnetic portion 11B is non-magnetic. It is located between the detection section 5 and the detection section 6 .
In FIG. 8, a conducting member 7 (FIG. 8) is arranged adjacent to the non-detecting portion 5 and in the direction in which the magnetic line of force M is emitted from the non-detecting portion 5 (leftward in FIG. 8). The conductive member 7 includes a first bending member 8 made of a ferromagnetic material, a bolt 9 (see FIG. 7) made of a magnetic material attached to the first bending member 8, and made of a ferromagnetic material attached to the bolt 9. It is constituted by a second folding member 10 (FIG. 8) which is constructed. Here, although the bolt 9 is not shown in FIG. 8 and the rotating shaft 11E is shown, the bolt 9 extends through the hollow portion of the rotating shaft 11E, which is a sleeve-shaped hollow structure. there is

In FIG. 7, the first bending member 8 of the conducting member 7 is a substantially L-shaped plate material and is fixed to the rotating member 11 by a fixing bolt 13 (FIG. 7). The first bending member 8 includes an attached portion 8A extending parallel to the rotating member 11 and a rising portion 8B that rises (folds) near the non-detecting portion 5 .
7 and 8 (the panel 18 is closed and the fuel nozzle 20 is removed from the nozzle hook 1), the rising portion 8B of the first bending member 8 is adjacent to the non-detecting portion 5 (see FIG. 7). , the position on the left near the non-detection portion 5 in FIG.
The second bending member 10 of the conducting member 7 is also an approximately L-shaped plate member, and is connected to the first bending member 8 via the bolt 9 (and rotating member 11). The second bending member 10 includes an attachment portion 10A extending parallel to the rotating member 11 and a rising portion 10B rising (bending) near the detecting portion 6. As shown in FIG.
7 and 8 (with the panel 18 closed and the fuel nozzle 20 removed from the nozzle hook 1), the rising portion 10B (made of ferromagnetic material) of the second bending member 10 is adjacent to the detecting portion 6. 7 and 8 (the position on the left near the detector 6 in FIGS. 7 and 8).
As described above, the first bending member 8, the bolt 9, and the second bending member 10, which are constituent members of the conducting member 7, are magnetically connected.

Next, the flow of magnetic lines of force (arrows M, FIG. 8) in the switch section 4 in the states shown in FIGS. 7 and 8 will be described.
In the state shown in FIGS. 7 and 8, the intermediate portion 11F (FIG. 8) of the main body portion of the non-magnetic rotating member 11 is positioned between the non-detecting portion 5 and the detecting portion 6. The lines of magnetic force generated from the portion 5 are blocked by the intermediate portion 11F and do not reach the detecting portion 6 at the opposite position.
As indicated by a plurality of arrows M in FIG. 8, the magnetic lines of force emitted from the non-detecting portion 5 travel leftward and extend to the rising portion 8B of the first bending member 8, which is a member made of a magnetic material, and the attached portion. 8A, the bolt 9, the attached portion 10A of the second bending member 10, and the rising portion 10B, and reach the detecting portion 6. As shown in FIG.
Therefore, even if the temperature of the magnet increases and the lines of magnetic force emitted from the magnet decrease (weaken), or even if there is a member made of a magnetic material around the switch unit 4, the panel 18 is closed and the refueling nozzle 20 is removed from the nozzle hook 1, the magnetic lines of force M generated at the non-detecting portion 5 are directed to the conducting member 7 (first bending member 8, bolt 9, It is reliably transmitted to the detector 6 via the second bending member 10). Therefore, ON/OFF of the switch section 4 (nozzle switch) can be reliably detected.
In other words, even if the magnetic lines of force M emitted from the non-detecting portion 5 are unstable, the conducting member 7 is adjacent to the non-detecting portion 5, so that the magnetic force lines M reliably reach the detecting portion via the conducting member 7. 6. As a result, the fuel supply pump in the fuel supply device 100 can be driven and stopped accurately, and the work required for fuel supply can be performed.

Next, with reference to FIGS. 9 to 12, a state in which the panel 18 is attached to the fueling device 100 (the panel 18 is closed) and the fueling nozzle 20 is locked to the nozzle hook 1 will be described.
9 and 10, when the panel 18 is attached to the fueling device 100 and the fueling nozzle 20 is hooked to the nozzle hook 1, the lever guard 22 of the fueling nozzle 20 presses the lever switch 15 (arrow A1: FIG. 2), The lever switch 15 rotates counterclockwise about the shaft portion 14 (arrow A2 in FIG. 2), and stops at a position within the opening 1A of the nozzle hook 1. As shown in FIG. 9 and 10 , the discharge pipe 21 of the fuel nozzle 20 is inserted into the hood 2 and the lever guard 22 of the fuel nozzle 20 is held by the receiving portion 3 .
9 and 10, by locking the fuel nozzle 20 to the nozzle hook 1, compared to the state of FIGS. 5 and 6 (the state in which the panel 18 is closed and the fuel nozzle 20 is removed from the nozzle hook 1) , the lever switch 15 further rotates counterclockwise, and the second pressing piece 16B of the switch operating piece 16 connected to the lever switch 15 presses the second pressure receiving piece 11D of the rotating member 11 of the switch section 4. do. At this time, the first pressing piece 16A of the switch operating piece 16 does not press the first pressure receiving piece 11C of the rotating member 11, and the pressing of the first pressing piece 16A to the first pressure receiving piece 11C is released. ing.
When the fuel nozzle 20 is completely locked to the nozzle hook 1, the second pressing piece 16B of the switch operating piece 16 presses the second pressure receiving piece 11D of the rotating member 11, so that the rotating member 11 is held in position as shown in FIG. , to the position shown in FIG. The position of the rotary member 11 (the position of the rotary member 11 shown in FIGS. 11 and 12) when the panel 18 is closed and the fuel nozzle 20 is removed from the nozzle hook 1 (in the case shown in FIGS. 9 and 10) is referred to as "third position”.

9 and 10 (when the panel 18 is closed and the fuel nozzle 20 is removed from the nozzle hook 1), details of the switch section 4 are shown in FIGS. 11 and 12. FIG.
The rotating member 11 at the third position shown in FIGS. 11 and 12 is positioned between the non-detecting portion 5 and the detecting portion 6, and a second ferromagnetic material is placed adjacent to the non-detecting portion 5. Part 11B is located.
Therefore, for example, even if the magnetic lines of force emitted from the permanent magnet become strong in a cold region or in the coldest winter season, the magnetic lines of force emitted from the non-detecting portion 5 (arrow M: FIG. 12) are not detected by the second ferromagnetic portion 11B. , and does not reach the detector 6. Therefore, it can be reliably detected that the nozzle switch 4 is "off".
11 and 12, the conducting member 7 is separated from the non-detecting portion 5, so the magnetic lines of force emitted from the non-detecting portion 5 do not reach the detecting portion 6 via the conducting member 7. .
In order to prevent the rotating member 11 from rotating counterclockwise beyond the third position shown in FIGS. 11 and 12, the rotating member 11 is provided with a stopper 17 as shown in FIG. It is In FIG. 9, when the rotary member 11 attempts to rotate counterclockwise beyond the third position, the stopper 17 comes into contact with the component 23 (FIG. 9) fixed to the nozzle hook 1 side, Clockwise rotation is blocked.

As described above, in the switch section 4, the rotary member 11 rotatably supported by the rotary shaft 11E (in which the bolt 9 is contained) is rotatably supported as shown in FIGS. The state (first position) is maintained.
When the nozzle 20 is removed from the nozzle hook 1 (FIGS. 5 to 8) from the state in which the fuel nozzle 20 is locked by the nozzle hook 1 (FIGS. 9 to 12), the lever guard 22 of the fuel nozzle 20 lifts the nozzle hook 1. The lever switch 15 is not pressed, and from the state where the second pressing piece 16B of the switch operating piece 16 presses the second pressure receiving piece 11D of the rotary member 11 (FIGS. 9 to 12), the switch operating piece 16 is released. The first pressing piece 16A shifts to the state of pressing the first pressure receiving piece 11C of the rotating member 11 (FIGS. 5 to 8).
Therefore, the rotational position of the rotating member 11 in the switch section 4 moves from the third position shown in FIGS. 11 and 12 to the second position shown in FIGS.

Further, when the panel 18 is removed from the fueling device 100 (FIGS. 2 to 4) from the state in which the fueling nozzle 20 is removed from the nozzle hook 1 and the panel 18 is closed (FIGS. 5 to 8), the panel 18 5 and 6 (the state in which the panel 18 is closed), the nozzle hanger 1 is separated from the switch section 4 (the state in FIG. 2). At this time, the switch operating piece 16 moves from the state in which the first pressing piece 16A of the switch operating piece 16 presses the first pressure receiving piece 11C of the rotating member 11 (FIGS. 5 to 8). 2 to 4).
7 and 8 to the first position shown in FIGS.

As described above with reference to FIGS. 2 to 4, in the illustrated embodiment, when the panel 18 is removed from the fueling device 100 (the panel 18 is opened), the The lines of magnetic force are blocked by the ferromagnetic material portion 11A of the rotating member 11 and do not reach the detecting portion 6. FIG. Further, since the rising portion 8B of the conducting member 7 is not adjacent to the non-detecting portion 5 and is separated, the lines of magnetic force emitted from the non-detecting portion 5 do not pass through the conducting member 7 and do not reach the detecting portion 6. . Therefore, when the panel 18 is removed from the fueling device 100 (when the panel 18 is opened), malfunction of the nozzle switch 4 to start the fueling operation is reliably prevented.
5 to 8, when the fuel nozzle 20 is removed from the nozzle hook 1 with the panel 18 attached to the fueling device 100 (the panel 18 is closed), the non-detecting portion of the switch portion 4 The lines of magnetic force emitted from 5 surely reach the detecting portion 6 via the conducting member 7 . Therefore, when the panel 18 is attached to the refueling device 100 and the refueling nozzle 20 is removed from the nozzle hook 1, the nozzle switch 4 reliably detects this fact, so it is determined that refueling operation is possible. is surely done.
Further, as described with reference to FIGS. 9 to 12, when the panel 18 is attached to the fueling device 100 and the fueling nozzle 20 is engaged with the nozzle hook 1, the switch portion 4 is not detected. The lines of magnetic force emitted from the portion 5 are reliably blocked by the ferromagnetic portion 11B, which has a larger cross-sectional area than the existing technology, and do not reach the detection portion 6. FIG. Since the rising portion 8B of the conducting member 7 is not adjacent to the non-detecting portion 5, it does not reach the detecting portion 6 via the conducting member 7 either. Therefore, when the panel 18 is attached to the fueling device 100 (the panel 18 is closed) and the fueling nozzle 20 is locked to the nozzle hook 1, the malfunction of the nozzle switch 4 to start the fueling operation is reliably prevented. be done.

In the illustrated embodiment, as shown in FIGS. 11 and 12, the ferromagnetic portion 11B of the rotating member 11 is not detected when the panel 18 is attached and the fuel nozzle 20 is locked to the nozzle hook 1. It is a mechanical component for a switch that interrupts the transmission of magnetic lines of force from the portion 5 to the detection portion 6 . Then, as shown in FIGS. 3 and 4, when the panel 18 is removed from the fueling device 100 (when the panel 18 is open), the transmission of the magnetic lines of force from the non-detecting portion 5 to the detecting portion 6 is cut off. The ferromagnetic portion 11A of the rotating member 11 is a mechanical component for maintenance. The ferromagnetic portion 11B, which is the mechanical component for the switch, and the ferromagnetic portion 11A, which is the mechanical component for maintenance, are integrated as the rotary member 11 .
In this manner, by integrating the ferromagnetic body portion 11B, which is a switch mechanism component, and the ferromagnetic body portion 11A, which is a maintenance mechanism component, into the rotating member 11, a defect in the maintenance mechanism component can cause the nozzle to malfunction during maintenance. It is no longer possible to erroneously judge that it is out (refueling possible state). In addition, the integration reduces the number of parts and facilitates assembly.

As described above, the panel 18 can be removed from the fueling system 100, and FIG. 13 shows the panel 18 removed from the fueling system 100. FIG.
A nozzle hanger 1 is installed on the outer surface side of the panel 18 .
As shown in FIG. 13 with the panel 18 removed, a frame 19 is attached to the side of the housing body of the oil supply device 100, and a switch is provided on the rear side of the frame 19 (the side away from the panel 18 in FIG. 13). Part 4 is arranged.
The frame 19 has an opening at which the switch portion 4 is arranged (forming an opening portion 19A), and the switch portion 4 and the nozzle hanger 1 are provided at corresponding positions.

In FIG. 14, the switch unit 4 is provided on the opposite side of the frame 19 to the panel 18 (on the side of various machines) and is not arranged on the outer surface side of the panel 18 (on the arrow AP side). It does not protrude to the side. The only member of the frame 19 that protrudes toward the outer surface of the panel 18 (in the direction of the arrow AP) is a flange 19B formed in the opening 19A (in which the switch section 4 is arranged).
For example, when the panel 18 is removed for maintenance and work is performed, the discharge dimension of the flange 19B of the frame 19 protruding toward the panel 18 side (arrow AP side) is small, so the worker's head may not be in the discharge position. The risk of collision is extremely small.

According to the illustrated embodiment, the panel 18 is attached to the fueling device 100 (the panel 18 is closed) and the fueling nozzle 20 is removed from the nozzle hook 1 at a location different from the detection unit 6 . , the conducting member 7 is movable so as to be positioned at a position where the lines of magnetic force generated from the non-detecting portion 5 reach. The conductive member 7 includes a first bending member 8 made of a ferromagnetic material, a magnetic bolt 9 attached to the first bending member 8, and a ferromagnetic material attached to the bolt 9. It comprises a second folding member 10 which is folded.
When the panel 18 is attached to the fueling device 100 and the fueling nozzle 20 is disengaged from the nozzle hook 1, the magnetic lines of force emitted from the non-detecting portion 5 reach the first bending member 8, and then reach the first folding member 8. is transmitted to the detection unit 6 via the bending member 8 , the bolt 9 and the second bending member 10 . At that time, even if there is a member made of a magnetic material around the nozzle switch 4, not only the temperature change such as the temperature rise of the magnet, but also the non-detection The lines of magnetic force generated by the portion 5 are reliably transmitted to the detection portion 6, and the on/off state of the nozzle switch 4 can be reliably detected. As a result, it is possible to accurately drive and stop the oil supply pump and perform the work required for oil supply.

Further, according to the illustrated embodiment, the switch portion 4 has a rotating member 11 , and the rotating member 11 has a panel 18 attached to the fueling device 100 and a fueling nozzle 20 engaged with the nozzle hook 11 . In the state where it is (see FIGS. 9 and 10), it is positioned between the non-detecting portion 5 and the detecting portion 6 . The second ferromagnetic portion 11B of the rotating member 11 is arranged between the non-detecting portion 5 and the detecting portion 6. As shown in FIG. Therefore, for example, even if the magnetic lines of force emitted from the permanent magnet become stronger in a cold region, the magnetic lines of force emitted from the non-detecting portion 5 are blocked by the second ferromagnetic portion 11B and prevented from reaching the detecting portion 6. . As a result, it can be reliably detected that the nozzle switch 4 is "off".
Further, even when the panel 18 is removed from the fueling device 100 (when the panel 18 is open: see FIG. 2), the rotating member 11 of the switch portion 4 is positioned between the non-detecting portion 5 and the detecting portion 6. , and the first ferromagnetic portion 11A of the rotating member 11 is located between the non-detecting portion 5 and the detecting portion 6. As shown in FIG. Therefore, as in the case where the fuel nozzle 20 is locked by the nozzle hook 11, the magnetic lines of force emitted from the non-detecting portion 5 are blocked by the first ferromagnetic portion 11A and prevented from reaching the detecting portion 6. Thus, it is possible to reliably prevent refueling from being started while the panel 18 is open.
Here, in the illustrated embodiment, the cross-sectional area of the ferromagnetic material of the first ferromagnetic material portion 11A and the second ferromagnetic material portion 11B in the rotating member 11 is the ferromagnetic material in the prior art (Patent Document 1). , for example, 1.8 times or more, the effect of blocking the magnetic lines of force emitted from the non-detecting portion 5 by the first ferromagnetic portion 11A and the second ferromagnetic portion 11B is enhanced. can definitely perform.

In addition, according to the illustrated embodiment, the magnetic line of force from the non-detecting portion 5 to the detecting portion 6 is interrupted while the fuel nozzle 20 is engaged with the nozzle hook 1 (see FIGS. 11 and 12). A second ferromagnetic portion 11B of the rotary member 11 is provided as a mechanical component. In addition, when the panel 18 is removed from the fueling device 100 (the panel 18 is opened), the magnetic line of force from the non-detecting portion 5 to the detecting portion 6 is cut off (see FIGS. 3 and 4). As a first ferromagnetic portion 11A of the rotating member 11 is provided. The first ferromagnetic portion 11A and the second ferromagnetic portion 11B are integrated as a first rotary member 11. As shown in FIG. Since the first ferromagnetic portion 11A, which is a mechanical component for maintenance, and the second ferromagnetic portion 11B, which is a mechanical component for switches, are integrated, when the panel 18 is removed from the fuel supply device 100 (the panel is opened) This prevents an erroneous determination that the vehicle is ready for refueling. In addition, the integration reduces the number of parts and facilitates assembly.
Furthermore, since the nozzle switch 4 is arranged on the back side of the frame 19 attached to the side surface of the housing body of the oil supply device 100 (the side away from the removed panel 18 in FIG. 13), the panel 18 can be removed during maintenance, for example. When removed from the fueling device 100, the risk of the nozzle switch 4 arranged on the rear surface of the frame 19 coming into contact with the operator is reduced.

It should be noted that the illustrated embodiment is merely an example and is not intended to limit the technical scope of the present invention.

Reference Signs List 1 Nozzle hook 2 Hood 3 Receptacle 4 Switch (nozzle switch)
5 Non-detecting portion 6 Detecting portion 7 Conducting member 8 First bending member 9 Bolt 10 Second bending member 11 Rotating member 11A First ferromagnetic portion 11B Second ferromagnetic portion 11C First pressure receiving piece 11D Second pressure receiving piece 11E Rotary shaft 15 Lever switch 16 Switch operating piece 16A First pressing piece 16B Second pressing piece 17 Stopper 18 Panel 19 Frame 20 Refueling nozzle 21 Discharge pipe 22 Lever guard 100 Refueling device

Claims (4)

a hood portion for holding the discharge pipe of the fueling nozzle;
Having a receiving portion for holding a lever guard of the fuel nozzle,
The lever switch abutting against the lever guard has a switch operating piece, the switch operating piece is pressed by the lever switch in conjunction with the engagement/disengagement of the refueling nozzle, and the switch operates when the switch operating piece is pressed. has a part
The switch section has a non-detection section that emits magnetic lines of force and a detection section that detects the magnetic lines of force emitted from the non-detection section. In the nozzle hanging of the installed lubrication device,
When the refueling nozzle is removed from the nozzle hook, the switch section is actuated by a conductive member that conducts the magnetic line of force and is located separately from the detection section,
The conducting member includes a first bending member movable to a position adjacent to the non-detecting portion and made of a ferromagnetic material, a bolt attached to the first bending member, and a bolt attached to the bolt. a second folding member comprising a ferromagnetic material and movable to a position adjacent to the sensing portion;
When the fuel nozzle is disengaged from the nozzle hook, the magnetic lines of force emitted from the non-detection portion are transmitted to the detection portion via the first bending member, the bolt, and the second bending member. Nozzle hanging of the lubricating device characterized. A rotating member is provided, and the rotating member is positioned between the non-detecting portion and the detecting portion when the fuel nozzle is engaged with the nozzle hook and/or when the panel is removed from the fueling device. 2. A nozzle hanger for a lubricating device according to claim 1 , wherein the ferromagnetic material is arranged at a portion adjacent to the non-detecting portion of the rotary member. A member for blocking the magnetic lines of force from the non-detecting portion to the detecting portion when the fuel nozzle is engaged with the nozzle hook, and from the non-detecting portion to the detecting portion when the panel is removed from the fueling device. 3. A nozzle hanger for a lubricating device according to claim 1 , wherein the member for blocking the lines of magnetic force is integrated as a rotating member, and the nozzle switch is arranged on the rear surface of the frame of the housing body of the lubricating device. When the switch operating piece of the rotating member is pressed by the lever switch,
a first unpressed position when the panel is removed from the fueling device (the panel is open);
When the panel is attached to the fueling device and the fueling nozzle is removed from the nozzle hook from the first position, the first pressing piece at the tip of the switch operating piece presses the first pressure receiving piece of the rotating member. a second position to
From the state of the second position, the rotating member rotates to the third position where the second pressing piece of the switch operating piece presses the second pressure receiving piece of the rotating member when the fuel nozzle is engaged with the nozzle hook. move,
3. A nozzle hanger for a fuel supply device according to claim 2, further comprising a stopper for stopping the rotating member at said third position.

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