TWM626640U - Pneumatic impact tool with improved vibration damping structure - Google Patents

Abstract

The utility model relates to a pneumatic impact tool with an improved vibration damping structure, which comprises a handle with an alcove, and a cylinder and an air flow reversing valve are arranged in the alcove. The cylindrical piece is connected to an inner pipe piece, which includes a ring wall and a chamber, the ring wall is provided with at least one exhaust hole, and the ring wall is provided with an airflow channel connecting the airflow reversing valve and the chamber, and the airflow channel is in the chamber. The chamber forms a first air inlet and a second air inlet, and the air flow reversing valve can switch the air flow to enter the chamber. The chamber is provided with a hammer body closely connected to the ring wall, and a cylindrical gap is formed between the middle part and the ring wall. The hammer body is provided with an exhaust passage connecting the chamber and the cylindrical gap. When the high-pressure gas is injected into the chamber from the first air inlet, the hammer body is pushed backward, and the high-pressure gas passes through the exhaust passage and the cylindrical gap in sequence. And the exhaust hole to leak out, thereby reducing the force of the hammer to be pushed.

Description

Pneumatic impact tool with improved damping structure

This creation relates to hand tools, especially a pneumatic impact tool.

The pneumatic impact tool will vibrate due to the reciprocating displacement of the hammer body during use, which will adversely affect the palm of the user under long-term use. The greater the vibration, the greater the damage to the user, so it must be improved.

my country's Invention Patent Announcements No. I235700 and No. I729809 respectively disclose a pneumatic tool. In the structure of the barrel, an air chamber is arranged at the rear, so as to squeeze the air in the air chamber when the hammer body moves backward, so as to produce a buffer effect, and Reduce the vibration caused by the hammer body to the barrel. Figure 4 of I729809 discloses another pneumatic tool. There is a spring or a rubber block behind the barrel to push the spring or rubber block when the hammer body moves backwards, and it deforms to produce a buffer effect and lower the hammer. Vibration caused by the body to the barrel.

The above two conventional structures both add other components to the existing structure of the pneumatic tool (change the space configuration to form an air chamber, add a spring or a rubber block, etc.), and after the pneumatic tool generates a large amount of vibration, it is buffered. To reduce the vibration, in addition to the disadvantage of increased cost, the most important thing is that the vibration reduction effect is not ideal, and the user still feels uncomfortable in the operation.

In the structure disclosed in Fig. 5 of the above-mentioned I235700 patent, it is provided with an air intake pipe connected to the front end of the barrel, so as to move the hammer body that has moved to the front end of the barrel through high-pressure gas to move it backward, And about the middle of the barrel is provided with an exhaust hole for pressure relief. However, when the hammer body hits the tool head forward and rebounds back, the high-pressure gas in the barrel must be released after the hammer body passes through the exhaust hole in the middle position, but the gas has been discharged before it is released. The hammer body is driven back to the rear end of the barrel with high pressure, so as to hit the rear end of the barrel with a large force, which is the fundamental cause of the vibration of the pneumatic tool.

In view of this, how to improve the above problem is the primary issue that this creation intends to solve.

The main purpose of this creation is to provide a pneumatic impact tool with an improved vibration damping structure, which directly weakens the impact force of the hammer body retreating by means of air deflation by arranging an exhaust hole on the pipe fitting, thereby reducing vibration. Accordingly, the present invention produces the effect of vibration reduction without adding additional components.

In order to achieve the aforementioned purpose, the present invention provides a pneumatic impact tool with an improved vibration damping structure, which is characterized in that it includes: a handle, which is provided with an alcove inside, the handle is provided with an air inlet channel connected to the alcove, wherein an air flow switch is arranged in the air inlet channel; A cylindrical piece accommodated in the recessed cavity, the cylindrical piece is provided with an air flow reversing valve, and a side wall of the cylindrical piece is provided with a through hole communicating with the air inlet passage, so that the high-pressure gas can be introduced into the air flow reversing valve ; An inner tube includes a ring wall fixed on the cylinder and a chamber surrounded by the ring wall, a tool head is provided at the front end of the ring wall, and the ring wall is provided with at least one tool for connecting the chamber to the The external exhaust hole, the inside of the ring wall is provided with an airflow channel connecting the airflow reversing valve and the chamber, the airflow channel forms a first air inlet at the front end of the chamber, and the rear end of the chamber a second air inlet connected to the airflow reversing valve is provided, and the airflow reversing valve can switch the airflow to enter the chamber from the first air inlet or the second air inlet alternatively; A hammer body disposed in the chamber has a head and a body, wherein the head is closer to the first air inlet than the body, and the body includes a front section, a middle section and a body The rear section, wherein the front section and the rear section are closely connected to the annular wall, there is a cylindrical gap between the middle section and the annular wall, and the head is provided with an exhaust channel that communicates with the cavity and the cylindrical gap. When the airflow reversing valve injects high-pressure gas into the chamber from the second air inlet, the hammer body is pushed by the high-pressure gas to move toward the tool head; when the airflow reversing valve injects high-pressure gas from the first air inlet When the port is injected into the chamber, the hammer body is pushed away from the tool bit by the high-pressure gas. During this process, when the cylindrical gap communicates with the exhaust hole, the high-pressure gas in the chamber passes through the exhaust in sequence. The passage, the cylindrical gap and the exhaust hole leak out, thereby reducing the force of the hammer body being pushed.

Preferably, when the hammer body is in contact with the tool head, the cylindrical gap communicates with the exhaust hole.

Preferably, the annular wall is provided with three exhaust holes, and the distances between the exhaust holes and the tool head are different.

Furthermore, when the hammer body is in contact with the tool head, the cylindrical gap communicates with the two exhaust holes closest to the tool head.

Preferably, the exhaust passage includes an axial section and a radial section connected in a T-shape. The above-mentioned axial section is located in the center of the hammer head.

The above objects and advantages of the present invention can be easily understood from the detailed description and accompanying drawings of the following selected embodiments.

Please refer to Figures 1 and 2, which show a pneumatic impact tool with an improved vibration damping structure provided for this creation, including a handle 1 , a barrel 2 , an inner tube 3 and a hammer body 4 . The handle 1 can be in the shape of a pistol or a straight cylinder. In this embodiment, the handle 1 is in the shape of a pistol. The top of the handle 1 is provided with an alcove 11 . The bottom of the handle 1 is provided with an air inlet channel 12 extending upward and communicating with the recess 11 for connecting to an external high-pressure gas supply source. The air intake passage 12 is provided with an air flow switch 13 for controlling the passage of air, and a button 14 is connected to the air flow switch 13 on one side of the handle 1 for operation.

The cylindrical member 2 of this embodiment is accommodated in the concave chamber 11 , and the bottom end of the concave chamber 11 is provided with a spring 15 for buffering the cylindrical member 2 . A through hole 21 communicated with the air inlet passage 12 is formed on the side wall of the cylindrical member 2, and a conventional airflow reversing valve 22 is arranged in the cylindrical member 2. After the high-pressure gas is introduced into the air inlet passage 12, it will pass through the air inlet passage 12. The through hole 21 enters the air flow reversing valve 22, and the air flow reversing valve 22 is used to output the high-pressure gas in two different paths.

The inner pipe member 3 is a round pipe structure with a ring wall 31 and a cavity 32 surrounded by the ring wall 31 , wherein the ring wall 31 extends into the cylinder member 2 and is fastened to the cylinder member 2 by threads superior. The inner pipe member 3 protrudes out of the cylinder member 2, and a tool head 5 is arranged at the front end thereof, and the tool head 5 can be replaced according to actual use requirements. The annular wall 31 is different from the chamber 32 and has an airflow channel 33 connected to the airflow reversing valve 22 , and a first air inlet 34 is formed at the front end of the chamber 32 ; and the chamber 32 The rear end is provided with a second air inlet 35 connected to the airflow reversing valve 22 . Accordingly, the airflow reversing valve 22 can selectively output high-pressure gas to the airflow channel 33 at an appropriate time, and then inject the high-pressure gas into the chamber 32 through the first air inlet 34; The air inlet 35 is injected into the chamber 32 .

Furthermore, the annular wall 31 is provided with at least one exhaust hole 36 for connecting the chamber 32 to the outside; in this embodiment, the number of the exhaust holes 36 is three, which are along the axial direction of the inner pipe member 3 . Arranged in a straight line, the distances between the exhaust holes 36 and the tool head 5 are different. Furthermore, the above-mentioned three exhaust holes 36 are disposed between the first air inlet 34 and the second air inlet 35 .

As shown in Figs. 2 and 3, the hammer body 4 is disposed in the chamber 32, and includes a head portion 41 and a body portion 42 integrally connected, wherein the head portion 41 is closer to the body portion 42 than the body portion 42. The first air inlet 34 . In this embodiment, the head 41 is formed in a conical shape, and has a flat end surface 411 . The body 42 is cylindrical and includes a front section 421 , a middle section 422 and a rear section 423 , wherein the outer diameter of the front section 421 and the rear section 423 are equal to the inner diameter of the cavity 32 , and are then closely connected to the surrounding wall 31 ; And the outer diameter of the middle section 422 is slightly smaller than the outer diameter of the front section 421 and the rear section 423, and is also slightly smaller than the inner diameter of the chamber 32, and then a tube is formed between the middle section 422 and the ring wall 31 shaped gap 43 .

The inside of the hammer body 4 is provided with an exhaust passage 44 communicating with the cavity 32 and the cylindrical gap 43 . In this embodiment, the exhaust passage 44 includes an axial section 441 drilled and formed in the axial direction from the central position of the end surface 411 of the head 41 , and an axial section 441 formed by drilling from the middle section 422 in the radial direction. The radial segments 442 meet to form a T-shaped communication.

In this embodiment, the relative positional relationship between the cylindrical gap 43 and the exhaust hole 36 is as shown in FIG. 4 . In detail, when the hammer body 4 moves to the position where the front end of the chamber 32 contacts the tool head 5 , the extension range of the cylindrical gap 43 reaches the two exhaust holes closest to the tool head 5 36, and the connection port between the radial section 442 of the exhaust passage 44 and the cylindrical gap 43 is located near the front section 421.

With the above structure, when the button 14 is pressed to control the airflow switch 13 and the high-pressure gas is introduced into the airflow reversing valve 22 through the intake passage 12 , the airflow reversing valve 22 first sends the high-pressure gas from the second air inlet 35 . When injected into the chamber 32 , the high-pressure gas pushes the hammer body 4 to move forward at a high speed, and hits the tool head 5 to produce a working effect. Next, the air flow reversing valve 22 switches the air supply path, stops injecting high-pressure gas into the chamber 32 from the second air inlet 35, and instead introduces the high-pressure air into the air passage 33, and then the first air inlet Port 34 fills this chamber 32 . As for the technology of switching the air supply path by the airflow reversing valve 22 , it is a common and conventional technology, and details are not repeated here.

At this time, the high pressure gas starts to push the hammer body 4 to move backward. As shown in FIGS. 5 and 6 , when the hammer body 4 begins to leave the tool head 5 , the high-pressure gas in the chamber 32 can begin to pass through the axial section 441 and the radial section 442 of the exhaust passage 44 . , together with the cylindrical gap 43 and the exhaust hole 36 all the way to the outside, reducing the pressure in the chamber 32, thereby weakening the force of the hammer body 4 being pushed, accordingly when the hammer body 4 moves to the chamber At the end of the 32, the amplitude of the vibration caused will be reduced.

In addition, in the process of vibration reduction of the present invention, when the hammer body 4 is located at the front end of the chamber 32 as shown in FIG. The deflation can be started. Compared with the conventional structure, the deflation timing of the present creation is earlier, so that the force for pushing the hammer body 4 to a larger extent can be weakened. And during the retreating process of the hammer body 4 , as shown in FIG. 5 , different exhaust holes 36 can be connected through the cylindrical gap 43 to continuously deflate the air, so that the force of the hammer body 4 being pushed back is continuously weakened, and the vibration occurs. will be substantially weakened.

The feature of this creation is that at the source of the vibration of the pneumatic tool (that is, the impact force of the hammer body 4 retreating), the method of deflation directly weakens the impact force of the hammer body 4 retreating, so as to achieve the purpose of curing the root cause, it can produce more conventional The better vibration damping effect of the structure does not affect the force of the high-pressure gas driving the hammer body to strike the tool head, so the vibration damping effect can be produced under the premise of taking into account the output power of the pneumatic tool.

However, the disclosure of the above embodiments is only used to illustrate the present creation, not to limit the present creation, and the replacement of equivalent elements should still belong to the scope of the present creation.

To sum up, those skilled in the art can understand that this creation can indeed achieve the above-mentioned purpose, and it actually complies with the provisions of the Patent Law, and an application can be filed in accordance with the law.

1: Grip 11: Alcove 12: Intake channel 13: Airflow switch 14: Button 15: Spring 2: Cartridge 21: Through hole 22: Air flow reversing valve 3: Inner pipe fittings 31: Ring Wall 32: Chamber 33: Air flow channel 34: First air intake 35: Second air intake 36: exhaust hole 4: Hammer body 41: Head 411: End face 42: Body 421: The first paragraph 422: middle section 423: Backstage 43: Cylindrical gap 44: Exhaust channel 441: Axial segment 442: Radial segment 5: Tool head

Figure 1 is a three-dimensional exploded schematic diagram of the creation; Figure 2 is a schematic cross-sectional view of the entire creation; Figure 3 is a schematic cross-sectional view of the hammer body; Figures 4 to 6 are schematic diagrams of the action state of the creation.

1: Grip

11: Alcove

12: Intake channel

13: Airflow switch

14: Button

15: Spring

2: Cartridge

21: Through hole

22: Air flow reversing valve

3: Inner pipe fittings

31: Ring Wall

32: Chamber

33: Air flow channel

34: First air intake

35: Second air intake

36: exhaust hole

4: Hammer body

441: Axial segment

442: Radial segment

5: Tool head

Claims (6)

A pneumatic impact tool with an improved vibration damping structure, characterized in that it includes: a handle, which is provided with an alcove inside, the handle is provided with an air inlet channel connected to the alcove, wherein an air flow switch is arranged in the air inlet channel; A cylindrical piece accommodated in the recessed cavity, the cylindrical piece is provided with an air flow reversing valve, and a side wall of the cylindrical piece is provided with a through hole communicating with the air inlet passage, so that the high-pressure gas can be introduced into the air flow reversing valve ; An inner tube includes a ring wall fixed on the cylinder and a chamber surrounded by the ring wall, a tool head is provided at the front end of the ring wall, and the ring wall is provided with at least one tool for connecting the chamber to the The external exhaust hole, the inside of the ring wall is provided with an airflow channel connecting the airflow reversing valve and the chamber, the airflow channel forms a first air inlet at the front end of the chamber, and the rear end of the chamber a second air inlet connected to the airflow reversing valve is provided, and the airflow reversing valve can switch the airflow to enter the chamber from the first air inlet or the second air inlet alternatively; A hammer body disposed in the chamber has a head and a body, wherein the head is closer to the first air inlet than the body, and the body includes a front section, a middle section and a body The rear section, wherein the front section and the rear section are closely connected to the annular wall, there is a cylindrical gap between the middle section and the annular wall, and the head is provided with an exhaust channel that communicates with the cavity and the cylindrical gap. When the airflow reversing valve injects high-pressure gas into the chamber from the second air inlet, the hammer body is pushed by the high-pressure gas to move toward the tool head; when the airflow reversing valve injects high-pressure gas from the first air inlet When the port is injected into the chamber, the hammer body is pushed away from the tool bit by the high-pressure gas. During this process, when the cylindrical gap communicates with the exhaust hole, the high-pressure gas in the chamber passes through the exhaust in sequence. The passage, the cylindrical gap and the exhaust hole leak out, thereby reducing the force of the hammer body being pushed. The pneumatic impact tool with an improved vibration damping structure as claimed in claim 1, wherein when the hammer body is at a position in contact with the tool head, the cylindrical gap communicates with the exhaust hole. The pneumatic impact tool with an improved vibration damping structure as claimed in claim 1, wherein the annular wall is provided with three exhaust holes, and the distances between the exhaust holes and the tool head are respectively different. The pneumatic impact tool with an improved vibration damping structure as claimed in claim 3, wherein when the hammer body is in a position in contact with the tool head, the cylindrical gap is connected to the two rows of the two closest to the tool head. The pores are connected. The pneumatic impact tool with an improved vibration damping structure as claimed in claim 1, wherein the exhaust passage includes an axial section and a radial section connected in a T-shape. The pneumatic impact tool with improved vibration damping structure as claimed in claim 5, wherein the axial section is located at the center of the hammer head.

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