KR20190034573A - Nozzle hanger and lubrication device - Google Patents

Abstract

A nozzle hanger of a fuel supply device in which a nozzle switch always operates correctly is provided. The nozzle hanger of the lubrication apparatus of the present invention includes a nozzle hanger main body 2 for holding a discharge pipe of a lubrication nozzle, a receiving portion 3 for supporting a lever guard of the lubrication nozzle, a switch portion 4, 4-2, (4), wherein the switch unit comprises a detected portion (5) for emitting a magnetic line of force or light, a detecting portion (6) for detecting a magnetic line of force or light emitted from the portion to be detected, 7-2, and 7-3, and the actuating piece can move a magnetic force line or a light line emitted from the detected portion or a position that does not disturb the light from reaching the detection portion, as a solution do.

Description

Nozzle hanger and lubrication device

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a nozzle holder for a nozzle device for supplying fuel oil or the like to an automobile. In particular, the present invention relates to a nozzle hanger provided with a nozzle switch that is turned on and off in conjunction with the lubrication of a fuel supply nozzle, and is capable of always operating the nozzle switch accurately.

In the lubrication system provided at a gas station or the like, the lubrication nozzle provided at the end of the lubrication hose is pulled out of the nozzle hanger, and the lubrication nozzle is inserted into the fill port of the vehicle, and the lubrication is performed to the fuel tank of the vehicle.

A nozzle switch for detecting that the oil supply nozzle is missing is provided in the nozzle hanger of the oil supply device. The control section of the oil supply device performs control to start or stop the oil supply pump by turning on and off the nozzle switch.

The nozzle hanger of such a fuel supply device has been conventionally proposed (see, for example, Patent Document 1).

However, in such a conventional technique (Patent Document 1), it is necessary to remove the operating piece (to-be-detected piece) from the nozzle body during maintenance. When the operating piece is mounted on the nozzle body again, the position of the operating piece deviates , Defects such as malfunction may occur due to deviation of the position (positional difference).

In the related art, since the magnet is exposed at the portion facing the nozzle switch of the operating piece (to-be-detected piece), the temperature of the nozzle, the falling of the magnet due to the impact at the time of storing the nozzle, (Magnetic demagnetization occurs) due to the decrease of the magnetic force lines, which may cause deterioration of the detection performance by the nozzle switch.

For this reason, there has been a demand for a nozzle hanger of a lubricating device in which a nozzle switch always operates correctly.

However, at this time, there is not yet proposed a nozzle hanger for a fuel supply device that meets such a demand.

Japanese Patent Application Laid-Open No. 2014-65518

SUMMARY OF THE INVENTION The present invention has been made in view of the problems of the prior art described above, and it is an object of the present invention to provide a lubrication apparatus nozzle hanger in which a nozzle switch always operates accurately.

The nozzle holder 1 of the lubrication apparatus 100 of the present invention includes a nozzle hanger main body 2 on which a discharge pipe of a lubrication nozzle is supported, a receiving portion 3 for supporting a lever guard of the lubrication nozzle, 4-2 and 4-3, the switch unit 4, 4-2, 4-3 is provided with a to-be-detected portion 5 for emitting magnetic force lines or light, 7-2 and 7-3 for detecting the magnetic lines of force or light emitted from the detected part 5 and the operating pieces 7, 7-2, 7-7, 3 can be moved to a position which interferes with a magnetic force line or light emitted from the detected part 5 from reaching the detection part 6 and a position which does not disturb.

Here, it is preferable that the to-be-detected portion 5 emits magnetic lines of force, and that the operating members 7, 7-2, and 7-3 are made of a magnetic material.

Alternatively, the detected part 5 emits light, and the operating pieces 7, 7-2 and 7-3 are preferably made of a non-transmissive material.

In the present invention, it is preferable that the switch portion (4, 4-2, 4-3) is formed integrally with the to-be-detected portion (5) and the detection portion (6) with an interval therebetween.

In the present invention, it is preferable that the operating pieces 7, 7-2, and 7-3 block the area between the detected part 5 and the detecting part 6.

Here, the to-be-detected portion 5 emits a magnetic line of force, and the operating piece 7-2 is made of a magnetic material. The dimension of the operating piece 7-2 in the thickness direction is set to be large, 5 and the detecting section 6 is set to be small.

Alternatively, in the present invention, the detected part 5 emits a magnetic line of force, the operating piece 7-3 is made of a magnetic material, and the above-mentioned operating piece 7-3 is a detecting part of the detected part 5 6 which are not opposed to each other.

In the practice of the present invention, it is preferable that the detecting section 6 and / or the detected section 5 are covered with a resin.

Here, the resin is a material which does not interfere with magnetic force lines or transmission of light.

The fuel supply device 100 provided with the present invention (the nozzle holder according to any one of claims 1 to 6) has the second operating piece 8, and the panel 9 is opened, When the first operating piece 7, the second operating piece 7-2, and the third operating piece 7-3 are spaced apart from each other at a position disturbing the arrival of the magnetic line of force or light emitted from the detected portion 5 to the detecting portion 6, And moves to a position where it obstructs the magnetic force lines or light emitted from the detection unit (5) from reaching the detection unit (6).

According to the present invention having the above-described configuration, when the lubrication nozzle is hooked on and pulled out from the nozzle hanger 1, the operating piece 7, 7-2, (6), and a position where the magnetic force lines or light emitted from the detected part (5) do not obstruct the detection section (6) from reaching the detection section (6). Therefore, depending on whether or not the magnetic force line or light emitted from the detected portion 5 reaches the detecting portion 6, that is, depending on whether or not the detecting portion 6 detects the magnetic line of force or light in the detected portion 5, It is possible to accurately judge whether the nozzle hanger 1 is hooked or pulled out.

As a result, the reliability of the fuel supply device 100 (determination as to whether or not the fuel supply by the fuel supply nozzle is performed) is improved.

If the to-be-detected portion 5 and the detection portion 6 of the switch portions 4, 4-2 and 4-3 are integrally formed with a space therebetween in the present invention, The positional relationship can be accurately fixed. Therefore, it is possible to reliably prevent or prevent the magnetic flux lines or light from reaching the detecting section 6 by the operating members 7, 7-2, and 7-3. Therefore, it is possible to identify the storage state of the fuel supply nozzle with high accuracy by judging whether or not the magnetic line of force or light has reached the detection portion 6.

If the switch portions 4, 4-2 and 4-3 are formed integrally with the detected portion 5 and the detection portion 6 with the interval therebetween in the present invention, the detected portion 5 and the detected portion 6) is accurately fixed. Therefore, it is possible to identify with high accuracy whether the fuel supply nozzle is housed in the nozzle holder 1 or is out of the nozzle holder 1.

In the present invention, if the operating piece 7, 7-2, 7-3 is configured to block the area between the detected part 5 and the detecting part 6, the magnetic force line drawn from the detected part 5 The light is shielded by the operating pieces 7, 7-2 and 7-3 and does not reach the detecting portion 6. [ In other words, the magnetic force line or light emitted from the detected portion 5 is shielded by the operating pieces 7, 7-2, and 7-3, and therefore can not be detected by the detecting portion 6. [

The operation members 7, 7-2 and 7-3 described above are disposed at positions where the magnetic force lines or light emitted from the detected portions 5 are prevented from reaching the detection unit 6, 1 or stored in the nozzle hanger 1 can be identified with high accuracy.

Since the operating pieces 7, 7-2 and 7-3 are not in contact with the detected part 5 and the detecting part 6 but can identify the stored state of the fuel supply nozzle in a non-contact state, the durability is good.

When the operating piece 7-2 is configured to block the area between the detected part 5 and the detecting part 6, the detected part 5 emits a magnetic line of force, When the dimension in the thickness direction of the operating piece 7-2 is set to be large and the area for blocking the area between the detected part 5 and the detecting part 6 is set small, Since the magnetic body existing in the area between the detected part 5 and the detecting part 6 becomes large by increasing the thickness direction of the operating piece 7-2 having the property of being a large magnetic body They are all absorbed by the operating piece 7-2.

Therefore, even if the area for blocking the area between the detected part 5 and the detection part 6 is set small, the magnetic line of force generated by the detected part 5 is absorbed by the operating piece 7-2, It is possible to identify with high accuracy whether the lubrication nozzle is housed in the nozzle hanger 1 or housed in the nozzle hanger 1 because no mistake is made in identifying the housing state of the lubrication nozzle .

Since the length of the operating piece 7-2 which is the movable portion can be shortened by reducing the area of the operating piece 7-2 blocking the area between the detected portion 5 and the detecting portion 6, It can be concise itself.

Alternatively, in the present invention, the detected part 5 emits a magnetic line of force, the operating piece 7-3 is made of a magnetic material, and the operating piece 7-3 is placed on the detecting part 6 of the detected part 5 The magnetic line of force generated by the to-be-detected portion 5 is absorbed by the operating piece 7-3 because all the magnetic lines of force emitted from the to-be-detected portion 5 are absorbed by the operating piece 7-3 which is a magnetic body And does not reach the detection unit 6. Therefore, the housed state of the oil supply nozzle can be identified with high accuracy.

Further, since the position at which the operating piece 7-3 is located close to the side of the end surface that is not opposed to the detecting portion 6 of the detected portion 5, it is possible to freely attach the operating piece corresponding to the layout .

In the practice of the present invention, when the detecting section 6 and / or the detected section 5 are covered with a resin (resin that does not interfere with transmission of a magnetic line of force or light) 3), it is possible to reliably perform the operation of the switch portions 4, 4-2, 4-3 in preventing the reduction of the magnetic force line or the amount of light and discriminating the housed state of the fuel supply nozzle.

There is no fear of corrosion of the detecting section 6 and / or the detected section 5.

In the present invention, when the panel 9 of the fuel supply device 100 is opened in the state where the lubrication nozzle is built in the nozzle holder 1, the magnetic force lines or light emitted from the detected part 5 are prevented from reaching the detection part 6 7-2 and 7-3 are spaced apart from each other, the magnetic force line or light reaches the detecting portion 6, and thus the mistake is made in the state in which the lubrication nozzle is removed from the nozzle hanger 1 for lubrication There is a possibility.

The present invention has the second operating piece 8 and the panel 9 of the oil supply device 100 is opened so that the operating pieces 7, 7-2 and 7-3 of the nozzle holder 1: the above- Even when the second operating piece 8 is spaced apart from the position where it interferes with the detection of the magnetic force line or light emitted from the detected portion 5 from the detection portion 5, The magnetic force line or light emitted from the detected portion 5 by the second operating piece 8 does not reach the detecting portion 6 when the light is moved to a position where the light is prevented from reaching the detecting portion 6. [ Therefore, even when the panel 9 of the fuel supply device 100 is opened, the magnetic line of force or light emitted from the detected part 5 does not reach the detecting part 6, and the fuel supply nozzle is removed from the nozzle holder 1 for lubrication There is no mistake.

1 is a perspective view showing a fuel supply device to which the present invention is applied.
Fig. 2 is a cross-sectional view showing a nozzle hanger of a fuel supply device according to an embodiment of the present invention, in which a lubrication nozzle is missing. Fig.
Fig. 3 is a cross-sectional view showing a nozzle hanger of a lubricant supply apparatus according to an embodiment of the present invention, in which a lubrication nozzle is hooked. Fig.
Fig. 4 is an explanatory view showing a relative position between the nozzle switch and the operating piece in the state shown in Fig. 2. Fig.
5 is an exploded perspective view of the nozzle switch.
Fig. 6 is an explanatory view for explaining the main part of the first embodiment of the present invention. Fig.
Fig. 7 is an explanatory view for explaining the main part of the second embodiment of the present invention. Fig.
Fig. 8 is an explanatory view for explaining the main part of the third embodiment of the present invention. Fig.
Fig. 9 is an explanatory view for explaining the main part of the fourth embodiment of the present invention. Fig.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

First, a first embodiment of the present invention will be described with reference to Figs. 1 to 6. Fig.

1, the lubrication apparatus to which the nozzle hanger of the present invention is applied is generally indicated by reference numeral 100. The fuel supply device 100 is provided with a nozzle hanger 1, and a fuel supply nozzle (not shown) is attached to and detached from the nozzle hanger 1. Here, an oil supply nozzle (not shown) is provided at the tip of the oil supply hose. When the fuel is fed to a vehicle (not shown), an unillustrated lubrication nozzle is taken out of the nozzle hanger 1, and the lubrication nozzle is inserted into a fill port (not shown) of the vehicle to refuel the fuel tank of the vehicle.

2 and 3) are provided in the nozzle hanger 1 of the fuel supply device 100. The switch portion 4 is provided with a lubrication nozzle or the lubrication nozzle is connected to the nozzle And detects that it is missing from the hook (1). Based on the ON / OFF state of the switch unit 4, a control unit (not shown) controls start and stop of the fuel supply pump.

The fuel supply device 100 shown in Fig. 1 has three nozzle holders 1, and three kinds of oil supply nozzles (not shown) corresponding to three kinds of oil kind are attached.

2, the nozzle hanger 1 of the fuel supply device 100 is provided with a nozzle hanger main body 2 on which a discharge pipe (not shown) of a fuel supply nozzle is supported, and a lever guard And a switch unit (nozzle switch) indicated by reference numeral 4 as a whole.

A hood 12 is provided above the nozzle hanger main body 2 to support the discharge pipe of the lubricant nozzle and the surface of the nozzle hanger main body 2 is formed of a smooth curved surface extending downward from the hood 12 .

A mountain-shaped member 3A is provided on the receiving portion 3 and the mountain-shaped member 3A is subjected to a force as if it protrudes upward by an elastic means (energizing means) (FIGS. 2 and 3). When the lubrication nozzle is latched, the mountain-shaped member 3A is fitted to the engaging hole (not shown) on the lever guard side so that the lubrication nozzle is stably supported on the nozzle hanger 1 .

The nozzle hanger main body 2 and the receiving portion 3 are fixed to a housing (not shown) of the fuel supply device 100 by fastening means (not shown). A housing (not shown) is disposed on the right side of the nozzle holder 1 in Figs.

4, the switch portion 4 includes a detected portion 5 for emitting a magnetic line of force, a detecting portion 6 for detecting a line of magnetic force emitted from the detected portion 5, and an operating piece 7. [

The detected part 5 and the detecting part 6 are integrally formed with a gap therebetween. 2 and 3, only the detection unit 6 is shown. The detected unit 5 is not shown in Figs. 2 and 3, and is provided on the front side of the detection unit 6 Person Side. The to-be-detected portion 5 and the detection portion 6 are fixed to the housing of the fuel supply device 100 by fastening means (not shown). The detected part 5 and the detected part 6 will be described later with reference to Figs. 4 to 6. Fig.

2 to 5, reference numeral 6A denotes a cable for transmitting the detection result of the detection unit 6 to a control device (not shown).

2 and 3, the lever-shaped pressing portion 13, which is rotatably pivoted on the shaft portion 10, is moved from the opening 2A of the nozzle hanger body 2 by the reaction force of the not- And protrudes outside the hook body 2 (leftward in Fig. 1). Reference numerals 13A and 13B denote stopper portions for locking the nozzle hanger body 2 when the pressing portions 13 protrude.

When the lubrication nozzle (not shown in Fig. 2) is hooked on the nozzle hanger body 2, the lever portion (not shown) of the lubrication nozzle pushes the pressing portion 13 (arrow A1) 13) is rotated in the counterclockwise direction about the shaft portion 10 (arrow A2) and stopped at a position in the opening 2A of the nozzle hanger body 2 (state shown in Fig. 3).

A substantially L-shaped plate-like operating piece 7 is fixed to the pressing portion 13 and the operating piece 7 extends in the direction of a substantially intermediate position between the detected portion 5 and the detecting portion 6. In other words, the operating member 7 extends in the direction substantially in the middle of the detecting unit 5 and the detecting unit 6, which are disposed at intervals in the direction perpendicular to the paper in Figs. 2 and 3.

2, in which the oil supply nozzle is out of the nozzle holder 1, the lever-shaped pressing portion 13 is located outside the opening 2A (in the direction away from the nozzle hanger body 2: And the operating piece 7 fixed to the pressing portion 13 is prevented from reaching the detecting portion 6 by the line of magnetic force leaking from the detected portion 5 (not shown in Figs. 2 and 3) (It does not exist at a position where it interferes with the magnetic force line struck by the to-be-detected portion 5 from reaching the detection portion 6). Here, the direction of the magnetic force lines is a direction from the detected part 5 to the detection part 6, and is a direction perpendicular to the paper surface of Figs.

In the state shown in Fig. 3 in which the oil supply nozzle (not shown) is engaged with the nozzle holder 1, a discharge pipe (not shown) of the oil supply nozzle is inserted into the hood 12, and a lever guard Is supported by the receiving portion (3). At this time, the lever-shaped pressing portion 13 is pressed by a lever guard (not shown) (arrow A1 in Figs. 2 and 3). The lever-shaped pressing portion 13 pressed by the lever guard rotates in the counterclockwise direction with respect to the shaft portion 10 (arrow A2 in Figs. 2 and 3) and enters the opening 2A of the nozzle hanger body 2 Stop at position.

Then, the operating piece 7 fixed to the pressing portion 13 is moved to a position where it interferes with the magnetic force line struck by the detected portion 5 from reaching the detecting portion 6 (arrow A3, Figs. 2 and 3) .

4 showing the state in which the lubricant nozzle is missing from the nozzle holder 1, the switch unit 4 includes a detected unit 5, a detecting unit 6 and an operating member 7, And the magnetic force line (arrow M) that is emitted is detected by the detecting section 6. The detection result of the detection unit 6 (the detection result that the detection unit 6 detects the magnetic force line of the detected part 5) is transmitted to the control device not shown through the cable 6A.

Here, the to-be-detected portion 5 and the detection portion 6 are spaced apart from each other (space) S and can be integrally formed for manufacturing.

4, the operating piece 7 does not block the magnetic line of force M that is emitted from the detected portion 5 toward the detecting portion 6 (see FIG. 4) when the lubrication nozzle is missing from the nozzle holder 1 (I.e., the operating piece 7 does not exist in a position to block magnetic force lines M). 3), the operating piece 7 moves in the direction of the arrow A3 and the magnetic force line M (hereinafter, referred to as " M "), which is emitted from the detected portion 5 toward the detecting portion 6, As shown in Fig.

5, the to-be-detected portion 5 includes a permanent magnet 5A (an operating portion: a member that emits magnetic force lines) and a housing 5B that surrounds and protects the permanent magnet 5A and fixes the permanent magnet 5A at a predetermined position. Since the to-be-detected portion 5 needs to have an explosion-proof structure, it is safer to use permanent magnets as the magnets of the to-be-detected portion 5, which do not need current to flow more than magnets that require current to flow. However, the magnet of the detected part 5 may be an electromagnet.

The detection unit 6 includes a circuit board 6B and an iron plate (not specifically shown) is disposed on the reed switch 6C of the circuit board 6B. The iron plate as a magnetic body is sucked and closed by closing a detecting circuit (not shown).

When the magnetic force line from the detected part 5 is interrupted by the operating piece 7 and the magnetic force is erased, the unshown steel plate of the reed switch 6C returns to the state before being sucked by the elasticity, The circuit is opened and turned off.

The circuit board 6B is protected by being received and fixed in the housing 6D. Here, the side surface 6E of the housing 6D on the side of the portion to be detected 5 is made of a permeable material.

The detection result of the detection unit 6 (ON / OFF of the reed switch 6C) is transmitted to the control device not shown through the cable 6A, and the control device controls the reed switch 6C on / The control for starting or stopping the main pump is performed.

The detected part 5 and the detecting part 6 are connected by the connecting part 5C and the detected part 5 and the detecting part 6 are integrally formed with a space S (see FIG. 4) therebetween.

Although not clearly shown, the circuit board 6B of the detecting unit 6 is fixed by filling and solidifying the resin in the housing 6D, and the permanent magnet 5A of the detected part 5 (operating part: Member) is fixed by filling and solidifying the resin in the housing 5B. That is, the circuit board 6B and the permanent magnet 5A are covered with a resin, and the resin is a material that does not interfere with the transmission of magnetic lines of force.

As described above, in the prior art in which the permanent magnet is exposed, since the magnetic force increases or decreases when the temperature in the oil supply device changes, the design of the installation position of the proximity switch and the like must be changed. In the prior art in which the permanent magnet is fixed with a screw (piece) or the like, the screw is loosened due to vibration when the nozzle is hooked or pulled out, and the permanent magnet may fall.

On the other hand, in the illustrated embodiment, since the substrate 6B and the permanent magnet 5A are covered with the resin, adverse effects due to temperature change, corrosion, rust, moisture, dust, vibration and the like can be prevented or reduced.

As shown in Fig. 6, the operation piece 7 is inserted / withdrawn at the interval (the space S and the position where the magnetic force line M is blocked) between the detected part 5 (permanent magnet) and the detection part 6 The movable member 7 is made of a magnetic material such as iron and absorbs the magnetic force line M emitted from the detected portion 5. [

As described above, the operating piece 7 moves according to the stored state of the oil supply nozzle (whether the oil supply nozzle is engaged or disengaged with the nozzle holder 1). 6), when the lubricant line M emitted from the detected portion 5 reaches the detecting portion 6 (see Fig. 3), the operating piece 7 (The space between the detected part 5 and the detection part 6 is blocked), and the switch part 4 is turned off.

On the other hand, when the lubrication nozzle is out of the nozzle hanger 1 (see Fig. 2), the operating piece 7 is configured such that the magnetic force line M emitted from the detected portion 5 reaches the detecting portion 6 (Without blocking between the detected part 5 and the detection part 6) and the switch part 4 is turned on.

According to the first embodiment of Figs. 1 to 6, the operation member 7 blocks the area between the detected part 5 and the detection part 6 by hooking and pulling the lubrication nozzle to the nozzle holder 1, The position where the magnetic line of force emitted from the detected portion 5 is prevented from reaching the detection portion 6 and the position where the magnetic line of force emitted from the detected portion 5 does not interfere with the detection portion 6 are moved. Therefore, depending on whether or not the magnetic force line of the detected part 5 has been detected by the detection part 6 (that is, the switch part 4 is in contact with the detection part 6) Whether or not the oil supply nozzle is caught in the nozzle hanger 1 or exited from the nozzle hanger 1 can be accurately determined with high accuracy.

As a result, the reliability of the determination of whether or not the fuel supply by the fuel supply nozzle is in the fuel supply device 100 is improved.

The operating piece 7 is not in contact with the to-be-detected portion 5 and the detecting portion 6, and can identify the stored state of the fuel supply nozzle in a non-contact state, so that the durability is good.

According to the first embodiment, since the detected portion 5 and the detection portion 6 are formed integrally with each other with the space (space S) therebetween, Can be accurately fixed.

Therefore, it can be positively positioned by both of the state in which the magnetic line of force is prevented from reaching the detection section 6 by the operation member 7 and the state in which the magnetic line of force is not disturbed.

Thus, by judging whether the magnetic line of force has reached the detecting section 6 (depending on whether the switch section 4 is on or off), it is possible to identify with high accuracy whether or not the lubrication nozzle is housed in the nozzle hanger 1 have.

According to the first embodiment, since the detecting section 6 and the detected section 5 are covered with resin (resin that does not interfere with transmission of a magnetic line of force), the influence of the temperature change on the switch section 4 is reduced And it is possible to reliably identify whether or not the lubricant nozzle is housed in the nozzle holder 1 by preventing the magnetic force lines or the amount of light from being reduced.

It is also possible to prevent or reduce adverse influences of corrosion of the detecting unit 6 and / or the detected unit 5 due to rust, moisture, dust, vibration, and the like.

In the first embodiment of Figs. 1 to 6, the magnetic force line is emitted from the detected portion 5, the magnetic line of force is detected by the detecting portion 6, and the magnetic line of force of the operating piece 7 reaches the detecting portion 6 And the attachment / detachment (hooking / unplugging) of the oil supply nozzle to / from the nozzle holder 1 is accurately determined by determining whether the magnetic line of force has reached the detection portion 6 or not. Here, "light (light)" instead of "magnetic force line"

(For example, a well-known light emitting device) that emits "light", a detecting portion (for example, a known optical detector) for detecting light, a light detecting portion For example). In this case, the light operating element is made of a non-transparent material, and the to-be-detected portion and the detection portion are covered with a resin that does not interfere with the transmission of light.

In addition, since the substrate of the detection unit 6 tends to become large when the light is used, it is necessary to consider the arrangement of each member.

Next, a second embodiment of the present invention will be described with reference to Fig.

7, the detected part 5 (permanent magnet) and the detecting part 6 (reed switch) of the switch part 4-2 are similar to those of the first embodiment shown in Figs. 1 to 6, The operating piece 7-2 is set to be sufficiently large in size in comparison with the thickness direction dimension of the operating piece 7 used in the first embodiment. 3), the operating piece 7-2 does not completely block (block) the area between the detected part 5 and the detecting part 6, and when the lubrication nozzle is caught by the nozzle holder 1 Or the area between the detected portion 5 and the detecting portion 6 that is shielded by the operating member 7-2 is set to be small.

When the thickness T1 of the operating piece 7-2 made of a magnetic material is large (the operating piece 7-2 is thick), the magnetic line of force of the detected part 5 (permanent magnet) So that it does not reach the detecting portion 6. 7, even if the area of shielding the area between the detected part 5 and the detecting part 6 (reed switch) is small, the magnetic line of force does not reach the detecting part 6 Since the detecting section 6 does not detect the magnetic line of force, the switch section 4 is turned off.

7, since the dimension T1 in the thickness direction of the operating piece 7-2 is set to be large, the detected portion 5 (permanent magnet) and the detecting portion 6 (reed switch) It is possible to determine whether or not the lubricant supply nozzle is held in the nozzle holder 1 by the presence or absence of the magnetic line of force of the detected portion 5 reaching the detection portion 6, 1) is identified with high accuracy.

Further, since the area in which the operating piece 7-2 blocks the area between the detected part 5 and the detecting part 6 is made small when the fuel supply nozzle is caught by the nozzle holder 1 (see Fig. 3) The length of the operation member 7-2 as the movable member can be shortened, and thus the switch itself can be simplified.

Other configurations and operational effects of the second embodiment of Fig. 7 are the same as those of the first embodiment of Figs. 1 to 6.

Next, a third embodiment will be described with reference to Fig.

8, the detected part 5 (permanent magnet) and the detecting part 6 (reed switch) of the switch part 4-3 are the same as those of the first embodiment (the embodiment of the "magnetic force lines" The operating piece 7-3 made of a magnetic material such as iron is set to have a sufficiently large thickness T2 in the thickness direction of the first embodiment as in the second embodiment . The operation piece 7-3 is not provided in the area between the detected part 5 and the detection part 6 but in the vicinity of the detected part 5 (permanent magnet), and in the vicinity of the detected part 5, And is located in the opposite side region.

7, when the dimension of the operating piece 7-3 in the thickness direction is large (thick), the operating piece 7-3 is in contact with the detected portion 5 (permanent magnet) and the detecting portion 6, It is possible to detect the position of the to-be-detected portion 5 in the region opposite to the detecting portion 6, even if the region between the to-be-detected portion 5 and the to-be-detected portion 5 (permanent magnet) All the magnetic lines of force emitted from the detected part 5 are absorbed by the operating piece 7-3 and do not reach the detecting part 6. [ Therefore, the detection unit 6 outputs a detection result indicating that the magnetic force line is not detected, and the switch unit 4 is turned off.

According to the third embodiment of Fig. 8, when the lubrication nozzle is held on the nozzle holder 1, the operating piece 7-3 is moved in the vicinity of the detected part 5 (permanent magnet) All of the magnetic lines of force emitted from the detected portion 5 are absorbed by the operating piece 7-3 even when the detecting portion 6 is located on the opposite side to the detecting portion 6. [ Whether or not the lubricating oil nozzle is engaged with the nozzle hanger 1 or exited from the nozzle hanger 1 is identified with high accuracy by whether or not the magnetic force line of the detected part 5 has reached the detection part 6 .

Since the position of the operating piece 7-3 at the time of hooking the fuel supply nozzle to the nozzle holder 1 can be set as the area opposite to the detecting part 6 with respect to the detected part 5, It is possible to identify whether the lubrication nozzle is held in the nozzle hanger 1 or is out of the nozzle hanger 1 even when the interval between the detected part 5 and the detection part 6 can not be sufficiently secured . Thus, the degree of freedom in attaching the operating member 7-3 is improved.

Other configurations and operational effects of the third embodiment of Fig. 8 are the same as those of the first and second embodiments of Figs.

A fourth embodiment of the present invention will be described with reference to Fig.

9, in a state where the oil supply nozzle is locked in the nozzle hanger, the operating piece 7 is located on a side away from a person who looks perpendicular to the drawing of the to-be-detected portion 5. In Fig. 9, the panel 9 and the operating piece 7 in a state in which the panel 9 is closed are indicated by dotted lines.

When the panel 9 is opened (rotated in the direction of the arrow A4) in this state (the state where the oil supply nozzle is kept in the nozzle hanger), the operation member 7 is moved to the position indicated by the dotted line (the detected portion 5, (The position between the first and second guide grooves 6). In Fig. 9, the panel 9 and the operating piece 7 in the state of opening the panel 9 are indicated by solid lines.

When the operating member 7 is moved to the position indicated by the solid line, the magnetic line of force of the detected member 5 is not blocked by the operating member 7 but reaches the detecting unit 6 and the switch unit 4 is turned on. In other words, there is a possibility that the nozzle switch 4 is turned on and erroneously determined that the fuel supply nozzle is removed from the nozzle hanger (lubrication possible state).

9, the fuel supply device 100 is provided with a plate-shaped second operating piece 8, and the second operating piece 8 is fixed to a housing (not shown) And is rotatably and axially rotatably supported by the shaft portion 11.

The second operation member 8 is configured such that the contact portion 8A at one end of the panel 9 is in contact with a portion 9A of the inner surface of the panel 9 when the panel 9 is closed and the switch portion 4 5). In Fig. 9, the position of the second operating piece 8 when the panel is closed is indicated by a broken line.

The second operating piece 8 does not come into contact with the portion 9A of the inner side surface of the panel 9 when the panel 9 is opened so that the second operating piece 8 is moved in the direction of the arrow A5 And moves to the viewer side in the vertical direction with respect to the to-be-detected portion 5 in the drawing. As a result, the second operating piece 8 is located in the vicinity of the detected portion 5 as indicated by the solid line in Fig.

Therefore, when the panel 9 of the fuel supply device 100 is opened, the operating piece 7 (first operating piece) of the nozzle hanger 1 fixed to the panel 9 is pressed against the magnetic force line (The position indicated by the solid line in Fig. 9) at which the magnetic line of force is prevented from reaching the detection section 6 at the position where the magnetic line of force is prevented from reaching the detection section 6 2 operating piece 8 moves to the area near the detected part 5 (the position indicated by the solid line in FIG. 9), and absorbs all of the magnetic force lines emitted from the detected part 5. Therefore, the line of magnetic force emitted from the to-be-detected portion by the second operating piece 8 does not reach the detecting portion 6. [

Therefore, even when the panel 9 of the fuel supply device 100 is opened, the magnetic force line emitted from the detected part 5 is maintained in a state where it does not reach the detection part 6, so that the switch part 4 is turned off , The control device (not shown) does not mistakenly assume that the lubrication nozzle is removed from the nozzle hanger 1 for lubrication.

9, the case where the detected part 5 emits a magnetic line of force and the detecting part 6 detects the magnetic line of force has been described. However, similarly to the first embodiment, And the detection unit 6 may be configured to detect the light.

In this case, the position at which the second operating piece 8 moves when the panel 9 is opened is the position between the detected portion 5 and the detecting portion 6.

Other configurations and operational effects of the fourth embodiment of Fig. 9 are similar to those of the embodiments of Figs.

It should be noted that the embodiments of the present invention are illustrative only and are not intended to limit the technical scope of the present invention.

For example, in the illustrated embodiment, the detected portion is a magnet that emits a magnetic line of force, and the detection portion has a function of detecting a magnetic line of force. However, the detection portion may include various light- .

1 ... Nozzle hook
2 ... nozzle hanger body
3 ... receiver
4, 4-2, 4-3 ... switch parts
5 ... Detected part
5A ... permanent magnet
5B ... housing
5C ... connection
6 ... Detector
6A ... cable
6B ... circuit board
6C ... Reed switch
6D ... housing
6E ... side
7, 7-2, 7-3 ... Operation part (first operation part)
8 ... second operating piece
9 ... panel
10, 11.
12 ... hood
13 ... pressing portion
100 ... Lubricator

Claims (7)

A nozzle holder for a lubrication apparatus comprising a nozzle hanger body for holding a discharge pipe of a lubrication nozzle, a receiving portion for supporting a lever guard of the lubrication nozzle, and a switch portion,
The switch unit is provided with a to-be-detected portion for emitting magnetic force lines or light, a detecting portion for detecting a magnetic force line or light emitted from the to-be-detected portion,
Wherein the operating piece is movable to a position where it does not interfere with a magnetic line of force or light that is emitted from the to-be-detected portion and that prevents the light from reaching the detecting portion. The method according to claim 1,
And the to-be-detected portion and the detection portion of the switch portion are integrally formed with an interval therebetween. 3. The method according to claim 1 or 2,
And the operating piece blocks an area between the detected part and the detecting part. The method of claim 3,
Wherein the to-be-detected portion is a magnetic force line, the operating piece is made of a magnetic material, the dimensions of the operating piece in the thickness direction are set large, and the area for blocking the area between the detected portion and the detecting portion is set small Nozzle hanger. 3. The method according to claim 1 or 2,
Wherein the to-be-detected portion is a magnetic force line, the operating piece is made of a magnetic material, and the operating piece is close to a cross section not facing the detecting portion of the to-be-detected portion. 6. The method according to any one of claims 1 to 5,
Wherein the detection part and / or the detected part are covered with a resin. The lubrication apparatus provided with the nozzle hanger according to any one of claims 1 to 6,
When the panel is opened and the operating piece of the nozzle hanger is isolated from a magnetic force line emitted from the to-be-detected portion or from a position obstructing the light from reaching the detection portion, the magnetic flux line or light emitted from the to- And moves to a position where it is prevented from reaching the detection section.

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