JP3192929B2 - Discharge hydraulic pressure destruction method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention provides the disrupter the free surface is 2 or more surfaces, rock, concrete structure, to discharge electrostatic pressure disruption method for destroying underwater rocks and concrete structures.

[0002]

2. Description of the Related Art An electric energy charged and stored in a capacitor is discharged and supplied to a thin metal wire in a very short time. The liquid pressure destruction method, which destroys the air, does not depend on the ambient temperature or the elapsed time after loading, does not explode unless voltage is applied, and is extremely safe. It is used to destroy concrete structures such as converted buildings.

[0003]

However, in the conventional electric discharge hydraulic pressure destroyer, since an impact force is generated evenly in the circumferential direction,
For example, when there is another free surface on one side and a continuous fracture surface is desired to be formed, the same impact force is generated on the other side, so that there is a problem that the fracture cannot be performed efficiently.

[0004] The present invention is able to significantly generate an impact force in a predetermined direction, for example, that the free surface to provide a discharge pressure destroying method that can more effectively disrupt the above two surfaces of the debris Aim.

[0005]

Means for Solving the Problems] discharge pressure destroying method according to the first aspect of the present invention in order to achieve the above object, Conde
The electric energy stored in the sensor is stored in a sealed cylindrical
To supply metal wires in a breaking container in a very short time
More rapid vaporization of the thin metal wire and the surrounding liquid, body
Use a discharge hydraulic pressure breaker that generates an impact force due to product expansion.
The free surfaces are adjacent to each other when destroying
One free side and another free side when
A breaking hole is formed at a predetermined distance away from the inside of the cylindrical breaking container.
Fluid pressure breaker with a thin metal wire arranged close to one side wall
Using the discharge hydraulic pressure rupture tool on one side
Load the breaking hole so that the wall is on the other free side, and
By supplying energy to a thin metal wire in a short time,
Large impact force is generated on the other free surface side where the thin metal wire approaches
The fracture surface or fracture hole that is continuous with the free surface.
It forms a destructive surface that connects them.

[0006] The discharge hydraulic pressure destruction method according to claim 2 is characterized in that:
In the invention described in claim 1, the breaking hole and the other free surface
The distance Y is the width of the direct breaking area by the discharge hydraulic pressure breaking tool.
Then, the range of Y ≦ L is set, and the width L of the direct destruction region is set.
Is greater than the direct fracture area inside the fracture hole and the surface of the fracture hole
Below the direct destruction area.

According to the third aspect of the present invention, the electric energy charged and stored in the capacitor is supplied to the thin metal wire in a very short time, so that the thin metal wire and the liquid around it are rapidly vaporized and expanded. When the object to be destroyed is destroyed using a discharge hydraulic pressure destroyer in which the impact force generated by the discharge is evenly generated around the periphery, the fracture hole is formed with a larger diameter than the discharge hydraulic pressure destroyer, and inside the fracture hole The discharge hydraulic pressure breaking tool is arranged close to the inner surface of the breaking hole on the side requiring a large impact force, and the remaining space of the breaking hole is filled with a pressure transmitting material to break the discharge.

[0008] Further, the invention described in claim 4 is the present invention.
In the third aspect, the free surfaces are adjacent to each other and are two or more.
At one time, one of the free surfaces
Form a rupture hole for electric discharge breakdown, this rupture hole and other free surface
Is the width of the direct breaking area by the discharge hydraulic pressure breaking tool.
Let L be the range of Y ≦ L, and
The width L is larger than the direct fracture area inside the fracture hole and
It is less than the direct fracture area on the hole surface.

[0009] The invention according to claim 5 provides the invention according to claim 2 or
In the invention described in 4, a plurality of fracture holes are formed and
When discharge breakdown occurs, the distance X between adjacent breakdown holes is
X ≦ 2 × L.

[0010] The discharge hydraulic pressure breakdown according to claim 1 or 3
According to the construction method, for example, in the case of an object to be destroyed having two or more free surfaces adjacent to each other, when the discharge breakdown surface is desired to be continuous with another free surface, or when the surface connecting the fracture holes is to be formed as a finished surface. By loading the side wall of the container where the thin metal wire approaches toward the other free surface side into the breaking hole, a large impact force is generated on the other free surface side and a small impact force is generated on the opposite side. Can be destroyed effectively.

According to the second or fourth aspect of the present invention, the distance between the tip of the rupture hole and the other free surface is directly within the rupture area, so that the destruction is performed on the other free surface. , And discharge breakdown can be performed in a state where the object to be destroyed is scraped off, so that effective destruction can be performed.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Here, the discharge pressure rupture according to the present invention is described.
An embodiment of the breaking method will be described with reference to FIGS.

First, an outline of a discharge hydraulic pressure breaking tool used in the discharge hydraulic pressure breaking method will be described. As shown in FIG.
The discharge probe 3A, which is a discharge hydraulic pressure breaking tool to be loaded into the breaking hole 2 formed in the object 1 to be broken, is made of synthetic rubber or waterproof paper filled with a breaking liquid 4 such as water. Between the container 5, a pair of electrode rods 7 penetrating through the central portion of the top plate 5 a of the container 5, extending into the breaking liquid 4, and held in parallel with each other by the spacer 6, between the tip of the electrode rod 7 An energy supply circuit 10 having a large-capacity capacitor 10a, which is constituted by a connected thin metal wire 8 and is disposed apart from the object to be destroyed 1, is connected to an electrode rod 7 by a lead wire 9 having a discharge switch 9a. ing. The energy supply circuit 10 includes a DC high-voltage power supply 10b that charges and accumulates electric energy in a capacitor 10a.
c are connected to each other by an interposed connection line 10d.

The relationship between the charging voltage Vc of the capacitor 10a of the energy supply circuit 10 and the discharge impact force F of the discharge probe 3A is in a proportional relationship as shown in the graph showing the F-Vc characteristic in FIG. By the way, this discharge probe 3A
7, the width Li of the internal direct breakdown region is different from the width La of the direct breakdown region on the surface, as shown in FIG. The discharge impact force F and the width Li, L of the direct breakdown region
As shown in FIG. 9 and the equation, the relationship F
It is derived as a proportional relationship between c (volt) and the width L (cm) of the direct breakdown region.

| Vc | / 120 ≧ L ≧ | Vc | / 1200... In FIG. 9, the width La of the direct breakdown region on the surface is expressed by |
Vc | / 120, the width Li of the internal direct breakdown region
Corresponds to | Vc | / 1200 in the equation.

The discharge probe 3 is such that the thin metal wire 8 is disposed at the center of the container 5 in a plan view, and the destructive force is uniformly applied to the periphery. Experiments have shown that the relationship between the impact force S by the discharge probe 3A and the distance N from the discharge point (the thin metal wire 8) to the inner surface of the breaking hole 2 is inversely proportional, as shown in FIG. Therefore, when it is desired to form a destructive surface that is continuous with another free surface by generating an impact force concentrated in a predetermined direction as in the present invention, or as shown in FIG.
A fracture surface M connecting the fracture hole 2 by reducing the impact force on the predetermined surface side
When the surface is a finished surface, a discharge hydraulic pressure breaker that generates a large impact force on the predetermined surface side is desirable.

That is, the discharge probe 3B shown in FIG.
Is a method in which the electrode rod 7 and the thin metal wire 8 are connected to one side 5b in the container 5.
It is located close to the side. The shift amount is N ₁ : N
₂ Then, the destructive force S generated on one side 5b side
_1, if the destructive force S ₂ that occurs on the other side 5c side and _{S 1 = (N 2 / N} 1) × S 2 ... equation relationship.

As a device that directly uses the breaking hole 2, a discharge hydraulic pressure breaking tool 3C shown in FIG. 2 can be considered. That is, the breaking hole 2 formed in the object 1 is used as a container, the electrode rod 7 and the fine metal wire 8 are arranged close to the one side surface 2a side, and the breaking liquid 4 is filled and the lid 5d is filled.
Sealed. The equation is applied to the discharge hydraulic pressure destroyer 3C, similarly to the discharge probe 3B.

Further, there is a method of using the discharge probe 3A of FIG. 6 to unevenly distribute the impact force. That is, as shown in FIG. 3, a breaking hole 2 'larger than the diameter of the discharge probe 3A is formed, and the discharge probe 3A is arranged close to or in contact with the inner surface on the side where a large impact force is required.
Is filled with a pressure transmitting material C made of jelly or concrete. 5e is a sealing lid provided as needed. In this case, it is more effective that the crushing hole 2 'has a diameter of 40 to 50 mm or more for breaking.

Next, an embodiment of the discharge hydraulic pressure breaking method is shown in FIG.
This will be described with reference to FIGS. a. First, a plurality using perforating device, for example one another
For example, two breaking holes 11A and 11 are formed on the first free surface F1 of the object 1 having two adjacent free surfaces F1 and F2.
B are formed vertically.

The breaking holes 11A and 11B are
The distance Y between b and the second free surface F2 is within the range of the width L (actually, Li) of the direct breakdown region 12 by the discharge probe 3. That is, Y ≦ L. The distance X between the destruction holes 11A and 11B is within twice the width L of the direct destruction region 12. That is, X ≦ 2 × L...
Expression The width L of the direct destruction region 12 at this time satisfies the expression. b. A discharge probe 3A is loaded into each of the breaking holes 11A and 11B, and a high voltage is supplied from the capacitor 10a to the fine metal wire 8 in a very short time.
And the surrounding liquid 4 is instantaneously vaporized, the impact force is transmitted to the surrounding object 1 to be destroyed, and the destroyed area 12 is directly destroyed.

Thus, the breaking holes 11A and 11B and the second
Is destroyed with the free surface F2 of the
3 are continued and the object to be destroyed 1 is cut off. Therefore, by repeating this, the object to be destroyed 1 can be more effectively destroyed.

In FIG. 12, reference numeral 12 'denotes a direct destruction area 1.
Although it is in the range of 2, because it is not connected to the free side,
This is the part where the chip is not destroyed in the scraped state and a crack is generated due to discharge breakdown.

In the above-mentioned discharge hydraulic pressure breaking method, the discharge probe 3A which generates a destructive force evenly in the circumferential direction is used. However, the discharge probe 3B shown in FIG. 1 or the discharge hydraulic pressure breaking tool 3C shown in FIG. 2 is used. Then, by loading the large destructive force S ₁ so as to concentrate on the second free surface F2 side, the width L of the second free surface F2 side direct destruction area 12 is increased, and therefore the destruction hole 11A is provided. , 11B and the second free surface F2 can be increased, and effective destruction can be performed.

Further, the discharge probe 3A by loading as shown in FIG. 3, it is possible to generate a greater destructive power S ₁ to the second free surface F2 side, can be effectively destroyed.

[0026]

As described above, according to the present invention ,
According to the discharge hydraulic pressure destruction method according to any one of Items 1 and 3 , for example, when it is desired to make the discharge breakdown surface continuous with another free surface, for example, with an object to be destroyed having two or more free surfaces adjacent to each other,
When the surface connecting the breaking holes is to be formed as a finished surface, a large impact force is generated on the other free surface side by loading the side wall of the container where the fine metal wire approaches toward the other free surface side and loading it into the breaking hole. Then, a small impact force can be generated on the opposite side, and the object to be destroyed can be effectively destroyed.

According to the second or fourth aspect of the present invention, the distance between the tip of the pre-breaking hole and the other free surface is directly within the breaking area, so that the breaking can be performed by another free-flowing method. It can reach the surface and can be destroyed by electric discharge in a state where the object to be destroyed is scraped off, so that effective destruction can be performed.

[Brief description of the drawings]

FIG. 1 is a plan view showing a first embodiment of a discharge hydraulic pressure destroyer according to the present invention, in which (a) is a longitudinal sectional view and (b) is a plan sectional view.

FIGS. 2A and 2B are plan views showing a second embodiment of the discharge hydraulic pressure destroyer according to the present invention, wherein FIG. 2A is a longitudinal sectional view and FIG.

FIG. 3 shows a discharge hydraulic pressure breaking method according to the present invention, wherein (a)
Is a longitudinal sectional view, and (b) is a plan sectional view.

FIG. 4 is a graph showing the relationship between the impact force of the discharge hydraulic pressure fracturing tool and the discharge point to the inner surface of the rupture hole.

FIG. 5 is a plan view illustrating an example of using the discharge hydraulic pressure destroyer.

FIG. 6 is a configuration diagram showing a basic configuration of a discharge hydraulic pressure destroyer.

FIG. 7 is a cross-sectional view showing a destruction state of an object to be destroyed by the discharge hydraulic pressure destruction tool .

FIG. 8 is a graph showing a relationship between a discharge impact force and a charging voltage in the discharge hydraulic pressure breaking method.

FIG. 9 is a graph showing a relationship between a direct breakdown region and a charging voltage in the discharge hydraulic pressure breakdown method.

FIG. 10 is a plan view showing an embodiment of a discharge hydraulic pressure breaking method according to the present invention.

FIG. 11 is a side sectional view showing the discharge hydraulic pressure breaking method.

FIG. 12 is a side sectional view showing a destruction state by the discharge hydraulic pressure destruction method.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Destructible object 2, 2 'Breaking hole 3A Discharge probe 3B Discharge hydraulic pressure breaker 3C Discharge probe 4 Breaking liquid 8 Thin metal wire 10 Energy supply circuit 10a Capacitor S Impact force N Shift amount C Pressure transmitting material 11A, 11B Breaking hole 12 Direct breakdown area 13 Fracture surface L Width of direct breakdown area Vc Charge voltage F1 First free surface F2 Second free surface

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-63-221857 (JP, A) JP-A-55-78765 (JP, A) JP-B-43-2114 (JP, B1) (58) Field (Int. Cl. ⁷ , DB name) B28D 1/00 B26F 3/00 E21C 37/18

Claims (5)

(57) [Claims] An electric energy charged and stored in a capacitor.
The metal wire inside the sealed cylindrical breaking container
The liquid between the thin metal wires and the surrounding liquid
Discharge that generates impact force due to rapid vaporization and volume expansion of the body
When destroying an object to be destroyed by using a hydraulic rupture tool, when one or more free surfaces are adjacent to each other,
A destruction hole is formed at a predetermined distance from other free surfaces
And placed a thin metal wire close to one side wall in the cylindrical breaking container.
Using a discharge hydraulic pressure destroyer, the discharge hydraulic pressure breaker is
By loading electric energy into the metal wire in a short time
Impact force on the other free surface side where the thin metal wire is approached.
Ku is generated, thereby a fracture surface or destroy holes between contiguous free surface
Discharge hydraulic fracturing, characterized by forming a tying fracture surface
Law. 2. The distance Y between a breaking hole and another free surface is determined by the discharge liquid
Assuming that the width of the direct breaking area by the pressure breaking tool is L, Y ≦ L
And the width L of the direct destruction area is the direct destruction area inside the destruction hole.
Or more, and it has the following direct destruction region of fracture pore surface
The method according to claim 1, wherein: 3. The electric energy charged and stored in the capacitor is supplied to the thin metal wire in an extremely short time, so that the impact force generated due to rapid vaporization and volume expansion of the thin metal wire and its surroundings is evenly generated around the thin metal wire. When breaking an object to be destroyed by using a discharged hydraulic pressure breaker, the diameter of the rupture hole is made larger than that of the discharge hydraulic pressure breaker, and a large impact force is required for the discharge hydraulic pressure breaker in the rupture hole. thereby located close to the fracture hole inner surface of the side to be, especially to breakdown by filling the pressure transmitting member to the remainder space-breaking pores
Discharge pressure destroying method according to symptoms. 4. When two or more free surfaces are adjacent to each other.
At a position where one free surface is a predetermined distance away from the other free surface
At the same time, a discharge hole is formed in which a discharge hydraulic pressure breaker is
Discharge pressure on the inner surface of the fracture hole on the other free side.
The breaking tool is located, and the distance Y between the breaking hole and the other free surface is determined by the discharge hydraulic pressure breaking tool.
Let L be the width of the direct destruction region due to
And the width L of the direct destroy region, direct breakdown region of the internal fracture holes
Or more, and it has the following direct destruction region of fracture pore surface
The method according to claim 3, characterized in that: 5. A discharge destruction is simultaneously performed by forming a plurality of destruction holes.
In this case, the distance X between adjacent breaking holes is such that X ≦ 2 × L
5. The release according to claim 2, wherein the range is a range.
Electro-hydraulic destruction method.