JPH0643039Y2 - Liquid injection gun - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial application] The present invention relates to a liquid injection gun used for injecting hydraulic fluid into a reserve tank of a power steering system for an automobile, for example.

[Prior Art] As prior arts related to the present invention, Japanese Utility Model Publication No. 59-14759 and Japanese Patent Publication No. 62-54719 are known. The former discloses a device that can easily and reliably fix the liquid tank such as a reserve tank in close contact with the liquid tank even if the liquid tank is inclined. Can be released,
Further, a liquid press-fitting device that can prevent the dripping of the residual liquid in the device with a simple sealing mechanism that does not require processing accuracy is disclosed.

In the reserve tank of the power steering system of the car,
Some are made of metal and some are made of resin, and the injection level of the hydraulic fluid is different. The liquid is injected into the reserve tank by a liquid injection gun, and the position of the nozzle is changed depending on the type of the reserve tank to ensure a desired injection level.

3 and 4 show a metal reserve tank. In the figure, 1 indicates a reserve tank, and the reserve tank 1 is composed of a tank main body 2, a lid 3, claws 4, and a spring 5. The upper end of the tank body 2 is an opening, and the opening is covered with a lid 3. A columnar portion 3a extending toward the bottom surface of the tank body 2 is provided in the central portion of the lid 3.
Are formed. The claw 4 is movably held by the columnar portion 3a of the lid 3. The claw 4 is biased against the inner wall of the opening of the tank body 2 by a spring 5 arranged on the outer periphery of the columnar portion 3a.

A notch 2a for inserting the claw 4 is formed in the opening of the tank body 2, and the outermost peripheral portion of the tank body 2 is
A flange portion 2b is formed which bulges outward in the radial direction. Lid 3
A seal member 6 is attached to a portion of the tank body 2 that contacts the open end of the tank body 2.

In this reserve tank 1, after injecting the fluid,
By rotating the lid 3 about half a turn with the claw 4 inserted in the notch 2a of the tank body 2, the claw 4 and the tank body 2 are rotated.
Are reliably engaged with each other, and liquid leakage from the tank body 2 is prevented.

5 and 6 show a resin reserve tank. In the figure, 11 indicates a reserve tank, and the reserve tank 11 is composed of a tank body 12 and a lid 13. A flange portion 12a is provided on the outer peripheral surface of the tank body 12 in the vicinity of the opening, and the collar portion 12a bulges in the radial direction. A plurality of notches 12b are formed in the collar portion 12a. The lid 13 is provided at its lower end with a claw 13a protruding inward in the radial direction, and the claw 13a is notched.
It is formed in a size that can be inserted into 12b. A seal member 14 is attached to a portion of the lid 13 that comes into contact with the open end of the tank body 12.

In this reserve tank 11, after injecting the fluid,
With the claw 13a inserted into the notch 12b of the tank body 12, the lid 13
By rotating the tank about half a turn, the claw 13a and the tank body 12 are securely engaged with each other, and liquid leakage from the tank body 12 is prevented.

FIG. 7 shows the structure of a conventional liquid injection gun. In the figure, 21 indicates a liquid injection gun, and 22 indicates a gun body. Two fluid passages 23, 24 are formed in the gun body 22, one of which is open to one end surface of the gun body 22. The other one of the flow passages 23 extends toward the center of the gun body 22 and is located on the outer periphery of a nozzle 25 described later.
The other fluid passage 24 opens at the other end surface of the gun body 22. A nozzle 25 that can move axially in the gun body 22
Is provided. One of the nozzles 25 is formed in the piston 25a, and the other is formed in the pipe portion 25b through which the fluid can pass. The passage 25c in the pipe portion 25b is the distribution passages 23, 24.
It is possible to communicate with. The nozzle 25 is biased upward by a spring 28 located on the outer circumference.

A twist claw 26 is provided on the outer peripheral portion of the other end surface of the gun body 22. The twist claw 26 can be engaged with the collar portion 12a of the resin reserve tank 11 described above. Twist claw 2
Inside the 6, another twist claw 27 is provided. The twist claw 27 is engageable with the collar portion 2c of the inner wall of the open end of the reserve tank 1 made of metal. When the twist claws 26, 27 are engaged with the collar portions 2c, 12a, the other end surface of the gun body 22 is in close contact with the open end of each reserve tank.

The nozzle 25 provided in the gun body 22 is moved in the axial direction by the compressed air supplied to the pressure chamber 29 located above the piston 25a, and is positioned at a predetermined position. A metal detector 30 is attached to the gun body 22 so that it is possible to determine whether or not the tank for injecting the fluid is a metal reserve tank.

In the liquid injection gun configured as described above, for example, after one twist claw 26 is engaged with the reserve tank 11, the height of the nozzle 25 is changed based on the type of the tank. As a result, the distance from the tip of the nozzle 25 to the opening end of the tank becomes a desired value, and the fluid F is injected in this state. When the fluid F reaches a certain level, the supply of the fluid is stopped, and conversely, the fluid is sucked from the nozzle and the fluid reaches a predetermined level. That is, the level adjustment during the injection of the fluid F is determined by the insertion height L ₃ of the nozzle of the injection gun, and the injection level of the fluid is secured at a predetermined value.

FIG. 8 shows another example of a conventional liquid injection gun.
In the figure, 41 indicates a liquid injection gun, and 42 indicates a gun body. In the pressure chamber 43 inside the gun body 42, the piston 43
Is slidably inserted, and the piston 43 is urged downward by a spring 57 provided on the outer circumference. The upper end of the piston 43 is formed on the male screw portion 43a, and the bracket 50 is screwed onto the male screw portion 43a. A plurality of arms 44 extending downward along the gun body 42 are attached to the bracket 50.

At the lower end of the arm 44, claws 45 and 46 capable of engaging with various reserve tanks are formed. Claw 45 located at the bottom end
Is engageable with the collar portion 2b of the metal reserve tank 1, for example, and the pawl 46 located above the pawl 45 is engageable with the collar portion 12a of the resin reserve tank 11. There is. A guide 47 is provided on the outer circumference of the gun body 42, and a pin 49 attached to the arm 44 is inserted into a guide hole 48 of the guide 47. The arm 44 moves inward in the radial direction as the piston 43 driven by the compressed air supplied from the air supply hole 50 to the pressure chamber rises.

A nozzle 52, which is biased upward by a spring 51, is movably provided in the gun body 42. One of the nozzles 52 is formed in the piston 52a, and the other is formed in the pipe portion 52b through which the fluid can pass. Flow path 52 in pipe section 52b
The c communicates with a liquid supply port 53 opening on the outer peripheral surface of the gun body 42. The nozzle 52 is movable in the axial direction by the compressed air supplied to the pressure chamber 54. The gun body
A metal detector 55 is attached to 42, and it is possible to determine whether or not the tank for injecting the fluid is a metal reserve tank. On the lower end surface of the gun body 42, a seal member 56 capable of contacting the open end of each tank is attached.

In the liquid injection gun configured as described above, the height of the nozzle is changed based on the tank type (signal from the metal detector 55) after the claw of the arm 44 is engaged with the reserve tank. It is variable. As a result, the distance L ₄ from the tip of the nozzle to the opening end of the tank becomes a desired value, and the fluid is injected in this state. When the fluid reaches a certain level, the supply of the fluid is stopped, and conversely, the fluid is sucked from the nozzle and the fluid is adjusted to a predetermined level.

[Problems to be Solved by the Invention] However, the liquid injection guns shown in FIGS. 7 and 8 also have the following problems.

First, in the case of the liquid injection gun shown in FIG. 7, the work efficiency is deteriorated because the injection gun and the collar portion of the tank must be engaged by inputting. Further, in the case of the liquid injection gun of FIG. 8, a piston mechanism for engaging the gun body and the tank and a piston mechanism for changing the position of the nozzle must be provided, and the structure is complicated. However, the weight increases as it becomes difficult to handle.

Furthermore, it is common to both, but in the configuration in which the type of tank is determined by the metal detector and the nozzle is activated based on this signal, if the metal detector fails, the nozzle will not operate as desired. , The injection level of the fluid is not reliably managed, and the power steering function cannot be fully exerted.

An object of the present invention is to provide a liquid injection gun that can be easily mounted on a container, can have a simplified mechanism, and can reliably control the liquid injection level.

[Means for Solving the Problems] A liquid injection gun according to the present invention which meets the above object is provided with a plurality of arms, one of which is swingably supported by a support portion, and various containers provided on the arms and having different shapes. A plurality of types of claws that can be engaged with the collar portion formed in the vicinity of the liquid injection port, one fixed to the support portion, and the other has an injection portion that can enter the liquid injection port of the container, A nozzle having a fixed piston that bulges outward in the radial direction between the fixed portion and the injection portion, and the pressure of the fluid supplied to the pressure chamber that is provided on the outer circumference of the nozzle and in which the fixed piston is fitted. A cylinder part that moves axially with respect to the nozzle, and a seal that is provided on the cylinder part and that is pressed against the liquid injection port of the container by the axial movement of the cylinder part when the claw and the flange part are engaged. Member and the cylinder In the state where the liquid injection port of the container is pressed by the seal member, an air vent passage communicating between the inside of the container and the outside of the container, a plurality of guide pins fixed to the cylinder portion, and each arm. A guide elongated hole into which the guide pin is inserted, and arm swinging means for swinging each arm in the radial direction around the nozzle by axial movement of the cylinder portion. .

[Operation] In the liquid injection gun configured as described above, when the cylinder section moves in the axial direction by the pressure of the fluid, the plurality of arms swingably supported by the support section center the nozzle by the arm swinging means. As a result, the arm claws engage with the flange of the container.

In this state, the seal member provided in the cylinder portion is pressed against the liquid injection port of the container, and the injection portion of the nozzle enters the container for a certain length. That is, since the nozzle is connected to the arm via the support part, the arm's claw can be set by setting the position of the arm's claw so that the tip of the injection part of the nozzle is located at the reference liquid surface of the liquid. When engaged with the collar of the container, the injection part of the nozzle will reliably project into the container by the desired length.

Also, when the container is different, another claw corresponding to this container will be engaged with the flange, so that the injection part of the nozzle can be positioned according to this container, and the injection part of the nozzle can be placed inside the container. Can be entered for a predetermined length.

When the positioning of the nozzle is completed, the liquid is injected from the injection part of the nozzle into the container, and the injection of the liquid is completed when the liquid exceeds the tip of the injection part of the nozzle. Next, a part of the liquid injected into the container is sucked up by the nozzle. As a result, the liquid level of the liquid coincides with the tip surface of the injection portion of the nozzle, and the liquid level management of the liquid in the container is reliably performed.

At the time of injecting the liquid into the container, the liquid injection port of the container is pressed by the seal member provided in the cylinder part,
In this state, the inside of the container and the outside of the container are communicated with each other by an air vent passage provided in the cylinder portion. Therefore, at the time of injecting the liquid, the residual air in the container can be easily pushed out of the container through the air vent passage.

As described above, according to the present invention, since the pressing operation of the seal member against the liquid injection port can be performed at the same time as the engaging operation with the collar section of the arm, only one cylinder section is required as the driving means, and the mechanism is It is much simpler than before.

[Embodiment] Hereinafter, a preferred embodiment of the liquid injection gun according to the present invention will be described with reference to the drawings.

FIG. 1 shows an embodiment of the present invention, and particularly shows an example of injecting liquid into a reserve tank shown in the prior art. In the figure, reference numeral 61 denotes a nozzle that is inserted into the liquid injection port of each container (reserve tank) having a different shape. The nozzle 61 has a small-diameter injection portion 61b formed at a portion to be inserted toward the reserve tanks 1 and 11, and a large-diameter fixed portion 61a formed at the other portion. A male screw 62 is formed at the tip of the fixed portion 61a, and the male screw 62 is a support portion made of a flat plate member.
It is inserted through 63. A passage 65 penetrating both ends of the nozzle 61 is formed at the center of the nozzle 61. Support part 63
A nut 72 is screwed into the male screw 62 inserted in
The nozzle 61 is fixed to the support portion 63 by tightening the nut 72.

The end portion of the fixed portion 61a of the nozzle 61 is fixed to the center of the support portion 63, and the screw hole 65a of the passage 65 opened in the end surface of the fixed portion 61a.
The liquid (fluid) F is supplied from the side toward the reserve tank. The fixed portion 61 of the nozzle 61
A fixed piston 61c that bulges outward in the radial direction is formed between a and the injection portion 61b.

On the outer peripheral portion of the support portion 63, a plurality of arms 64 engageable with the collar portions 2b and 12a provided near the liquid injection ports of the reserve tanks 1 and 11 are provided. Pins on top of arm 64
It is connected to the support 63 via 70, and the arm 64 is a pin.
With 70 as a fulcrum, it can swing in the radial direction with respect to the nozzle 61. Each arm 64 has a first claw 64a engageable with the collar 2b of the metal reserve tank 1 and a second claw 64b engageable with the collar 12a of the resin reserve tank 11. Has been formed. The first claw 64a is located at the lowermost end of the arm 64 and projects inward in the radial direction. The second engaging portion 64b is located above the first claw 64a, and
It projects further inward in the radial direction than 64a.

An arm swinging means 66 for swinging the arm 64 in the radial direction around the nozzle 61 is provided between the second claw 64b of the arm 64 and the fulcrum through which the pin 70 is inserted. The arm swinging means 66 is composed of a guide pin 66a and a guide elongated hole 66b. The guide elongated hole 66b is provided in the arm 64, and has an upper portion bent to the nozzle 61 side and has a V shape. A guide pin 66a fixed to the outer peripheral surface side of a cylinder portion 71 described later is inserted into the elongated guide hole 66b via a bracket 90.

A cylinder portion 71 that is movable in the axial direction of the nozzle 61 is arranged on the outer periphery of the nozzle 61. The cylinder portion 71 has a side wall 71.
a and end walls 71b and 71c. The inner peripheral surface of the pressure chamber 85 located inside the side wall 71a is capable of sliding contact with the fixed piston 61c located substantially at the center of the nozzle 61 in the axial direction. That is, the fixed piston 61c is fitted in the pressure chamber 85 of the cylinder portion 71. The inner peripheral surface of the end wall 71b can be slidably contacted with the fixed portion 61a of the nozzle 61, and the inner peripheral surface of the end wall 71c can be slidably contacted with the injection portion 61b of the nozzle 61. Injection part 61b
Project outward from the end wall 71b. Sealing members 81 and 82 that seal the gap between the nozzle 61 and the end wall 71b and the end wall 71c of the cylinder 71 are mounted. Also, the end wall 71c is formed integrally with the side wall 71a, and the end wall 71b is removable from the side wall 71a. Therefore, a seal member 83 that seals a gap between the end wall 71b and the side wall 71a is attached to the outer peripheral surface of the end wall 71b. A seal member 84 that seals a gap between the fixed piston 61c of the nozzle 61 and the side wall 71a of the cylinder portion 71 is also mounted on the outer peripheral surface of the fixed piston 61c.

The pressure chamber 85 of the cylinder portion 71 is moved to the first by the piston 61c.
Is divided into a pressure chamber 85a and a second pressure chamber 85b. First
Of the pressure chamber 85a communicates with a screw hole 71d opened in the end wall 71b, and the second pressure chamber 85b has a screw hole opened in the end wall 71c.
It communicates with 71e. The screw holes 71d and 71e are connected to a compressed air supply source (not shown) via a direction switching valve (not shown).

An air vent passage 87 that opens into the reserve tanks 1 and 11 is formed in the end wall 71c of the cylinder portion 71, and the air vent passage 87 communicates with a screw hole 71f that opens in the side wall 71a. The end portion of the end wall 71c is adapted to be inserted into the liquid injection ports 8 and 18 of the reserve tanks 1 and 11.
A seal member 89 capable of contacting the end faces of the liquid injection ports 8 and 18 of the reserve tanks 1 and 11 is attached to the outer peripheral end face of the tip end of the.

By the arm swinging means 66 described above, each arm 64 swings in the radial direction according to the axial movement of the cylinder portion 71.

Next, the operation of the above liquid injection gun will be described.

FIG. 2 shows a state in which the liquid (fluid) F is injected into the metal reserve tank 1 and the resin reserve tank 11, respectively. In the figure, the left side shows the case of a metal reserve tank, and the right side shows the case of a resin reserve tank. Since the injection procedures for both are almost the same, the explanation will focus on the case of a metal reserve tank.

When the reserve tank 1 is positioned at a predetermined position, the operator moves the liquid injection gun directly above the reserve tank 1, and the liquid transfer nozzle 61 is inserted into the liquid injection port 8 of the reserve tank 1. In this state, each arm 64
Is open outward in the radial direction. in this case,
Since the end wall 71c of the cylinder part 71 is also inserted into the liquid injection port 8 at the same time, the injection part 61b of the nozzle 61 is positioned substantially at the center of the liquid injection port 8. In this state, the compressed air is sent under pressure to the first pressure chamber 85a, so the arm 64 is pushed outward in the radial direction by the urging force of the guide pin 66a.

When the nozzle 61 is inserted into the liquid inlet 8, the cylinder portion 71
The compressed air is sent under pressure to the second pressure chamber 85b of the cylinder section 7b.
The guide pin 66a fixed to the bracket 90 of 1
It moves downward along the guide elongated hole 66b. As a result, each arm 64 moves radially inward about the nozzle 61, and the first claw 64a of the arm 64 engages with the collar portion 2b of the reserve tank 1. In addition, the arm 64 has a support portion 63.
Since the cylinder portion 71 is urged in the direction away from the support portion 63 in the state where the compressed air is sent to the second pressure chamber 85b, the cylinder portion 71 is mounted on the end wall 71c side. The sealed sealing member 89 is pressed against the end surface of the liquid injection port 8 of the reserve tank 1.

In this state, the injection part 61b of the nozzle 61 is connected to the liquid injection port 8
Enter the reserve tank 1 by the length L ₁ from the end face of.
In the present embodiment, the position of the first claw 64a of the arm 64 is set so that the tip of the injection portion 61b of the nozzle 61 serves as a fluid reference F ₁
Since it is set to be located at, the claw 64a of the arm 64
In the state in which is engaged with the collar portion 2b of the reserve tank 1, the nozzle 61 surely enters the reserve tank 1 by the desired length L ₁ .

Next, the fluid F is supplied through the passage 65 in the nozzle 61, and the fluid is injected into the reserve tank 1. The injection of the fluid F is stopped when the liquid level F ₁ exceeds the tip of the nozzle 61. When the injection of the fluid F is completed, the directional switching valve (not shown) connected to the nozzle 61 is switched, and the reserve tank 1 is switched by a vacuum pump or the like.
The fluid F inside is sucked up. by this,
The fluid level F ₁ of the fluid coincides with the tip surface of the injection portion 61b of the nozzle 61, so that the fluid level of the fluid F is reliably managed.

As described above, since the pressing operation of the seal member 89 against the liquid injection port 8 can be performed at the same time as the engaging operation with the flange portion 2b of the arm 64, only one cylinder portion 71 as a drive source is required.
The mechanism can be simplified.

Next, regarding the procedure for injecting the liquid into the resin-made reserve tank 11, in this case, the second claw 64b of the arm 64 is engaged with the collar portion 12a of the reserve tank 11. This second claw 64b
Is also set so that the tip of the injection part 61b of the nozzle 61 is located at the liquid level F ₁ that serves as the reference of the fluid F, so that the second claw 64b of the arm 64 engages with the collar part 12a. In the state, the nozzle 61 is securely inserted into the reserve tank 11 by a desired length L ₂ .

As described above, according to the present invention, the nozzle 61 can be positioned only by engaging the claws 64a and 64b of the arm 64 with the collar portions 2b and 12a of the reserve tanks 1 and 11, respectively. It is not necessary to change the height of the nozzle according to the type of the tank, and it is also possible to prevent the injection level of the fluid F from being inaccurate due to the failure of the metal detector.

In addition, in the present embodiment, an example in which the liquid is injected into the reserve tank made of metal and resin of the power steering system of the automobile has been shown, but the present invention is not limited to the reserve tank and can be applied to other containers.

[Effects of the Invention] According to the liquid injection gun of the present invention, the following effects can be obtained.

(1) Since the arm swingably supported by the support member is provided with a plurality of types of claws that can engage with the flanges of various containers, the claws depending on the type of the container are the flanges of the container. By engaging, the amount of protrusion of the injection part of the nozzle into the container can be changed according to the type of the container. As a result, the liquid injected into the container can be sucked up to the end surface of the injection portion of the nozzle, and the liquid injection level can be reliably managed according to the type of the container. Therefore, the reliability of the quality control can be improved as compared with the case where the type of the container is discriminated by the metal detector or the like as in the conventional structure and the injection level is controlled.

(2) A cylinder portion that moves in the axial direction by the pressure of the liquid is provided on the outer circumference of the nozzle, and the arm swinging means swings each arm in the radial direction around the nozzle by the movement of the cylinder portion in the axial direction. Therefore, the engaging operation of the arm with the flange portion and the pressing operation of the seal member with respect to the liquid injection port can be performed by one cylinder portion. Therefore, the mounting work becomes easier as compared with the manual mounting to the container, and the configuration of the liquid injection gun can be simplified.

(3) Further, since the arm swinging means is composed of the guide pin fixed to the cylinder portion and the guide elongated hole formed in the arm and into which the guide pin is inserted, even if an external force acts on the arm at the time of liquid injection, the pawl is provided. The engagement between the container and the flange portion of the container is not disengaged, and the injection work can be reliably performed.

[Brief description of drawings]

1 is a sectional view of a liquid injection gun according to the present invention, FIG. 2 is a sectional view showing a state of injecting a liquid into a metal reserve tank and a resin reserve tank using the apparatus of FIG. 1, 3 is a sectional view of the metal reserve tank shown in FIG. 2, FIG. 4 is a sectional view taken along line IV-IV of FIG. 3, and FIG. 5 is a sectional view of the resin reserve tank shown in FIG. 6 is a sectional view taken along line VI-VI of FIG. 5, FIG. 7 is a sectional view showing an example of a conventional liquid injection gun, and FIG. 8 is a sectional view showing another example of a conventional liquid injection gun. ,. 1 …… Container (metal reserve tank) 2b …… Collar part 8 …… Liquid injection port 11 …… Container (resin reserve tank) 12a …… Collar part 18 …… Liquid injection port 61 …… Nozzle 63… … Supporting part 64 …… Arm 64a… First claw 64b… Second claw 66… Arm swinging means 71… Cylinder part 87 …… Air vent passage 89 …… Seal member F …… Liquid

Claims (1)

[Scope of utility model registration request] 1. A plurality of arms, one of which is swingably supported by a support portion, and engageable with a collar portion which is provided on the arm and is formed in the vicinity of a liquid injection port of various containers having different shapes. A plurality of types of claws, one of which is fixed to the support portion, and the other of which has an injection portion that can enter the liquid injection port of the container, and bulges outward in the radial direction between the fixed portion and the injection portion. A nozzle having a fixed piston, a cylinder portion provided on the outer circumference of the nozzle and axially moving with respect to the nozzle by the pressure of a fluid supplied to a pressure chamber in which the fixed piston is fitted; A seal member is provided, which is pressed against the liquid injection port of the container by the axial movement of the cylinder part when the claw and the flange part are engaged with each other, and the liquid injection port of the container is provided on the cylinder part. Pressed by the seal member In the state, the cylinder includes an air vent passage that communicates the inside and the outside of the container, a plurality of guide pins fixed to the cylinder portion, and a guide elongated hole formed in each arm into which the guide pin is inserted. A liquid injection gun, comprising: arm swinging means for swinging each arm in a radial direction around a nozzle by moving the arm in the axial direction.