KR102424003B1 - vacuum hammer - Google Patents

Abstract

The vacuum hammer according to the present invention includes a cylinder unit having a cylinder in which a piston is reciprocally installed by a hydraulic pressure supply unit, and a blow that is slidably installed in a housing provided under the cylinder unit and is struck by the piston of the cylinder. member, a vacuum chamber installed in the housing and maintaining a vacuum state in order to accelerate the descending speed of the piston and reduce noise when the striking member is struck by the piston, and the vacuum chamber is connected to the vacuum chamber to apply vacuum pressure A piston acceleration and striking noise reduction unit including a vacuum generating unit for maintaining, and installed between the housing in which the vacuum chamber is installed and the cylinder to cool the piston striking the striking member, and hydraulic oil from the cylinder in the vacuum chamber A cooling unit is provided to prevent leakage by vacuum pressure.

Description

vacuum hammer

The present invention relates to a vacuum hammer, and more particularly, to a vacuum hammer capable of increasing the striking force of a striking member by using vacuum pressure.

In general, a hammer or hydraulic breaker is installed in construction equipment such as excavators and loaders and is widely used to construct piles or to crush concrete and rock.

The hammer or hydraulic breaker drives a pile or crushes concrete, rock, etc. by striking force by striking a chisel, which is a pile or a crushing tool for construction, using a piston of a cylinder.

Meanwhile, noise regulations at construction sites have been strengthened, making it compulsory to indicate the noise level of construction machinery. Excavators, dozers, loaders, breakers, etc.

In addition, if an area within a certain distance from a residential area, apartment building, school, hospital, public library, etc. is designated as a calm zone and a specific construction with a high noise level is carried out in the calm zone according to the Ordinance of the Ministry of Environment, soundproofing facilities must be installed before the start of construction. .

As described above, in order to avoid noise regulation, low-noise type breaker with reduced noise by improving hydraulic breaker is being developed.

Korean Patent Registration No. 2009413 discloses a low-noise breaker, and Korean Patent No. 1230361 discloses a low-noise breaker having a guide for noise reduction.

And the Republic of Korea Patent Registration No. 10-1775328 discloses a breaker equipped with a vacuum atmosphere striking space.

The posted breaker includes a cylinder in which a piston is provided reciprocally by a separate drive pump; a housing provided at a lower portion of the cylinder, penetrating along the vertical direction and having a striking space formed therein; a striking unit provided in the housing to seal the striking space from the lower part, and to receive the stroke of the piston and the lower end to strike the striking object; and a vacuum unit communicating with the striking space and controlling the inside of the striking space to a vacuum atmosphere to reduce noise when the piston is struck.

The vacuum breaker as described above has a structure to reduce noise by controlling the vacuum atmosphere inside the striking space, but it is difficult to expect a noise reduction effect because it is formed in the shape of a cylinder.

In particular, since the seal part of the piston operated by hydraulic pressure is exposed to a vacuum atmosphere, there is a problem in that the lubricating oil flows out into the striking space. And the striking space is a space to attenuate the noise, and does not significantly affect the increase in the striking force of the piston.

On the other hand, Korean Patent Registration No. 10-1219299 discloses a driving machine, and Korean Patent Publication No. 2009-051629 discloses a driving machine including an active noise control device.

Korean Patent Registration No. 2009413 Korean Patent No. 1230361 Korean US Patent Registration No. 10-1775328

The present invention is a vacuum hammer that can solve the above problems, can significantly improve the striking force of the striking object by the piston, and can prevent the lubricating oil from leaking by exposing the piston to a chamber that is a vacuum space with a sealing part Its purpose is to provide

Another object of the present invention is to provide a vacuum hammer capable of preventing overheating of the piston and its striking portion by further providing a cooling unit capable of cooling the piston between the vacuum space and the cylinder of the piston.

In order to achieve the above object, the vacuum hammer of the present invention is

A cylinder unit having a cylinder in which a piston is reciprocally installed by a hydraulic pressure supply unit;

a striking member that is slidably installed in a housing provided under the cylinder unit and is struck by the piston of the cylinder;

A vacuum chamber installed in the housing to maintain a vacuum state in order to accelerate the descending speed of the piston and reduce noise when the striking member is struck by the piston, and to maintain a vacuum pressure in the vacuum chamber connected to the vacuum chamber A piston acceleration and hitting noise reduction unit including a vacuum generating unit,

A cooling unit is installed between the cylinder and the housing in which the vacuum chamber is installed, is lifted by the cylinder, cools the piston hitting the striking member, and prevents hydraulic oil from flowing out from the cylinder by the vacuum pressure in the vacuum chamber. characterized by one.

In the present invention, the vacuum chamber of the piston acceleration and striking noise reduction unit is separated into a first vacuum chamber installed around the striking member and the striking portion of the piston, and an auxiliary chamber connected to the first vacuum chamber and the connecting portion. .

The cooling unit is exposed so that the vacuum pressure inside the first vacuum chamber formed in the housing between the cylinder and the housing does not act on the piston and the sliding part of the cylinder, so that the piston is air-cooled. And the connecting portion connecting the first vacuum chamber and the auxiliary chamber is provided with a perforated plate formed with a plurality of through-holes.

Alternatively, the vacuum hammer of the present invention for achieving the above object includes a cylinder unit having a cylinder in which a piston is reciprocally installed by a hydraulic pressure supply unit, and is slidably installed in a housing at the upper and lower portions of the cylinder unit and is formed by the cylinder. The first and second striking members to be struck, and

It is installed in the housing between the lower portion of the piston and the striking portion of the first striking member and the upper portion of the piston and the striking portion of the second striking member to accelerate the lifting speed of the piston when the first and second striking members are struck by the piston. The first and second vacuum chambers to reduce noise and the first and second vacuum chambers are connected to the first and second vacuum chambers and are respectively connected by first and second connecting parts to reduce noise; 1, 2 and a piston acceleration and hitting noise reduction unit including a vacuum generating unit for providing vacuum pressure to the vacuum chamber and the auxiliary chamber;

It is installed between the housing and the cylinder in which the vacuum chamber is installed, is lifted up and down by the cylinder, cools the piston hitting the first and second striking members, and the first, It is characterized in that the hydraulic oil in the second vacuum chamber is prevented from flowing out.

The vacuum hammer according to the present invention can improve the striking force by increasing the acceleration force of the piston when the striking member is struck by the piston of the cylinder unit, and can reduce the noise generated during the striking. In particular, since the noise generated when the piston strikes the striking member during operation of the vacuum hammer can be reduced, construction in the city center is possible.

1 is a cross-sectional view of a vacuum hammer according to the present invention;
2 is a cross-sectional view showing another embodiment of a vacuum hammer according to the present invention;

An embodiment of a vacuum hammer capable of reducing noise and improving striking force according to the present invention is shown in FIGS. 1 to 2 .

Referring to the drawings, the vacuum hammer 10 in the present invention includes a cylinder unit 20 having a cylinder 22 in which a piston 21 is reciprocally installed by a hydraulic pressure supply unit, and a lower portion of the cylinder unit 20 . It is slidably installed in the housing (40) provided in the cylinder (22) is provided with a striking member (30) hit. And the housing 40 is provided with a piston acceleration and hitting noise reduction unit 50 for accelerating the descending speed of the piston 21 using vacuum pressure and reducing noise. And between the cylinder 22 and the housing 40 is lifted by vacuum pressure and cools the piston 21 hitting the striking member 30, and hydraulic oil flows out from the cylinder by the vacuum pressure in the vacuum chamber. It is provided with a cooling unit (70) to prevent the.

The vacuum hammer according to the present invention configured as described above will be described in detail for each component as follows.

The cylinder unit 20 is provided with a relatively long cylinder 22, the piston 21 is slidably installed in the cylinder 22 to be lifted. The cylinder unit 20 is configured to selectively move up and down by a hydraulic drive unit (not shown).

The hydraulic drive unit may include a drive pump for pumping hydraulic oil for operating the cylinder 22 and a control valve or a pulse generator for controlling the piston 21 to be lifted with respect to the cylinder 22 .

On the other hand, the housing 40 is provided under the cylinder 22, the hitting member 30 to be described later is slidably installed. The housing 40 is formed so as to penetrate up and down in the lower part of the cylinder unit 20 so that when the piston 21 is lowered, a part of the housing 40 is introduced to the inside to hit the striking member 30 . The cylinder and the housing have a structure in which they are coupled by a separate coupling unit or supported in a spaced state.

The striking member 30 installed in the housing 40 may be formed of a chisel having a sharp end so as to crush rocks, ground, concrete, and the like. The striking member 30 is provided with a step part 31 having a relatively small diameter on the upper side, and the inner diameter reduction part 41 corresponding to the step part 31 is installed in the housing 40, so that the piston ( 21), it is possible to prevent the striking member 30 from rising to the upper side of the housing by the repulsive force. And although not shown in the drawings, a means for preventing the striking member 30 from being separated from the housing 40 is further provided.

And the piston acceleration and hitting noise reduction unit 50 is for accelerating the descending speed of the piston 21 and reducing the noise by using vacuum pressure, and the piston ( 21) and the vacuum chamber 51 is formed around the striking portion of the striking member 30 installed in the housing 20. A vacuum generating unit 62 connected to a pneumatic tube 61 for providing vacuum pressure to the vacuum chamber 51 is installed in the housing 40 .

The vacuum chamber portion 51 constituting the piston acceleration and impact noise reduction unit 50 includes a first vacuum chamber 52 installed around the striking portion of the striking member 30 and the piston 21, and the first vacuum It consists of the chamber 52 and the auxiliary chamber 53 connected by the connection part (55).

It may be formed inside the housing 40 of the first vacuum chamber 52 , and is formed in the longitudinal direction around the striking portion of the piston 21 and the striking member 30 . The length of the first vacuum chamber 52 is such that the end of the piston 21, that is, the striking portion, should not be separated from the first vacuum chamber 52 when the piston 21 is raised and lowered, and the striking member 30 In addition, it is formed so as not to deviate from the area of the first vacuum chamber 52 when ascending and descending along the housing 40 . In addition, a first sealing part 56 is installed on the outer circumferential surface of the piston 21 and the housing 40 corresponding thereto so that the vacuum pressure inside the first vacuum chamber 52 does not leak out, and the striking member 30 ) and the second sealing portion 57 is formed on the housing 40 corresponding thereto.

In addition, the auxiliary chamber 53 connected by the connection part 55 is a space in which vacuum pressure is applied, and may be formed in the housing 40 or as a separate auxiliary tank. The auxiliary chamber 53 is preferably formed to be relatively larger than the first vacuum chamber 52 . And a noise reduction member (not shown) capable of reducing noise caused by the impact of the striking member 30 and the piston 21 is further provided inside the auxiliary chamber 53 and inside the first vacuum chamber 52 . can be The noise reduction member may be made of a perforated plate installed inside the first vacuum chamber 52 and the auxiliary chamber 53 or a sound absorbing material installed on the inner circumferential surface of the chamber.

The connection part 55 includes a perforated plate 55a having a plurality of through holes to reduce noise generated by the impact force of the piston 21 and the striking member 30 .

The vacuum generating unit 60 connected by the auxiliary chamber 53 and the supply pipe 61 may be formed of a vacuum pump. According to the vacuum pressure inside the first vacuum chamber 52 and the auxiliary chamber 53, it is possible to increase the descending speed when the piston 21 is descending, so that the vacuum pump can maintain the descending speed of the piston at a speed of 10 m/sec. It is preferable to use a pump capable of providing vacuum pressure.

On the other hand, the cooling unit 70 is installed between the cylinder 22 and the housing 40 to cool the piston, and the vacuum pressure inside the first vacuum chamber formed in the housing 40 is the piston 21 and the It has a structure so as not to act on the sliding part of the cylinder (22). The cooling unit 70 is spaced a predetermined distance between the cylinder 22 and the housing 40 so that the vacuum pressure in the first vacuum chamber 52 does not act toward the cylinder unit 20, the cylinder 22 and the housing. A part of the piston 21 sliding on the 40 has a structure in which it is exposed.

However, the present invention is not limited thereto, and a ring-shaped cooling member 71 having a plurality of through-holes radially formed between the cylinder 22 and the housing 40 may be installed. The cooling member may be made of metal, and has a structure in which the piston 21 between the cylinder 22 and the housing 40 is exposed to the atmosphere through the through holes.

In addition, an orifice member 150 connecting the outside and the inside of the vacuum chamber is installed in the housing 40 in order to discharge the thermal energy of the vacuum pressure of the first vacuum chamber 52 to the outside. The orifice member 150 discharges heat energy generated when the piston 21 is struck after it rises to the outside. Also, the vacuum pressure is temporarily reduced.

Meanwhile, FIG. 2 shows another embodiment of the vacuum hammer according to the present invention. The same reference numerals as in the above embodiment designate the same components.

Referring to the drawings, in the vacuum hammer according to the present invention, the first and second housing parts 110 and 120 are installed on the lower part of the cylinder unit 20 including the piston 21 in addition to the cylinder 22, and now The first and second striking members 35 and 36 each hit by the upper and lower sides of the piston 21 of the cylinder unit 20 are installed in the first and second housing parts 110 and 120 , respectively. The first and second housing parts 110 and 120 may be formed of a single body, and may have a structure coupled to the cylinder unit 20, respectively.

And first and second vacuum chambers 52 and 121 are formed in the first and second housing parts 110 and 120, respectively, and the first and second vacuum chambers 52 and 121 are auxiliary chambers 53 ) and the connection part 55, respectively. A cooling unit 70 is installed between the cylinder 22 of the cylinder unit 20 and the first and second housing parts 110 and 120 . When connected to the first vacuum chamber 52 of the auxiliary chamber 53 and not connected to the second vacuum chamber 121, the first and second vacuum chambers 52 and 121 are connected to the piston 21. A connection passage (not shown) that can communicate with each other may be formed.

Since the cooling unit 70 and the connection part 55 have the same structure as the above-described embodiment, they will not be described again.

And in the above embodiment, the striking members 30 and 35 installed in the first and second housing portions 120 are fixed to the first and second housing portions 120, respectively, and the first and second housing portions By integrally forming (110) and (120), a hammer for drawing or driving a file can be implemented, and in this case, a clamp for gripping the file can be installed on one side of the housing. In addition, the housing may be provided with a refurbished blade capable of excavating or crushing an arm.

The vacuum hammer according to the present invention configured as described above operates the cylinder unit 20 in the hydraulic drive unit to raise the piston 21, and then strikes the striking member 30, which is the striking object, to arm, concrete, and soft ground. It is constructed by crushing the back or hitting a pile.

In this process, since a relatively high vacuum is maintained in the first vacuum chamber 52 and the auxiliary chamber 53 by the vacuum generating unit 62, the piston 21 descending for striking is accelerated by the vacuum pressure. to hit the striking member 30 .

Therefore, since the descending speed of the piston 21 moving by the operation of the existing cylinder unit 20 can be doubled, the striking force of the striking member 30 can be doubled. Therefore, it is possible to improve the construction of the pile or the crushing ability of the arm by the crushing member 30 .

On the other hand, when the striking member 30 is struck by the piston 21, a striking sound is generated, and the striking sound is prevented from spreading because the striking portion is surrounded by the first vacuum chamber 52 . In particular, since the first vacuum chamber 52 is connected by the connection part 55 including the perforated plate 55a, noise is reduced while passing through the perforated plate 55a, and disappears in the second auxiliary chamber 53. or become smaller

As described above, the vacuum hammer of the present invention can maximize the striking force by the vacuum pressure and can reduce the striking sound caused by the piston, thereby preventing civil complaints due to noise during operation as in the prior art.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

Claims (7)

A cylinder unit having a cylinder in which a piston is reciprocally installed by a hydraulic pressure supply unit;
a striking member that is slidably installed in a housing provided under the cylinder unit and is struck by the piston of the cylinder;
A vacuum chamber that is installed in the housing and maintains a vacuum state in order to accelerate the descending speed of the piston and reduce noise when the striking member is struck by the piston, and is connected to the vacuum chamber to maintain a vacuum pressure in the vacuum chamber A piston acceleration and hitting noise reduction unit including a vacuum generating unit, and
A cooling unit is installed between the cylinder and the housing in which the vacuum chamber is installed, is lifted by the cylinder, cools the piston hitting the striking member, and prevents hydraulic oil from flowing out from the cylinder by the vacuum pressure in the vacuum chamber. and
The vacuum chamber of the piston acceleration and striking noise reduction unit is a vacuum hammer, characterized in that it is separated into a first vacuum chamber installed around the striking member and the striking portion of the piston, and an auxiliary chamber connected to the first vacuum chamber and the connecting portion. . delete The method of claim 1,
The cooling unit is exposed so that the vacuum pressure inside the first vacuum chamber formed in the housing between the cylinder and the housing does not act on the sliding part of the piston and the cylinder, and the piston is air-cooled. The method of claim 1,
A vacuum hammer, characterized in that the connection portion connecting the first vacuum chamber and the auxiliary chamber is provided with a perforated plate having a plurality of through-holes formed therein. The method of claim 1,
The vacuum hammer, characterized in that the housing is provided with an orifice member that connects the first vacuum chamber and the outside to discharge heat energy generated when the piston is struck to the outside. A cylinder unit having a cylinder in which a piston is reciprocally installed by a hydraulic pressure supply unit;
The first and second striking members are slidably installed in the first and second housings installed at the upper and lower portions of the cylinder unit and are struck by the piston of the cylinder;
The piston is installed between the lower portion of the piston and the striking portion of the first striking member and the upper portion of the piston and the striking portion of the second striking member in the first and second housings when the first and second striking members are struck by the piston. first and second vacuum chambers for accelerating the lift speed and reducing noise, and an auxiliary chamber for reducing noise by being respectively connected to the first and second vacuum chambers and the first and second connecting parts, the auxiliary chamber and A piston acceleration and hitting noise reduction unit including a vacuum generating unit connected to provide vacuum pressure to the first and second vacuum chambers and the auxiliary chamber;
A vacuum hammer comprising a cooling unit installed between the cylinder of the cylinder unit and the first and second housings.


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