JP3119547U - Rapid joint structure for air driven tool intake - Google Patents

Abstract

An air-driven tool is detachable from a rapid joint and can be connected to the rapid joint at high speed, and can be rotated 360 degrees around the axis of the rapid joint, and can be rotated outward from the axis of the rapid joint at a predetermined angle. A structure of a rapid joint for an air driven tool intake is provided.
In the structure of a rapid joint for an air-driven tool inlet including an air-driven tool, a leakage prevention piston, a male joint, and a screw, the air-driven tool houses one elastic element at the bottom. One spring accommodating hole is provided, and a screw hole is provided in the opening of the bottom. The leakage preventing piston has one end in contact with the elastic element and the other end in contact with the male joint. The ball at one end is in contact with the piston for leakage prevention, the other end is inserted through a screw and protrudes outward, and the screw is screwed into a screw hole at the bottom of the air-driven tool.
[Selection] Figure 1

Description

The present invention relates to a structure of a rapid joint for an air driven tool inlet, and in particular, the air driven tool inlet is connected to a male joint of the rapid joint so that the air driven tool can be detached from the female joint of the rapid joint. A rapid joint for an air-driven tool inlet that can be connected at high speed, can be rotated 360 degrees around the axis of the rapid joint, and can be rotated outward from the axis of the rapid joint at a predetermined angle It is.

FIG. 4 shows an air gun 11 which is a conventional air-driven tool, and a male joint 15 of a rapid joint is required to be screwed into an intake port 14 at the end thereof, and the male joint 15 is an air pipe line. The female joint 17 screwed to 16 can be detachably and quickly connected. However, a general air-driven tool needs to swivel during use, and the air pipe 16 is also twisted according to the swiveling. As a result, it often affected the operation of pneumatic tools.

FIGS. 5 and 6 show a rapid joint set 30 that can be rotated 360 degrees around the axis of the rapid joint and that can be rotated outward from the axis of the rapid joint at a predetermined angle. The connecting screw 31 has one end connected to the pneumatic tool, the other end screwed to the connecting nut 32, a male joint 33 provided inside the connecting nut 32, and a ball 331. The upper and lower balls are respectively provided with an upper seal ring 341 and a lower seal ring 342, and a back hole 311 in an end face of the connecting screw 31 abuts on the upper seal ring 341, thereby the upper seal ring 341. And the lower seal ring 342 are in intimate contact with the ball 331 to achieve a leakage prevention effect. The male joint 33 can be rotated 360 degrees around the axis of the rapid joint, and can be rotated outward from the axis of the rapid joint at a predetermined angle. Since 16 is no longer twisted, the operation of the pneumatic tool is not affected.

However, since the upper seal ring 341 is often twisted and deformed when pressed by the connecting screw 31, the upper seal ring 341 cannot be in close contact with the ball 331, and air leakage is often caused. In addition, since the upper seal ring 341 and the lower seal ring 342 are in contact with the ball 331 in the form of line contact, the effect of preventing air leakage is not good. If it is worn for a long time, the effect of preventing air leakage is further deteriorated, so the service life of this rapid joint is not long.

In addition, the rapid joint set has an overall length of about 55 to 60 mm, and when attached to an air driven tool, the overall length becomes longer. Convenience of operation deteriorates.

The main object of the present invention is that the pneumatic tool can be detachably connected to the female joint of the rapid joint and can be quickly connected, and can be rotated 360 degrees around the axis of the rapid joint. Provided is a rapid joint structure for an air-driven tool inlet that can be turned outward at a predetermined angle.

The invention of the present application made to achieve the above object is a structure of a rapid joint for an air driven tool intake including an air driven tool, a leakage prevention piston, a male joint, and a screw. The bottom portion has one spring accommodating hole for accommodating one elastic element, the bottom opening has a screw hole, and one end of the leakage preventing piston is in contact with the elastic element and the other end is The male joint abuts on the male joint, the ball on one end abuts on the leakage prevention piston, the other end is inserted through a screw and protrudes outward, and the screw is a screw hole at the bottom of the air-driven tool. The gist of the present invention is the structure of a rapid joint for an air-driven tool inlet, which is characterized in that it is screwed to the air joint.

In the invention of the present application, the leak preventing piston has one O-ring, and the inside of the leak preventing piston is a tapered hole whose one end gradually expands from the end to the inside, 2. The rapid joint structure for an air-driven tool intake according to claim 1, wherein a spherical recess is provided in the opening, and the radius of curvature of the spherical recess is the same as that of the ball of the male joint. Is the gist.

In the invention of the present application, the screw has a through hole for accommodating a ball of a male joint at one end, and a tapered hole which is gradually reduced in diameter from the end surface to the other end. The gist of the present invention is the rapid joint structure for an air-driven tool intake according to claim 1, wherein one soft packing is provided between the hole and the tapered hole.

According to the structure of the rapid joint for an air-driven tool intake according to the present invention, the following effects are obtained.
(A) Since the rapid joint according to the present invention is pivotally attached to the intake port of the air driven tool, it is not necessary to separately attach the rapid joint as in the prior art.

(C) The rapid joint according to the present invention has good productivity and can be mass-produced.

(2) In the present invention, the high pressure air and the elastic element cause the leakage preventing piston and the ball to always come into close contact with each other, so that the air leakage preventing effect can be completely achieved.

(E) A pneumatic joint tool according to the present invention has a male joint pivotally attached thereto, and the male joint is capable of turning 360 degrees around the axis of the rapid joint, and is predetermined outward from the axis of the rapid joint. Since the air pipe 16 connected to the air driven tool is not twisted during use, the operation of the air driven tool is not affected.

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

First, FIG. 1 and FIG. 2 are referred. The structure of a rapid joint for an air driven tool inlet according to the present invention includes an air driven tool 40, a leakage preventing piston 60, a male joint 70, and a screw 80.

The air driven tool 40 is provided with one spring accommodating hole 41 for accommodating one elastic element 50 at the bottom, one end of the elastic element 50 abuts against the leakage preventing piston 60, and the air driven tool 40. One screw hole 42 is provided in the opening at the bottom of the.

The leakage preventing piston 60 is made of a soft material, and is provided with one O-ring 61 for sealing the leakage preventing piston 60 and the spring accommodating hole 41. The inside of the piston 60 is a tapered hole 62 with one end gradually expanding from the end to the inside, and a spherical recess 63 is provided in the opening at the other end. The curvature radius of the spherical recess 63 is the male joint 70. This is the same as the ball 71.

In the male joint 70, the ball 71 at one end contacts the spherical recess 63 of the leakage preventing piston 60, and the ball 71 is accommodated in the screw 80.

The screw 80 is screwed into a screw hole 42 at the bottom of the air driven tool 40, and a through hole 81 for receiving the ball 71 of the male joint 70 is provided at one end, and the other end is provided from an end face. A tapered hole 82 that gradually decreases in diameter is provided, and one soft packing 83 is provided between the through hole 81 and the tapered hole 82, and the ball 83 and the screw 80 are connected by the packing 83. Excessive wear can be prevented, and the leakage preventing piston 60 biased by the elastic element constantly contacts the ball 71, so that an air leakage preventing effect can be achieved.

Reference is also made to FIG. Since the male joint 70 according to the present invention is pivotally attached to the air driven tool 40 and can be quickly attached to and detached from the female joint 17 provided in the air duct 16, the user does not need to assemble the male joint separately. Usability becomes extremely convenient.

Reference is also made to FIGS. Since the ball 71 of the male joint 70 according to the present invention is pivotally mounted between the screw 80 and the leakage preventing piston 60, the male joint 70 can pivot 360 degrees about the axis of the rapid joint. Since the air pipe 16 connected to the air driven tool 40 is not twisted during use, the operation of the air driven tool 40 is not affected. In the precision lapping process, the phenomenon of insufficient processing or excessive processing is eliminated, and user fatigue can be reduced.

Reference is also made to FIGS. It is necessary that the ball 71 and the leakage preventing piston 60 are always in close contact with each other, so that air does not leak for the first time, and the ball 71 can be rotated 360 degrees about the axis of the rapid joint. Yes, it can be swung outward from the axis of the rapid joint at a predetermined angle. Therefore, the friction between the ball 71 and the leakage preventing piston 60 causes a slight amount of wear on the leakage preventing piston 60, and the service life is long. However, since the leakage prevention piston 60 biased by the elastic element 50 is constantly in contact with the ball 71, an air leakage prevention effect can be achieved, and the leakage prevention piston 60 is worn. However, the effect of preventing air leakage can be maintained and the service life is extended.

Reference is also made to FIG. When the compressed air fills the spring accommodating hole 41 and the tapered hole 62, the vertical force applied to the top surface of the leakage preventing piston 60 is larger than the vertical force in the tapered hole 62. Accordingly, the leakage preventing piston 60 and the ball 71 are always in close contact with each other, and an air leakage preventing effect can be achieved.

It is an exploded perspective view of the present invention. It is sectional drawing which shows the union state of this invention. It is the schematic which shows the pivotable angle of the male joint which concerns on this invention. It is the schematic which shows the connection of the conventional air gun and an air pipe line. It is side surface sectional drawing which shows the decomposition | disassembly state of the conventional rapid joint group. It is side surface sectional drawing which shows the combination state of the conventional rapid joint group. It is the schematic which shows the pivotable angle of the conventional rapid joint group.

Explanation of symbols

(Conventional part)
11 Air Gun 14 Intake Port 15 Male Joint 16 Air Pipe Line 17 Female Joint 30 Rapid Joint Assembly 31 Connecting Screw 311 Back Hole 32 Connecting Nut 33 Male Joint 331 Ball 341 Upper Seal Ring 342 Lower Seal Ring (Part of the Invention)
40 Air Drive Tool 41 Spring Housing Hole 42 Screw Hole 50 Elastic Element 60 Leakage Prevention Piston 61 O-ring 62 Tapered Hole 63 Spherical Depression 70 Male Joint 71 Ball 80 Screw 81 Through Hole 82 Tapered Hole 83 Packing

Claims (3)

In the structure of a rapid joint for an air driven tool intake including an air driven tool, a leakage prevention piston, a male joint, and a screw,
The air-driven tool is provided with one spring accommodating hole for accommodating one elastic element at the bottom, and a screw hole is provided at the opening at the bottom,
The leakage prevention piston has one end in contact with the elastic element and the other end in contact with the male joint,
The male joint has a ball at one end abutting against the leakage prevention piston, the other end is inserted through a screw and protrudes outward, and the screw is screwed into a screw hole at the bottom of the air-driven tool. Features a rapid joint structure for air-driven tool intake. The leakage prevention piston is provided with one O-ring, and the inside of the leakage prevention piston is a tapered hole with one end gradually expanding from the end to the inside, and a spherical recess is formed at the other end opening. The structure of a rapid joint for an air-driven tool intake according to claim 1, wherein the radius of curvature of the spherical recess is the same as that of the ball of the male joint. The screw has a through hole for accommodating a ball of a male joint at one end, and a tapered hole which is gradually reduced in diameter from the end surface to the inside at the other end. The structure of a rapid joint for an air-driven tool inlet according to claim 1, wherein one soft packing is provided between the two.