KR101410404B1 - Air hammer tool, and method of adjusting impact force of the air hammer tool - Google Patents

Abstract

The present invention provides an air hammer tool in which vibration transmission to an operator is largely suppressed, and also a structure is simple and lightweight, can be manufactured at low cost, and can be easily maintained. In the air hammer tool 1A, a single coil spring 9 (elastic body) is fitted on the outer periphery of the cylinder portion 11 of the slide moving body 8 and fitted to the front end portion When the coil spring 9 is installed as a compression spring and the trigger 4a is operated between the spring fixing member 16 fixed to the front end portion of the slide moving body 8 and the front end surface 10a of the slide moving body 8 The slide moving body 8 is pushed forward by the compressed air so that the coil spring 9 is contracted and the slide moving body 8 is pressed backward State.

Description

Technical Field [0001] The present invention relates to an air hammer tool, and a method of adjusting the impact force of the air hammer tool,

The present invention can be applied to a variety of applications including, for example, rock drills, concrete breakers, chipping machines, nailing machines, riveters, pile drivers, Such as road leveler, compactor, rammer, tamper, voltage changer, asphalt or concrete grounding machine, so-called jet chisel To an air hammer tool configured as a target.

Conventionally, various air hammer tools as described above have been proposed (see Patent Documents 1 to 4). In addition, a structure having a vibration damping device is already disclosed so that the impact generated by the reciprocating movement of the piston mounted in the air hammer tool can not be transmitted to the operator 5). For example, the configuration disclosed in Patent Document 5 has a cushioning chamber filled with a cushioning liquid, a cushioning cylinder into which a cushioning slide moving body is inserted, (Mechanism) formed of a communication hole formed in a shock-absorbing cylinder for communicating the inside of the shock absorber cylinder.

Japanese Patent No. 4340081 Japanese Patent No. 3825802 Japanese Patent No. 2746712 Japanese Patent Application Laid-Open No. 1996-197458 Japanese Patent Application Laid-Open No. 1997-11156

However, in the configurations of Patent Documents 1 to 4, since the tip end of a chisel or the like which has obtained kinetic energy due to the impact of the hammer vibrates strongly against the tool body, The tool body vibrates more strongly. Therefore, in order to prevent the air hammer tool from splashing, or to prevent the position of the tip end from being displaced from the striking object such as an object to be broken, or to effectively transmit the force due to the vibration of the end sill to the striking object , The worker who is working should always press the tool body strongly against the strong vibration and the strong vibration is transmitted to the worker and the worker's body is seriously obstructed by the use of the worker for a long period of time There was a problem that the possibility was high. In addition, there is a fear that noise during operation caused by vibration of the distal end sphere or collision between the distal end sphere and the hammer may cause obstacles to hearing loss to an operator or people around the operation site.

The configuration of Patent Document 5 has a possibility of solving the above problem and in order to fill the buffer body with the buffer liquid for obtaining a sufficient buffering effect, the buffer chamber is enlarged, And the weight is increased. As a result, there is a problem that it is very difficult for the operator to handle. In addition, since the buffer liquid must be filled in the air hammer body without leaking, the internal structure is highly precise and complex, which raises the manufacturing cost. In addition, since the number of components of the air hammer tool is increased, disassembly and cleaning become extremely troublesome, and maintenance can not be easily performed. For these reasons, the structure disclosed in Patent Document 5 is extremely impractical and is not currently on the market.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an air hammer tool that drastically reduces vibrations and noise transmitted to an operator, is simple and light in structure, can be manufactured at low cost, and can be easily maintained, And to provide a method of adjusting the hitting force of the hitting device.

According to the present invention, there is provided an air conditioner comprising: a cover body; and a front end protruding forward from the cover body, wherein an impact force, which is obtained by a gas pressurized into the cover body, The hammer tool according to claim 1, wherein the cover body has an inner space portion formed along the front-rear direction, and a gas press-in portion for press-fitting the gas forward into the inner space portion is formed in the peripheral wall of the cover body, And an elastic body provided between the outer circumferential surface of the slide moving body and the inner circumferential surface of the cover body is mounted with the slide moving body capable of sliding forward and backward and the rear end surface of the slide moving body in the inner side space portion, A compressed air inflow chamber in which airtightness is enhanced is formed between the inner circumferential surface of the cover member and the inner circumferential surface of the cover member facing the end surface, Wherein the slide moving body has a slide moving body body and a cylindrical cylinder portion provided at a front end portion of the slide moving body body portion and projecting forward from the cover body, And a gas introducing portion for guiding the gas injected into the cylinder into the cylinder portion is formed in the cylinder portion, and a hammer is mounted so as to be slidable back and forth in the cylinder portion, Wherein when the gas is press-fitted into the cover body through the gas press-in portion, the gas is introduced into the compressed air inflow chamber, and the slide moving body is moved by the pressure of the gas, In the cover body, advancing while elastically deforming the elastic body, The hammer is reciprocated back and forth in the cylinder portion by the gas introduced through the gas introduction portion into the dummy portion so as to repeatedly collide with the rear end portion of the distal end sphere to obtain the striking force, The coil spring is interposed between the front end surface of the slide moving body body and the inner circumferential surface of the cover body so as to be oriented in the longitudinal direction and the gas is press-fitted into the cover body through the gas press- The coil spring biases the slide moving body backward when the slide moving body advances and a coil spring as an elastic body is provided between the rear end face of the slide moving body and the inner peripheral surface of the cover body, The coil spring is oriented in the front-rear direction and is also opened in a contracted state, The gas is press-fitted portion through the base body in the press-in cover member is air hammer tool, characterized in that for pressing the moving body slides forward in the state in which the mobile body is a slide forward in the forward direction.

As described above, the air hammer tool of the present invention is characterized in that the air hammer tool of the present invention has a cover body and a slide moving body in which a hammer striking a tip end is inserted, separately, and between the cover body and the slide moving body, In which the light emitting diode is interposed. In such a configuration, since the inertia of the hammer and the reciprocating motion of the hammer in the slide moving body are preferably absorbed by the elastic body, a large vibration Is not easily transmitted.

The second feature of the air hammer tool of the present invention is that, in addition to the first feature point, the cylinder portion and the distal end sphere are fixed so that the distal end sphere can not be moved relative to the cylinder portion. In this configuration, when the work is performed by applying a hitting force to the hitting object, the tip of the tip is brought into contact with the hitting object to operate the air hammer tool. Then, when the hammer in the cylinder part collides with the tip end, the tip end functions as a so-called " chisel ", and the impact force due to the inertia of the hammer is applied to the impact object via the tip end. Therefore, the air hammer tool does not vigorously vibrate and noise generated by the vibration of the tip end bore does not occur as compared with the conventional configuration in which the impact force is applied to the impact target by the vibration of the tip bore itself. Therefore, in addition to the advantages of the first feature point, the vibration and noise transmitted to the worker can be drastically reduced, and an air hammer tool can be provided which sufficiently considers the health of workers and the like.

Further, in the air hammer tool of the present invention, when the slide moving body is advanced by press-fitting of the gas during operation, the tip end of the air hammer tool is located at the protruding position near the front side. On the other hand, The slide moving body is returned to the initial position by the restoring force of the elastic body, and the tip end is moved to the retracted position. That is, when the operation is interrupted, the operator usually needs to stop the pressurization of the gas and further move the air hammer tool itself away from the object to be hurt so as to separate the tip from the impact object. However, in the present invention, the distal end sphere is retracted backward away from the impact object without intentionally performing the operation of moving the air hammer tool itself away from the impact object. Therefore, for example, when a plurality of workpieces (striking objects) are sequentially processed using the air hammer tool of the present invention, the air hammer tool itself is not moved away from the workpiece every time the operation is interrupted, It becomes possible to sequentially exchange the workpiece each time the workpiece is moved away from the workpiece.

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The coil spring, which is elastically compressed when the slide moving body advances and presses the slide moving body backward, has a function of absorbing the inertia of the hammer which reciprocates when the hammer and the tip of the slide moving body collide with each other, And a function of returning the slide moving body to the initial position when stopping the press of the gas to interrupt the operation. Since the air hammer tool having such a configuration uses an elastic body made of a solid material that does not use a buffer liquid, it does not require the addition of a large-sized mechanism other than the coil spring. Therefore, do. Therefore, the increase in weight as a whole is suppressed, and the entire tool becomes compact. Thereby, the handling property is not deteriorated and the maintenance easiness is also excellent.

Here, in the configuration in which only the coil springs interposed between the front end surface of the slide moving body and the inner circumferential surface of the cover body are mounted, by the absorbing function of the coil spring as described above, Since the slide moving body is always pressed backward by the reaction force of the coil spring at the time of use, the pushing pressure against the striking object of the tip end is decreased and the striking force as a whole weakens, When the feed of the press-in gas for extruding the slide moving body forward becomes unstable, the slide moving body may be projected in the cover body and a stable striking force can not be obtained. Thus, in order to make a new improvement, the above configuration is proposed.

That is, a coil spring as an elastic body is arranged in the front-rear direction and also in a state of being elastically stretched between the rear end surface of the slide moving body and the inner peripheral surface of the cover body, The gas is press-fitted through the press-in portion of the gas and the slide moving body is forwardly pressed in a state in which the slide moving body advances forward.

In the above arrangement, the coil spring for urging the slide moving body forward in a state in which the slide moving body is advanced forward, pressurizes the slide moving body appropriately to the striking object by moderately pressing the slide moving body, It is possible to prevent splashing. As a result, a stable striking force can be obtained.

In the above air hammer tool, it is preferable that a coil spring interposed between a front end surface of the slide moving body and an inner circumferential surface of the cover is a first coil spring, and the rear end surface And the coil spring interposed between the inner peripheral surface of the cover member and the inner peripheral surface of the cover member is a second coil spring and the urging force is adjusted by changing the pressing force of the second coil spring with respect to the slide moving member. This is a method of adjusting the impact force of the tool.

For example, when the pressing force of the second coil spring against the slide moving body is increased, the hitting force is increased. On the other hand, when the pressing force is weakened, the hitting force is decreased. With this configuration, it is possible to easily fine-adjust the hitting force of the air hammer tool while preventing a large vibration from being transmitted to the operator.

In addition, the following configuration may be employed. That is, an air control body to which a gas is supplied from the outside is disposed on the rear side of the cover body, and a gas supplied from the outside is supplied to the air- And a cylindrical gripper is fitted in the outer periphery of the cover member and / or the outer periphery of the air control member from outside along the front-rear direction with an elastic member interposed therebetween .

The clasp is attached to the cover member or the air control member with the elastic member interposed therebetween. Therefore, when the worker is working with the gripper, the vibration transmitted to the worker is largely suppressed by the front and rear vibrations generated in the cylinder portion being absorbed by the elastic member. For example, the worker grips the gripper body mounted on the cover body with one hand and grips the gripper body mounted on the air control body with the other hand, thereby greatly reducing the burden due to vibration.

 INDUSTRIAL APPLICABILITY The air hammer tool of the present invention is remarkably reduced in vibration and noise transmitted to an operator, and is simple in structure and light in weight so that it can be manufactured at low cost and can be easily maintained. In addition, the method of adjusting the hitting force of the air hammer tool of the present invention has an effect that the hitting force can be finely adjusted easily.

1 is a longitudinal sectional view of an air hammer tool.
2 is a longitudinal sectional view showing another state of the air hammer tool.
3 is a sectional view taken along the line A-A in Fig.
4 is a partial longitudinal sectional view showing the inside of the cylinder portion in an enlarged manner.
Fig. 5 is a graph showing a comparison between the air hammer tool according to the present invention and the conventional product, wherein (a) shows an average value, (b) shows a change in performance (C) shows the performance change over time in the conventional product.
Fig. 6 is a conceptual diagram showing a measurement mode.
7 is a longitudinal sectional view of another type of air hammer tool.
8 is a longitudinal sectional view of another type of air hammer tool.

Embodiments of the air hammer tool of the present invention will be described with reference to the accompanying drawings.

For the sake of convenience, the front end direction of the air hammer tool is forward and the base end direction is rearward, but it is not excluded that the air hammer tool is used in the upward direction or the downward direction. Further, the air hammer tool of the present invention is not limited to the following embodiments, but can be appropriately changed in design without departing from the gist of the present invention.

As shown in Fig. 1, the air hammer tool 1A is a tool using compressed air (gas), and includes a cover body 2 in which the compressed air is press-fitted from the outside, And a distal end opening 20 formed therein.

The cover body 2 is made of a metal material and includes a grip portion 3a held by a worker in operation and a substantially cylindrical body portion coupled to the upper portion of the grip portion 3a along the front- 3b.

A tree rejection 4a is provided on the front portion of the grip portion 3a. By operating the tree rejection 4a, the supply of compressed air to the air hammer tool 1A can be controlled. A feed mechanism 4b for introducing compressed air from the outside is provided at the lower end of the grip portion 3a.

A known mechanism is preferably employed as the compressed air introduction mechanism for introducing the compressed air from the outside into the cover member 2 and for controlling the inflow of the compressed air by the tree rejection 4a.

The main body portion 3b has an inner space portion 2a formed along the front-rear direction. A press-in portion 6a for pressurizing the compressed air is provided in the inner space 2a in the rear peripheral wall of the main body portion 3b. In addition, a valve 5 is provided adjacent to the press-fitting portion 6a of the base body. The compressed air introduced from the grip portion 3a flows into the inner space 2a of the main body portion 3b through the valve 5. A gas discharging portion 6b is formed in the front peripheral wall of the main body portion 3b so that the compressed air introduced into the main body portion 3b can be discharged to the outside.

In addition, the slide moving body 8 is mounted on the inner space 2a of the main body portion 3b so as to be slidable in the front-rear direction. As shown in Fig. 1, the slide moving body 8 is formed of a metallic material and has a cylindrical main body portion 10 having a large diameter and a front end face 10a of the slide moving body 10, 10a extending in the forward direction from the center of the cylinder. The cylinder portion 11 protrudes from the cover body 2 through a connection portion 6c with a cylinder portion opened at the front end of the body portion 3b. A bearing member 17 is internally connected to an inner edge of the cylinder portion connection hole 6c and the cylinder portion 11 is supported by the bearing member 17 so as to be slidable.

In addition, a plurality of O-rings 12 are mounted on the outer peripheral surface of the slide moving body main body 10. The O-ring 12 is in close contact with the inner circumferential surface of the main body 3b. In the inner space portion 2a of the main body portion 3b, between the rear end surface of the slide moving body 8 and the inner peripheral surface of the main body portion 3b facing the rear end surface, airtightness And the compressed air inflow chamber 7 in which the air tightness is increased is formed.

In addition, as shown in Figs. 3 and 4, a plurality of gas passages (passages) are formed in the slide moving body main body portion 10 so as to pass therethrough. The gas discharge relay section 13 is constituted by the gas flow path for communicating the compressed air inflow chamber 7 and the gas discharge section 6b of the main body part 3b among the plurality of gas flow paths, The gas introducing portion 14a is constituted by a gas flow passage for communicating the inside of the cylinder portion 11 with the compressed air inflow chamber 7.

Further, as shown in Fig. 4, the cylinder portion 11 of the slide moving body 8 has an outer cylinder portion 11a. An air supply / discharge switching valve 14c is provided at the proximal end portion of the outer cylinder 11a. A mounting portion 18 formed by thickening the peripheral wall around the front opening portion 8a inward is formed in the front opening portion 8a of the outer cylinder portion 11a and the mounting portion 18 is provided with the front end opening 20 are fixed relative to the cylinder portion 11 so as not to move relative to each other.

4, the distal end opening 20 is made of a metal material, and has a distal end shed body 22 and a pile type chipping, which is attached to the distal end of the distal end suturing body 22, A disc-shaped stop portion 20b formed at a middle portion of the distal end sphere body 22 and a rear end portion 20c projecting rearward from the center of the stop portion 20b; ). The rear end portion 20c of the distal end opening 20 is inserted into the mounting portion 18 from the front opening portion 8a of the outer cylindrical portion 11a to be inserted into the cylinder portion 11, 20b abuts the distal end surface of the outer tube 11a. A cap type chuck body 15 having a tip opening 15a through which the tip end bulb 20 is inserted is opened at the contact point. The stop portion 20b is held on the outer periphery of the mounting portion 18 while being held by the inner surface of the chuck body 15 and the front end surface of the outer tube portion 11a in a state in which the chuck body 15 is covered, The chuck body 15 and the tip end portion of the cylinder portion 11 are screwed together with the O-ring 15b interposed therebetween. As a result, the distal end opening (20) is firmly fixed without falling off the cylinder portion (11). The chuck body 15 can be attached to and detached from the cylinder portion 11, so that the distal end opening 20 can be replaced.

Next, the structure of the distal end opening 20 will be described in more detail.

4, a shaft portion 20e is coupled to the base end portion of the chipping member 20a, and an O-ring 20f is attached to the shaft portion 20e. The shaft portion 20e is fitted and fixed to the front end of the distal end sphere body 22. The shaft portion 20e can be pulled out or inserted into the distal end sill body 22 so that the shaving member 20a can be replaced as appropriate.

Further, as shown in Fig. 4, the forward portion of the stopper portion 20b of the distal end sill body 22 is cylindrical. A cushioning material 21 made of a fiber material such as a felt (needle punch nonwoven fabric) made of polyester fiber is filled in the inside of the tip sphere body 22, and the noise is reduced by the fiber material have. A heat dissipation hole 20d for preventing the temperature of the buffer material 21 from excessively rising due to heat energy is formed in the peripheral wall of the distal end sphere body 22 at a portion filled with the buffer material 21 Are formed.

Next, the cylinder portion 11 will be described in detail.

A hammer 30 made of a metal material is slidably mounted in the outer cylinder 11a of the cylinder 11. In the hammer 30, the optimum size and weight are appropriately set.

As shown in Fig. 1 and the like, a single coil spring 9 (elastic body) is fitted on the outer periphery of the cylinder portion 11 from the outside. More specifically, the cover member 2 has an annular spring fixing portion 16 provided at a front end portion of the main body portion 3b, and the coil spring 9 is in a state of being oriented along the front- And is provided between the rear end face 16a of the annular spring fixing portion 16 and the front end face 10a of the slide moving body main body portion 10 and functions as a compression spring.

When the above-described air hammer tool 1A is used, the trigger 4a is actuated in a state in which the tip of the distal end bulb 20 is strongly pressed against a striking object (not shown) such as a rock or a concrete block. Then, the compressed air is continuously pressed into the compressed air inflow chamber 7 while being prevented by the valve 5 from backward flow to the air supply mechanism 4b through the press-in portion 6a of the gas in the main body portion 3b . Then, the slide moving body 8 is extruded forward by the pressure increased in the compressed air inflow chamber 7. The volume of the compressed air inflow chamber 7 is enlarged and the coil spring 9 is urged toward the spring fixing portion 16 And is elastically stretched between the slide moving body 10 and the slide moving body 8 to press the slide moving body 8 backward.

The compressed air sucked into the main body portion 3b is discharged to the outside of the cover body 2 from the gas discharge portion 6b via the gas discharge relay portion 13 formed on the slide moving body main body portion 10. [ At the same time, the compressed air pushed into the main body portion 3b is introduced into the cylinder portion 11 through the gas introducing portion 14a of the slide carriage body portion 10, So that the hammer 30 reciprocates in the anteroposterior direction. Then, the reciprocating hammer 30 repeatedly collides with the rear end 20c of the distal end 20. As a result, the impact force is continuously applied to the impact object via the tip 20. As a mechanism for reciprocating the hammer 30 in the cylinder portion 11, a well-known mechanism can be preferably employed. For example, a well-known mechanism disclosed in Japanese Laid-Open Patent Publication No. 1997-11156 can be applied to the air hammer tool 1A.

In the above configuration, the cover body 2 held by a worker is separated from the slide moving body 8 into which the hammer 30 hitting the tip end 20 is inserted. Further, the cover body 2, The coil spring 9 is interposed between the slide moving body 8 and the slide moving body 8 so that the impact generated when the hammer 30 and the tip end bulb 20 collide with each other or the inertia of the reciprocating hammer 30, And is preferably absorbed by the coil spring 9. Therefore, transmission of vibration to an operator using the air hammer tool 1A is effectively suppressed.

The distal end opening 20 is integral with the slide moving body 8 and conveys the hitting force generated when the hammer 30 is impacted to the striking object so that the grip portion 20 of the cover body 2 3a do not transmit a large vibration. Therefore, the air hammer tool 1A is very slight in vibration compared to the air hammer tool in which the tip of the conventional structure is vibrated. As a result, by using the air hammer tool of the conventional configuration, The occurrence of a serious problem such as a disorder of hearing loss can be suppressed.

In addition, the air hammer tool 1A has a simple internal structure, a small number of parts, a compact overall structure, and a light weight. Therefore, the manufacturing cost is reduced. In addition, there is an advantage that the disassembly is facilitated and the maintenance work is facilitated.

When the operation is interrupted by operating the trigger 4a, the air hammer tool 1A is operated so that the pressure of the compressed air (see FIG. 1) And the slide moving body 8 returns to the initial position by the urging force of the coil spring 9 and the tip end 20 becomes the retracted position (see FIG. 2). That is, in the air hammer tool 1A, when the operation is stopped and press-fitting of the compressed air is stopped, the tip end 20 itself is evacuated to the rear and away from the impact target. Therefore, it is not necessary to perform the operation of moving the air hammer tool 1A itself away from the workpiece every time the work is interrupted, for example, when a plurality of workpieces (impact targets) are sequentially processed. Thereby, for example, it becomes possible to sequentially exchange workpieces in accordance with the timing at which the tip ends 20 retreat.

For reference, the noise measured by the trial product corresponding to the above configuration is about 90 dB, and the noise measured by the general-purpose conventional product without the coil spring 9 is about 95 dB (Used sound meter: Model SL-310 multi-meter sales company).

5, the vibration hammer performance is shown in comparison with the air hammer tool according to the present invention and the prior art (not including the coil spring 9). The vibration was measured by measuring three axes (front and rear, upper and lower, left and right) at the rear end of the tool body as shown in Fig. 6 with a commercially available three-axis vibration system. The compressed air pressure used in the measurement was 0.25 MPa. The measurement time was 10 seconds (T). The shape of the distal end opening 20 was a brush type. (Type: UV0) manufactured by RON CORPORATION was used as a vibration system. (Type: DL750) manufactured by Yokogawa Electric Corporation was used as a measuring instrument. (Type: PV-97C) was used as a piezoelectric acceleration peak. (Model: VE-10) manufactured by RON CORPORATION was used as a vibration calibrator.

As shown in Fig. 5 (a), as a result of the measurement, it was found that the present invention was superior in vibration absorption performance to all three axes as compared with the conventional product. Particularly, about the longitudinal vibration, the attenuation amount (attenuation amount) of about 92% was obtained. As shown in Figs. 5 (b) and 5 (c), the measured values obtained by the three-axis vibration system described above were stable with less unevenness within the measurement time. Thus, it can be seen that the vibration absorbing performance of the air hammer tool according to the present invention is clearly improved by objective measurement.

[Example 2]

Hereinafter, the air hammer tool 1B according to the second embodiment will be described, but the points common to the first embodiment will be described briefly or omitted, and the same reference numerals are given to the same.

As shown in Fig. 7, the air hammer tool 1B includes a first coil spring 91 and a second coil spring 92. The first coil spring 91 is provided between the front end face 10a of the slide moving body 10 and the front end inner peripheral end face 25a of the cover body 2 in the slide moving body 8, As shown in FIG. On the other hand, the second coil spring 92 has a rear end face 10b of the slide moving body 10 and a body portion 3b located behind the rear end face 10b in the slide moving body 8, And the end face 16b formed on the inner peripheral surface of the base member 16 in the front-rear direction. Then, in such a mounted state, the second coil spring 92 is in the elastically contracted state and presses the slide moving body 8 forward.

A supporting body 40 constituted by a known bearing member is provided in the cover body 2. The supporting body 40 is in contact with the side surface portion of the slide moving body 8 to move the slide moving body 8 So that the slide moving body 8 is prevented from swinging.

In the above configuration, when the air hammer tool 1B is used, the trigger 4a is operated to continuously pressurize the compressed air into the compressed air inflow chamber 7. Then, the slide moving body 8 is supported by the support body 40 by the pressure elevated in the compressed air inflow chamber 7, so that the slide moving body 8 is extruded forward. When the slide moving body 8 is pushed forward, the first coil spring 91 is elastically compressed to press the slide moving body 8 backward, and the second coil spring 92 is elastically compressed The slide moving body 8 is pressed forward. In this state, the hammer 30 in the cylinder 11 reciprocates and collides repeatedly with the distal end 20, so that the impact force continues to be applied to the striking object through the distal end 20.

With this configuration, the vibration absorbing effect and the noise suppressing effect can be obtained by the first coil spring 91 on the front side. In addition, the second coil spring 92 at the rear serves to supplement the pressure of the compressed air, thereby pressing the slide moving body 8 forward to stabilize the striking force.

For reference, the striking force measured by the prototype corresponding to the second embodiment was improved by about 20 to 30% as compared with the striking force of the prototype corresponding to the first embodiment having no second coil spring 92. The measurement of the striking force was carried out by using a measuring device which numerically quantizes the kinetic energy transmitted from the distal end ball 20 based on the acceleration.

By appropriately setting the spring constant of the second coil spring 92 described above, it is possible to adjust the hitting force applied to the hitting target while maintaining the optimum vibration absorbing effect and the noise suppressing effect.

For example, in order to increase the striking force, the spring constant of the second coil spring 92 is changed to strengthen the forward pressing force with respect to the slide moving body 8. In this way, the slide moving body 8 can be appropriately pressed forward so that the tip opening 20 can be appropriately pressed against the striking object, and also in the inner space 2a of the slide moving body 8 So that the striking force is increased. On the other hand, when the hitting force is to be reduced, the spring constant of the second coil spring 92 is changed to weaken the forward pressing force on the slide moving body 8. Then, based on the opposite principle described above, the hitting force is reduced.

[Example 3]

In addition to the above configuration, another type of air hammer tool 1C is proposed. The description of the points common to the first and second embodiments is omitted or omitted, and the same reference numerals are given to the same points in the drawings.

As shown in Fig. 8, an air control body 50 is disposed at the rear of the cover body 2. As shown in Fig. The air control body (50) includes an air control body (51). In the interior of the air control body 51, a gas flow path 55 in the front-rear direction is formed in a through-hole shape.

On the outer surface of the air control body 51, an air control switch portion 52 is provided. The air control switch unit 52 includes an operation unit 52A and an operation unit 52B. The operating portion 52A is constituted by an elongated plate member, and its base end portion is supported on the side wall of the air control body 51. [ The operating portion 52B is composed of a rod member protruding outwardly from the inside of the air control body 51 and has its tip abutted against the back surface of the operating portion 52A. When the operating portion 52A is operated, the operating portion 52B moves up and down along the axial direction. An opening / closing valve 54 incorporated in the air control body 51 is connected to the operating portion 52B. When the operating portion 52A is operated, the opening / closing valve 54 operates in conjunction with the operating portion 52B to open / close the gas flow path 55 properly. The mechanism of the on-off valve 54 may be a well-known technique. For example, a well-known mechanism disclosed in Japanese Utility Model Registration No. 3153805 can be applied to the air hammer tool 1C.

The pressurizing portion 6a of the base body of the cover body 2 and the gas flow channel (not shown) in the air control body 50 are provided between the air control body 50 and the cover body 2, 55 are communicated in an airtight manner.

A cylindrical front gripper 74 is fitted on the outer periphery of the cover body 2 through an O-ring 75 or 75 serving as an elastic member from the outside. In this state, the O-rings 75 and 75 are sandwiched between the cover member 2 and the front grasp body 74 and are in close contact with each other.

Further, coil springs 78a and 78b as elastic members are provided on the front and rear sides of the front grasping member 74, respectively. More specifically, a flange-like spring fixing portion 76a is provided around the front end of the cover member 2, and the spring fixing portion 76a and the front end surface of the front gripper member 74 A coil spring 78a is disposed so as to cover the cover body 2 between the first and second plates. On the other hand, a flange-shaped spring fixing portion 76b is provided around the rear end of the cover member 2, and between the spring fixing portion 76b and the rear end surface of the front gripper member 74 A coil spring 78b is disposed so as to cover the cover body 2. [ The O-ring 75 has a vibration absorbing function for preventing upward, downward, and leftward and rightward vibration generated in the cover body 2 from being easily transmitted to the front grasper 74. The coil springs 78a and 78b have a vibration absorbing function that prevents the forward and backward vibrations generated in the cover body 2 from being transmitted to the front grasp body 74 easily.

Further, a rear gripper 84 is attached to the rear portion of the air control body 50 described above. The rear gripper 84 is formed of a cylindrical member having a bottom. The rear gripper body 84 is fitted to the air control body 50 from the outside through O-rings 85, 85 as elastic members. Further, coil springs 94 and 94 as elastic members are provided between the rear end surface of the air control body 50 and the bottom portion of the rear gripper body 84, that is, the rear end portion. The O-ring 85 has a vibration absorbing function for preventing upward, downward, left and right vibrations transmitted to the air control body 50 from being easily transmitted to the rear gripper 84. The coil spring 94 has a vibration absorbing function that prevents the forward and backward vibration transmitted to the air control member 50 from being easily transmitted to the rear gripper 84. [

A large-diameter extension portion 58 is provided at the rear end of the air control body 51. At the same time, a ring-shaped stopper portion 86 is fixed to the front end of the rear gripper 84 by bolts 88. In this configuration, even if the rear gripper body 84 falls off the air control body 51 from the rear, the stopper portion 86 and the extension portion 58 are engaged with each other, .

Further, a compressed air introduction portion 96 is provided on the rear end surface of the rear gripper 84. [ The compressed air introduced from the outside through the compressed air inlet portion 96 passes through the air passage 89 in the rear gripper 84 and is guided to the gas passage 55 in the air controller 50 do.

When the air control switch unit 52 of the air control unit 50 is switched, the compressed air is first supplied from the outside through the compressed air inlet unit 96 to the air control unit 50 And then is guided into the cover body 2 through the press-fitting portion 6a of the base body of the cover body 2. Then, Thereby, the hammer 30 rocks back and forth.

Since the front grasping member 74 is provided around the cover member 2 and the rear grasping member 84 is provided near the air control switch unit 52, It is possible to work by holding the holding body 74 and grasping the rear holding body 84 with the other hand. With this configuration, vibration is not easily transmitted to the hands that support the entire air hammer tool 1C, even in the hands that operate the air control switch portion 52, and thus the vibration absorbing performance is extremely excellent.

In addition, in the present invention, the cover member 2 and the distal end opening 20 may be made of different materials. For example, the grip portion 3a of the first embodiment is made of an elastic material such as rubber, do. Further, the material of the hammer 30 may be appropriately selected from known materials, and it may be composed of a core material and an outer shell covering the core material. Further, the hammer 30 may be appropriately subjected to surface treatment. Further, the hammer 30 may be formed by connecting a plurality of block bodies, and the hitting force or the weight composition of the hammer 30 may be adjusted according to the number of the block bodies. Further, an elastic body made of a fiber material may be filled in a necessary portion. As the fiber material, a felt (needle punch nonwoven fabric) made of polyester fiber or the like can be employed. Further, the fiber material may be impregnated with oil to improve the durability of the fiber material. Further, the distal end opening (20) may be formed by, for example, a jackhammer, a concrete breaker, If the chipping machine is a chisel, a jigger, a riveter or a file driver, it may be a nail, a rivet or a pile, a surface stopper, a compactor, a rammer or a tamper, . The gas to be press-fitted into the air hammer tools 1A to 1C is not limited to compressed air, and may be a gas such as an inert gas.

1A ~ 1C: Air hammer tool
2: Cover body
2a: Inner space part
8: Slide carriage
8a: front opening
9, 91, 92: coil spring (elastic body)
20: Flier
20c: rear end portion of the leading end
30: Hammer
50: air control element
52: Air control switch section
74: front gripper (gripper)
84: rear gripper (gripper)
75, 85O: ring (elastic member)
78a, 78b, 94: coil springs (elastic members)

Claims (5)

A cover body, and a tip end protruding forward from the cover body,
An air hammer tool for applying a striking force obtained by a gas press-fitted into the cover body to the striking object through the distal end opening,
The cover body
And a gas press-fitting portion for pressing the gas forward is formed in the peripheral wall of the cover body, and the inner space portion is provided with a slide moving body An elastic body provided between the outer peripheral surface of the slide moving body and the inner peripheral surface of the cover body is loaded,
A compressed air inflow chamber in which airtightness is enhanced is formed between the rear end surface of the slide moving body and the inner circumferential surface of the cover body opposite to the rear end surface in the inner space portion,
Wherein the slide moving body has a slide moving body body and a cylindrical cylinder portion provided on a front end portion of the slide moving body body portion and projecting forward from the cover body,
And a gas inlet portion for guiding the gas injected into the cover body into the cylinder portion is formed in the peripheral wall of the slide moving body body portion and the hammer is mounted so as to be slidable back and forth in the cylinder portion, A rear end portion of the distal end opening is fixed to the front end opening so as to collide with the hammer,
When the gas is press-fitted into the cover body through the gas press-fitting portion, the gas is introduced into the compressed air inflow chamber, and the slide moving body advances while elastically deforming the elastic body in the cover body by the pressure of the gas And the hammer repeatedly collides with the rear end of the distal end ball by reciprocating the hammer back and forth in the cylinder part by the gas introduced through the gas introduction part into the cylinder part,
The elastic body is a coil spring,
Wherein the coil spring is interposed between a front end surface of the slide moving body main body and an inner circumferential surface of the cover body so as to be oriented in the longitudinal direction,
Wherein when the gas is press-fitted into the cover body through the gas press-in portion and the slide moving body advances, the coil spring elastically presses the slide moving body backward,
A coil spring is arranged as an elastic body between the rear end surface of the slide moving body and the inner circumferential surface of the cover body and is opened in a forward and backward direction and also in a state of being elastically contracted,
Wherein the coil spring is configured to press the slide moving body forward while the slide moving body is advanced forward by pressurizing the gas through the gas press-
Air hammer tool. The method according to claim 1,
An air control body to which a gas is supplied from the outside is disposed at a rear side of the cover body, and a gas supplied from the outside by a switch operation of an air control switch section provided in the air control body is supplied to the gas press- As shown in Fig.
Wherein a cylindrical gripper is fitted to the outer periphery of the cover body and / or the outer periphery of the air control body through an elastic member from the outside along the front-rear direction. A method of adjusting a hitting force of an air hammer tool according to claim 1 or 2,
Wherein a coil spring that is opened between a front end surface of a body portion of the slide moving body and an inner circumferential surface of the cover body is a first coil spring,
A coil spring interposed between a rear end surface of the slide moving member and an inner circumferential surface of the cover member is a second coil spring,
And the hitting force is adjusted by changing a pressing force of the second coil spring with respect to the slide moving body,
A method of adjusting the impact force of an air hammer tool.
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