JPH07109083B2 - Boom actuating destruction device and method of destroying composite - Google Patents

Description

TECHNICAL FIELD The present invention relates to a method and apparatus for breaking a composite material such as cement into a plurality of pieces.

Background Art Many types of equipment have been devised to destroy surfaces such as concrete or asphalt pavement. Such a device can be called a destruction device.

Known destruction devices are U.S. Pat. Nos. 3,319,724 and 3,3.
No. 58,779. These destructive devices are mounted on the boom of a sediment transport machine to support the device. A separate motor is required to operate these known devices.

An object of the present invention is to provide a demolition device suitable for being attached to a boom of a earth and sand moving machine, which can operate the demolition device by moving the boom without using an independent motor for operating the demolition device. Is to provide.

Another object of the present invention is to provide a destructive device capable of exerting a greater force compared to the physical size and weight of the device.

Another object of the present invention is to provide a breaking device which can be easily attached to and detached from a boom of a soil moving machine.

Another object of the invention is to provide a destruction device that can be operated at any angle, for example vertical operation for the destruction of pavement and horizontal operation for the destruction of walls and the like.

Another object of the present invention is to provide a destructive device that is relatively inexpensive to manufacture and has a long service life.

Other objects and advantages of the invention reside in the construction of the parts, the combination of the parts, the method of operation and the method of use, as will be more apparent from the following description.

SUMMARY OF THE INVENTION The breaking device of the present invention is suitable for mounting on the boom or boom arm of a suitable machine, such as a earthmoving machine. The destroyer is operable by movement of the boom of the machine and does not require a separate motor means for operating the destroyer.

The destruction device has a housing mounted on the boom of the machine. An axially movable power plunger extends from the housing. The power spring biases the power plunger in one direction from the housing. An axially movable actuator plunger extends from the housing. A latch member is pivotally attached to the actuator plunger and maintains a position of the power plunger relative to the actuator plunger by engaging a portion of the power plunger.

In operation, the housing is moved towards the pavement or wall, etc. to be destroyed. As the housing is moved in the pavement direction, the actuator plunger becomes engaged with the surface to be destroyed. However, the power plunger is spaced from the surface to be destroyed. The actuator plunger continues to engage the pavement and the latch attached to the actuator plunger continues to engage the power plunger to maintain the position of the power plunger relative to the pavement surface as the housing continues to move toward the pavement surface. To do. Thus, as the housing is subsequently moved towards the pavement surface, the actuator plunger and power plunger will be oriented upwards within the housing. Such relative movement between the power plunger and the housing opposes the force of the power spring.

Movement of the housing toward the pavement surface continues until the abutment member engages a latch mounted on the actuator plunger. When the latch engages the abutment member, the latch is actuated and released from engagement with the power plunger. When this happens, the power spring momentarily and abruptly moves the power plunger into crash engagement with the pavement. The power plunger impacts the pavement with the energy of the power spring.

According to another aspect of the invention, a holding pressure is generally applied on the first surface of the composite material towards the second surface of the composite material. The holding pressure is increased and a tensile force is generated within the first thickness and along the surface of the slab of material to be destroyed. This increased holding pressure is maintained on the material surface while the first surface is generally impacted towards the second surface away from the holding pressure location.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view of a boom and a boom arm of a sediment moving machine, showing a bucket attached to the boom arm which is moved and operated as the boom and the boom arm are moved.

FIG. 2 is a side view showing a breaking device attached to the boom arm instead of the bucket. The destroyer is shown supported by the boom arm at a location remote from the pavement to be destroyed. In this figure, the pavement is shown in cross section.

FIG. 3 is a side view showing the boom and boom arm of FIGS. 1 and 2. This figure shows the actuator plunger of the destroyer engaging the pavement surface.

FIG. 4 is a side view showing a part of the boom arm of the machine, showing the positions of the power plunger and the actuator plunger at the moment when the breaking device is attached to the boom arm and the power plunger is released due to the impact action. .

FIG. 5 is a side view similar to FIG. 4, but showing the downward impact of the power plunger.

FIG. 6 is a cutaway sectional view showing the breaking action formed by the continuous action of the power plunger of the breaking device.

FIG. 7 is an enlarged side view showing the position of each plunger of the breaking device shown in FIGS. 2 and 3 when the breaking device is moved in the surface direction or downward direction for the breaking operation. .

FIG. 8 is an enlarged side view similar to FIG. 7, but showing the position of each plunger while the housing is moved further down and the actuator plunger engages the surface to be destroyed.

FIG. 9 is a cutaway sectional view drawn on the same scale as FIGS. 7 and 8, showing the elements of the breaking device at the moment when the power plunger is released to break the surface due to the downward impact movement and The position of a member is shown.

FIG. 10 is a sectional view similar to FIGS. 7 and 8, showing the impact action after the power plunger is released.

BEST MODE FOR CARRYING OUT THE INVENTION FIGS. 1, 2 and 3 show a part of a machine operation unit 20 such as a tractor or a transportation vehicle, which is shown herein as a earth and sand moving machine. There is.

A boom 22 is rotatably attached to the operation unit 20. A boom arm or a power arm 26 is rotatably attached to the boom 22 by a connecting unit 24.

A connecting unit 30 is fixed to the middle portion of the boom 22. A direct acting hydraulic motor 34 is rotatably attached to the operation unit 20 and the coupling unit 30. Direct acting hydraulic motor
36 is rotatably attached to the connecting unit 30 and has an extending piston rod 38. Piston rod
38 is rotatably attached to the connecting unit 24.

A direct-acting hydraulic motor 40 is rotatably attached to the connecting unit 24 and has an extending piston rod 44.
The lever 46 is rotatably attached to the end of the piston rod 44. The lever 46 is also pivotally attached to the arm 26 near the end of the arm.

As shown in FIG. 1, a bucket 50 is rotatably attached near the end of the boom arm 26, and the bucket 50 is moved and operated by the operation unit 20. The bucket 50 is also rotatably attached to the link 52. Ring 52 is also pivotally attached to lever 46. The hydraulic motors 34, 36, 40 are operated by control means (not shown) carried by the operation unit 20. Therefore, the boom 22, the boom arm 26, and the bucket 50 are moved by the operation of the operation unit 20.

When it is desired to attach the breaking device 60 of the present invention to the boom arm 26, the bucket 50 is removed from the arm 26 and the link 52. The breaking device 60 of the present invention includes a boom arm 26 and a link.
Bracket rotatably attached to the end of 52
It includes a housing 64 with 62.

A power plunger 68 having an end 69 in the housing 64
Is provided. Power plunger 68 is housing 64
It is attached by extending between both ends. The power plunger 68 is axially movable with respect to the housing 64.

As shown in FIGS. 7, 8 and 10, a cushion 70 is provided at the lower end of the housing 64.
The power plunger 68 extends through the cushion 70. A collar 72 surrounds the power plunger 68 and is secured to the power plunger. Preferably coil spring
An elastic member or biasing member in the form of 76 is provided between the collar 72 and the upper end of the housing 64 to bias the power plunger 68 longitudinally with respect to the housing 64, i.e., toward the end 69. And is provided around the power plunger 68 compressed between.

Further, an actuator plunger 80 having an end 81 is provided in the housing 64. The actuator plunger 80 extends from both ends of the housing 64 and
It extends through 70. Actuator plunger 80
Is axially movable with respect to the housing 64 between a first position shown in FIG. 7 and a second position shown in FIGS. 8 and 9. A base 82 is fixed to the middle portion of the actuator plunger 80. A lug 84 is fixed to the base 82. A latch 86 is pivotally attached to the lug 84 and the actuator plunger 80. The latch 86 has an engagement portion 86e located near the power plunger 68. A control spring 89 is compressed between the base 82 and the latch 86 and biases the latch 86 in a counterclockwise pivoting motion as viewed in FIGS. 7-10. Rug
84 is provided with a stopper portion 84e for limiting the counterclockwise rotational movement of the latch 86 to the position shown in FIGS. 7 and 8. An abutment member 90 engageable by a latch 86 is fixed in the housing 64 near the actuator plunger 80.

For the sake of clarity of explanation, the power plunger 68 is arranged in the longitudinal direction with respect to the housing 64, that is, the power plunger 68.
Note that the spring means 77 biasing towards said end 69 of said includes a spring 76 and a collar 72. Further, the spring means 77 is responsive to movement of the actuator plunger 80 from the first position to the second position.
The spring means in response to the power plunger 68 moving toward the housing 64 over a predetermined distance (D) by compressing
The means 83 for releasing 77 includes a base 82, a lug 84, a latch 86,
It includes a latch engagement portion 86e, a coil spring 89, a lug stopper portion 84e, and an abutment member 90. Latch 8
The trigger mechanism composed of 6, the collar 72, and the contact member 90 can adopt other configurations without departing from the scope of the present invention.

INDUSTRIAL APPLICABILITY As described above, the breaking device 60 according to the present invention has the boom arm 26.
It can be easily replaced with the bucket 50 attached to the. A bracket 62 of the housing 64 is rotatably attached to the end of the boom arm 26 and the link 52. Therefore, when the boom 22 and the boom arm 26 are moved, the destruction device is moved.

In the destruction process using the destruction device 60, the boom
22 and the boom arm 26 are operated to move the breaking device 60 toward the surface to be broken, as shown in FIG. Actuator plunger 80 and power plunger
68 is normally located in the maximum extension position as shown in FIGS. 2, 3 and 7. In this position, the power plunger 68 is spaced apart from the actuator plunger 80 in the upward direction. As the boom 22 and arm 26 move the disruption device 60 downwardly toward the pavement 96, the actuator plunger 80 will engage the pavement 96 as shown in FIG.

Latch attached to actuator plunger 80
The engagement portion 86e of 86 engages the collar 72 secured to the power plunger 68. Therefore, the boom 22 and the arm 26
When the breaking device 60 is continuously moved downward, the housing 64 is lowered, but the actuator plunger 80 and the power plunger 68 are not moved. Therefore, the plunger 8
Relative motion occurs between the 0, 68 and the housing 64. This downward movement of the housing 64 opposes the compressive force of the spring 76 surrounding the power plunger 68 and engaging the collar 72 and the housing 64. This downward movement of the housing 64 continues until the abutment member 90 in the housing 64 engages the latch 86 carried by the actuator plunger 80 as shown in FIG. This is the position where the power plunger 68 has moved in the direction of the housing 64 with respect to the housing by a predetermined distance "D" or more. When this engagement occurs, the latch 86 is rotated against the force of the control spring 89 and released from the collar 72 secured to the power plunger 68, as shown in FIG. When the latch 86 releases the collar 72, the power spring 76 immediately causes the power plunger 68 to move downward at high speed and with great force, as shown in FIGS. 9 and 10. The power plunger 68 impacts the pavement 96 and crushes the pavement 96 as shown in FIGS. 5 and 6. When the power plunger 68 reaches the maximum lowered position shown in FIG. 10, the collar 72 will engage the cushion 70.

The destruction device 60 is then raised again by the arm 26 and the boom 22 and moved above the pavement 96 to an adjacent position. The housing 64 is lowered again for the actuator plunger 80 to engage the pavement 96 and the operation is repeated so that the power plunger 68 impacts the pavement at some adjacent locations. The pavement is destroyed as shown in FIG.

Thus, the destruction device of the present invention is operated without the use of a special motor to operate it. The breaking device 60 is activated by moving the boom arm 26 and the boom 22 with respect to the surface to be broken.

When it is desired to destroy a wall, a ceiling, etc., the boom 22 and the boom arm 26 are operated by changing the angle of the housing 64.

Thus, the breaker 60 can be employed to break a substantially horizontal surface, or a substantially vertical surface, or any other angled surface. However, at some angles, the actuator plunger may be used to facilitate actuation.
You need to install a return spring on the 80.

According to another aspect of the invention, the opposing first surface 102 and second surface 103 (as shown in FIGS. 4 and 5).
And the first thickness portion 104 has a thickness including the first surface 102 and the second thickness portion 106 includes the second surface 103, and has a compressive force greater than a tensile force.
A method is provided for destroying a plurality of debris. An example of such a composite material 96 is concrete containing Portland cement.

In this unique method step,
A holding pressure is applied to the first surface of the substrate substantially in the direction of the second surface 103. The holding pressure is then increased to a strength at which a tensile force is generated along the first thickness portion 104 and the first surface 102. Thereafter, the increased holding pressure is maintained while the first surface 102 is impacted in the direction substantially toward the second surface at a position away from the holding pressure position.

As described above, the holding pressure or the concrete bending pressure is applied by the actuator plunger 80, and the impact force is applied by the power plunger 68.

For a person skilled in the art, when the holding pressure applied to the first surface of the concrete is increased, a tensile force is generated in the upper part of the concrete and a compressive force is generated in the lower part according to the generation of the bending force applied to the concrete. Easy to understand.

When such a force is applied to concrete and then such a strong impact in the vicinity of the bending force is applied, a very deep position is compared to when the composite material is impacted without applying such a bending force. It has been discovered that until the concrete is crushed into a very large number of pieces, the size of individual pieces is smaller. According to the method of the present invention, the innate properties of artificial and naturally occurring concrete and other composite materials have been utilized to mechanically assist the fracture process. As shown in Fig. 5, a large fracture line has an impact angle of about 45 degrees against a conventional substantially vertical crack generated when impacting concrete without stress. It was confirmed that it occurred in the downward direction.

The strength of holding or bending pressure applied to concrete is generally a function of the thickness of the concrete to be destroyed. The majority of concrete to be removed falls within the range of thickness below 30 cm. Thus, the preferred holding pressure magnitude is in the range of about 42 kg / cm ² to about 10.5 kg / cm ² . This pressure preferably holds elements or actuator plungers with ends having an area greater than about 45 cm ^2.
Applied by 80. At pressures below the desired minimum,
The upper surface of the concrete is not well stressed and the destruction is inefficient and waste of input and cost.
Pressures above the desired maximum value result in undesired waste of input and expense as the concrete is stressed more than necessary. If the surface area of the retaining element is below the desired range, the first surface of the concrete is exposed to undesired shear forces, and if the surface area of the retaining element is above the desired range, the device is utilized in its construction. More power is required to waste material and move and operate the device.

When breaking concrete, the distance between holding force and impact force should be 2.54 cm or more, and in order to destroy concrete efficiently and effectively, concrete should be shocked at intervals of 13 cm or more. Was discovered. If the distance between the holding force and the impact force is smaller, an undesired shearing action occurs, and if the distance between the impact forces is smaller, cracks due to excessive fracture of concrete and / or concrete This is a waste of resources due to the inadequate use of lateral propagation of.

While the preferred embodiment of the boom actuation demolition device of the present invention has been described, many modifications of its shape, details, proportions and placement of parts, and method of operation are possible within the scope of the present invention, which are generally Specifically, it is included in the boom actuating destruction device described in the appended claims.

Claims (9)

[Claims] 1. A holding pressure is applied on the surface (102) of the composite material (96) in a direction substantially perpendicular to the surface (102); inside the composite material (96) along the surface (102). Increasing the holding pressure sufficient to generate a pulling force on the surface (102) at a position remote from the holding pressure while maintaining the increased holding pressure in a generally vertical direction. A method for destroying a composite material (96), which comprises impacting and destroying the composite material (96) into a plurality of pieces. 2. A support structure (64) suitable for mounting on a movable arm member (20); an axially movable power plunger (68) supported by the support structure (64); A member (76); an elastic member (76) coupled to the power plunger (68) and the support structure (64), the elastic member (76) forcing the power plunger (68) from the support structure (64) in a predetermined direction. An actuator plunger (80) carried by a support structure (64) and having an extension; a means for moving the power plunger (68) relative to the position of the actuator plunger (80); A latch member (86) engageable with a portion (72) of the power plunger (68) to maintain the position; a latch member depending on the relative positions of the support structure (64) and the actuator plunger (80). Release means (90) carried by the support structure (64) for releasing 86) from the power plunger (68); support structure (64) to be broken by the arm-like member (20) Actuator plunger moved toward the surface (80)
Engages with the surface to be destroyed and further moves the support structure (64) in the direction of the surface to be destroyed, forcing a relative movement between the support structure (64) and the plunger (68, 80),
Such movement opposes the force of the elastic member (76) and further movement of the support structure (64) toward the surface to be destroyed causes the latch member (from the portion (72) of the power plunger (68) to move. The disengagement means actuates to disengage the engagement of the power plunger (6) under the influence of the elastic member (76).
A breaking device (60) suitable for being carried by a movable arm-like member (20), characterized in that it rapidly releases 8) to engage the surface to be broken. 3. The breaking device (60) according to claim 2, wherein the latch member (86) is rotatably supported by an actuator plunger (80). 4. The power plunger (68) has a latch member (8).
A destructive device (60) in accordance with Claim 2 including a collar (72) engaged by 6). 5. The support structure (64) is elongated, and the actuator plunger (80) and the power plunger (68) are substantially parallel elongated cylindrical members.
Destruction device according to paragraph (60). 6. The support structure (64) is supported by the arm-shaped member (20), and therefore has a mounting bracket (62) suitable for being rotatably mounted on the movable arm-shaped member (20). The destructive device (60) of claim 2 including. 7. An abutment member for manipulating the latch member (86) for engaging the latch member (86) and releasing the latch member (86) from said portion of the power plunger (68). Destruction device (60) according to claim 2 including 90). 8. The support structure (64) comprises a pair of opposing walls (97,9).
8) including an elongated housing, the actuator plunger (80) being an elongated tubular member extending through opposite end walls (97, 98), and the power plunger (68) being an elongated tubular member. The destruction device (60) according to claim 2, which is provided adjacent to and parallel to the actuator plunger (80) and extends between the opposed end walls (97, 98). . 9. The support structure (64) comprises a pair of opposing walls (97,9).
8) including an elongated housing having an elongated housing extending adjacent the actuator plunger (80) and between opposing end walls (97, 98), the power plunger (68) extending to the actuator plunger (80). Adjacent to
A disruption device (60) in accordance with Claim 2 extending through opposite end walls (97,98).