JPS63273800A - Laser initiating detonator - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a laser detonator that improves detonation properties by configuring the structure of the chamber for loading explosives, loading specific gravity, and constraint conditions of the chamber in a specific manner. It is something.

(Prior art) Conventionally, detonators used to detonate explosives include industrial detonators that use a fuse and electric detonators that allow current to flow through a conducting wire, but in recent years laser detonators that use laser light have been developed. ing.

A ruby laser, a YAG (yttrium aluminum garnet) laser, or the like is used as a laser oscillation device for such a laser detonator.

As a detonator that is detonated by a laser beam from the laser oscillation device, a detonator as shown in FIG. 3 is conventionally known (see US Pat. No. 3,528,372).

This laser detonator 30 has an air gap 37 and a plate 4.
An optical fiber 39 is connected to the upper part of the explosive 31 placed in the first chamber 33 through a lens 36, and the first chamber 33 and the second chamber 34 are defined by Chamber 3
3 and 34, a plate 40, a gap 37, a lens 36, and an optical fiber 39 are surrounded by a restraining wall 38, the end of the optical fiber 39 is sealed with an embolus 35, and a multilayer explosive is loaded into both chambers 33 and 34, respectively. 31 and 32 are class 2 high-performance explosives, and the loading specific gravity of each chamber is such that the upper part is higher than the lower part, and the specific gravity structure of both chambers is the same.

(Problems to be Solved by the Invention) Such a laser detonator has a complicated structure because it is divided into a first chamber and a second chamber, and is provided with a gap and a plate. A second chamber is placed in the part of the first chamber that contacts the optical fiber.
Because it was loaded with only high-grade explosives, most of the laser light irradiated through the optical fiber was reflected and could not be efficiently absorbed by the explosives. Further, since the loading specific gravity of the explosive loaded in each chamber was higher in the upper part than in the lower part, the ignition sensitivity by laser light was low in the first chamber. In addition, since the restraining wall also exists around the second chamber, when the second chamber detonates, the power is concentrated at the bottom, which has the disadvantage that the detonation ability of the explosive in the area in contact with the restraining wall is reduced. Ta.

In order to solve the above-mentioned problems, the present invention provides a laser detonator with a specific configuration, which simplifies the structure, efficiently absorbs laser light, ignites easily, and detonates reliably. An object of the present invention is to provide a laser detonator that can sufficiently detonate loaded explosives.

(Means for Solving the Problems) The present invention provides a laser detonator in which an optical fiber is brought into contact with the upper part of the explosive and a restraining wall is provided on the outside of the explosive.
The explosive loaded in the upper part that contacts the optical fiber is a Class 2 high-performance explosive containing a black laser light-absorbing material, or the explosive loaded in the upper part is a Class 2 high-performance explosive containing the above-mentioned laser light-absorbing material. The explosives loaded in the middle and lower parts are class 2 high-performance explosives.
The loading specific gravity of the explosives loaded in the lower part is higher in the middle than in the upper part and higher in the lower part than in the middle, and only the sides of the explosives loaded in the upper part or the upper part and the middle part are surrounded by the restraining wall. shall be.

(Function) According to the present invention, when the upper part of the explosive loaded in the laser detonator is irradiated with laser light through an optical fiber,
The laser light-absorbing material contained in the explosive loaded at the top is heated, igniting the surrounding explosive, increasing the burning rate of the explosive at the top surrounded by the restraining wall, and increasing the gas pressure. Therefore, when the combustion progresses to the lower explosive, the pressure of the combustion gas increases to a sufficient level to detonate the lower explosive, and the lower explosive charged with the laser detonator of the present invention detonates. The explosives around it detonate.

(Example) The present invention will be explained below with reference to the drawings.

FIG. 1 shows a first example of the laser detonator of the present invention. In this example, the laser detonator 1 has a bottomed tube body 2, in which the upper part of the tube body 2 is loaded with a class 2 class high explosive 4 containing a laser light absorbing substance, and the lower part is loaded with a class 2 class high explosive 4 containing a laser light absorbing substance. Load high explosive 5. At this time, the explosive 4 loaded in the upper part of the tube body 2
It is surrounded by a restraining wall 6 and its upper side is covered by an embolus 7. That is, the central part of the embolus 7 is penetrated by the optical fiber 8, and in this state, the embolus 7 is fitted into the upper end of the tube body 2 so that the end opening of the optical fiber 8 can come into direct contact with the explosive 4.

Explosives used in the laser detonator of the present invention configured as described above include, for example, PETN (pentaerythritol tetranitrate), tetryl () IJ nitrophenylmethyl nitroamine), RDX () rimethylene trinitramine), High-performance explosives selected from class 2 high-performance explosives such as HMX (cyclotetramethylenetetranitramine) are used, and the explosive 4 loaded at the top in particular contains carbon to efficiently absorb radar light. 0.5 to 10% by weight of black carbon-based substances such as black, graphite, or dyes that have an absorption band at the laser wavelength, such as black dyes (Direct Fast Black B1 manufactured by Sumitomo Chemical Co., Ltd.) and other laser light absorbing substances. The added Class 2 class high explosive is used as an igniter or a detonator.

For example, when PETN is used as the explosive, the loading specific gravity of the explosive loaded in the laser detonator of the present invention is 0.8.
Used in the range of ~1.7 but with explosives loaded on top 4
The loading specific gravity is usually selected from the range of 0.8 to 1.4, preferably from the range of 0.8 to 1.2. In addition, the loading specific gravity of the explosive 5 loaded at the bottom is usually 1.0~
It is selected from a range of 1.7, preferably from a range of 1.2 to 1.7.

In other words, the loading specific gravity of the explosive loaded at the top should be selected to be low in order to improve the ignition sensitivity of the laser, to continue combustion after ignition, to easily transfer from combustion to deflagration, and from deflagration to detonation. Make it. In addition, 5 explosives loaded at the bottom
is sufficiently detonated by the detonation wave of the explosive loaded at the top, and the loading specific gravity is selected to be high in order to obtain the explosive power sufficient to detonate the explosive loaded with the laser detonator of the present invention. .

The material of the restraining wall 8 is selected from metals with high tensile strength, such as iron, stainless steel, copper, and aluminum, or reinforced plastics with comparable strength. The thickness of the restraining wall 8 is determined by the inner diameter of the upper chamber and the material used, but for example, if the inner diameter is 5 mm and iron is used, the thickness should be 0.1 mm or more, but it is usually 1 to 2 mm.
The range is mm.

This restraining wall 8 is ignited by the explosives 4 loaded at the top.
It is used to maintain the pressure of the burned gas during combustion. Therefore, its length should be sufficient to cover at least the side surface of the explosive 4 loaded at the top. Further, although the detonating force of the explosive at the portion in contact with the side surface of the explosive 5 loaded in the lower part is weakened, the restraining wall 8 may cover even the side surface of the explosive 5 loaded in the lower part.

The tube body 2 is used as a container for loading the explosive 4.5, and may be made of any material and thickness that will not be deformed by the pressure during loading, such as iron, copper, aluminum, reinforced plastic, etc. For example, in the case of copper, if the loading specific gravity of the explosive is 1.4, the thickness is 0.1 m.
It is sufficient if it is about m. The optical fiber 8 and the class 2 high-performance explosive 4 containing a laser light absorbing substance may be brought into direct contact with each other, or may be brought into contact indirectly through a lens.

A second example of the laser detonator of the present invention will be explained below with reference to FIG.

In this example, the laser detonator 10 includes a bottomed tube body 11,
The length of the drug that is sufficient to ignite when the laser beam is absorbed by the upper part of the tube body 11 where the optical fiber 8 contacts is usually 1 to 1.
Loaded with Class 2 high-performance explosive 4 added with a laser light absorbing material within a range of 15 mm, and the middle and lower parts are
Loaded with species class high explosive 13. Further, the upper side of the explosive 4 is covered with an embolus 7. At this time, the optical fiber 9 = 8 is inserted into the center of the embolus 7, and in this state, the embolus 7 is fitted to the upper end of the tube body 11 so that the ends of the optical fiber 8 can come into direct contact with the loga explosive 4. Make it. Further, the outside of the tube body 11 is surrounded by a restraining wall 6 around the upper explosive 4 and the middle explosive 13.

The operation of the laser detonator configured as described above is the same as that described in the first example except that the explosive proceeds from the upper part to the middle part and then to the lower part, so a detailed explanation thereof will be omitted.

The present invention will be explained in detail below.

Specific Example 1 A laser detonator shown in FIG. 1 was produced by the following method.

As an explosive 5 to be loaded into a copper tube body 2 having an outer diameter of 7.6n+m, a thickness of 0.3 mm, a length of 50 mm, and a tube bottom 3 of 0.3 mm thick, at the bottom between 10 mm from the tube bottom 3, Loaded with PETN, a class 2 high-performance explosive, with a specific gravity of 1.40.
Loaded with. Next, the inner diameter is 5. Omm, thickness l+++m,
A restraining wall 6 made of iron and having a length of 30 mm was loaded so as to be in contact with the explosive loaded at the bottom. Next, PETN to which 1% by weight of carbon black, which is a laser light absorbing substance, was added was loaded as an explosive 4 on the inside of the restraining wall 8 with a loading specific gravity of 1.15. Next, the embolus 7 was inserted into the inside of the tubular body 2 so as to contact the restraining wall 6 and fixed by adhesive.

The laser detonator 1 shown in FIG. 1 has a core diameter of 0.8
An optical fiber 8 made of quartz material with a length of 30 m and an attenuation rate of 66 B/km is connected, and the wavelength is 1.06 μm and the pulse width is 0.
．． When irradiated with a laser beam from a YΔG laser that generates a laser beam with an energy of 2.5 J for 4 ms, the laser detonator 1 completely detonates, meeting the Japanese Industrial Standards (JIS) standard.
It penetrated the lead plate (40mm x 4mm x 4Q mm) of the lead plate test specified in K4806-1978). In addition, explosives (TN
We were able to completely detonate the T/trinitrotoluene (70%, talc 30%) and obtain blast marks on a lead plate (70mm x 70mm x 70mm) comparable to that of a No. 6 industrial detonator.

Concrete Example 2 The laser explosive detonator 20 shown in FIG. 2 has a copper detonator tube body 11 having an inner diameter of 6.2 mm, a thickness of 0.3 mm, a length of 55 mm, and a tube bottom 12 of 0.3 mm thickness. PETN is loaded as a class 2 high performance explosive between 15 mm from the bottom 12 of the tube with a specific gravity of 1.
．． 40 mm, and in the middle part, PETN was loaded with a loading specific gravity of 1.15 from a position 15 mm from the bottom 12 of the tube to 35 mm, and in the upper part, PETN was loaded with a specific gravity of 1.15 from a position 35 mm from the bottom 12 of the tube.
1% by weight of black dye (Direct Fast Black B, manufactured by Sumitomo Chemical Co., Ltd.), which is a laser light absorbing substance, is added between Il.
The added Te) IJ was loaded at a loading specific gravity of 1.15.

Next, a restraining wall 6 made of iron with an inner diameter of 6.8 mm, a thickness of 1 mm, and a length of 40 mm surrounds the explosives loaded in the upper and middle parts, and is attached to the tube body 11 so that the lower part is not covered. The same laser detonator 1 as shown in Example 1 was prepared and the same tests as in Example 1 were conducted, and the same good results were obtained.

Comparative Example 1 A conventional laser detonator 30 as shown in FIG. 3 was prepared.

A glass lens 36 was inserted into a restraining wall 38 made of copper and having a length of 58 mm, an inner diameter of 6 mm, and a thickness of 1 mm. PETN, which is a class 2 high-performance explosive, was used as the explosive, and it was placed in the first chamber 33 at a distance of 4 mm from the surface in contact with the lens 36.
The loading specific gravity was 1.40 between 4mm and 10mm, 1.20 between 4mm and 10mm, and 1.10 between 10mm and 16mm. 6 mm in diameter at the bottom of the first chamber 33,
A circular copper plate 40 with a thickness of 0.3 mm was placed and fixed by adhesive. Next, with a gap of 5'mm, the explosive in the second chamber 34 is placed at a position 21mm from the lens surface.
25mm to 31mm with loading specific gravity of 1.40 between 5''m
between 1.20 and 1.1 between 31 and 37+nmO
0 and loaded with PETN at 1.00 between 37 mm and 43 mm, respectively. The tube bottom 41 has a diameter of 3 mm and a thickness of 0.
．． A 3n+m copper plate was adhered and fixed to the restraining wall 40.

Next, an embolus 35 was inserted, and an optical fiber 39 was placed and fixed.

When this conventional laser detonator 30 was irradiated with laser light in the same manner as in Example 1, it did not ignite and did not explode.

Comparative Example 2 In the conventional laser detonator of Comparative Example 1, an explosive containing 1% by weight of carbon black as a laser light absorbing substance in PETN was used as an explosive loaded within 4 mm from the surface of the first chamber 33 in contact with the lens 36. A sample similar to Comparative Example 1 was prepared except that the sample was loaded with a loading specific gravity of 1.40, and the same test as Specific Example 1 was conducted.

As a result, although this conventional laser detonator detonator ignited, it was so weak that it did not penetrate the lead plate in the lead plate test, nor could it detonate pure explosives.

(Effects of the Invention) The laser detonator of the present invention has the following features.

(1) While the conventional laser detonator does not contain a laser light absorbing material in the explosive loaded in the upper part that contacts the optical fiber, the laser detonator of the present invention contains a laser light absorbing material. , Q with good absorption efficiency of laser light and large peak output with a pulse width of several 10 ns
Ignition can be reliably achieved even with a laser with a small pulse width of several μs or a continuous wave laser with a peak output other than the laser oscillation method using a switch.

(2) Explosives loaded at the top absorb laser light,
Explosives that contain laser light-absorbing substances are used only in the part to be ignited, and the other parts do not contain laser light-absorbing substances, so when they burn, there are no components other than the explosives, making them very powerful.

(3) In the conventional laser detonator, the loading specific gravity of the explosive is
In each of the first and second chambers, the upper part is higher than the lower part, whereas the laser detonator of the present invention makes the loading specific gravity of the explosive higher in the lower part than in the upper part, and the explosive loaded in the second part is It easily deflagrates, transitions from deflagration to detonation, and can reliably detonate the explosives loaded at the bottom.

(4) While the conventional laser detonator has the entire side surface of the first and second chambers covered with a restraining wall, the laser detonator of the present invention has a side surface of the explosive loaded in the upper or middle part. Since the lower part is not covered, the sides of the explosive loaded in the lower part also have detonating force, and the explosive loaded with the laser detonator of the present invention can be sufficiently detonated.

[Brief explanation of drawings]

FIG. 1 is a sectional view showing an example of the laser detonator of the present invention, FIG. 2 is a sectional view of another example of the laser detonator of the present invention, and FIG. 3 is a sectional view of a conventional laser detonator. . 1... Laser detonator of the present invention 2... Tube body 3... Tube bottom 4... Class 2 high-performance explosive added with a laser light absorbing substance

Claims (1)

[Claims] 1. In a laser detonator in which an optical fiber is brought into contact with the upper part of the explosive and a restraining wall is provided on the side of the explosive, the explosive loaded in the upper part that contacts the optical fiber is covered with a black laser light absorbing material. A type 2 class high-performance explosive containing a high explosive, and the loading specific gravity of the explosive loaded in the lower part is higher than that of the explosive loaded in the upper part, and only the sides of the explosive loaded in the upper part are surrounded by a restraining wall. A laser detonator characterized by: 2. In a laser detonator, which has an optical fiber in contact with the upper part of the explosive and a restraining wall on the side of the explosive, the explosive loaded in the upper part that contacts the optical fiber is heated to High explosives are used, and the explosives loaded in the middle and lower parts are used as secondary explosives.
The specific gravity of the explosives loaded in each part is higher in the middle than in the upper part and higher in the lower part than in the middle, and only the sides of the explosives loaded in the upper and middle parts are surrounded by restraining walls. A laser detonator characterized by the following features: