NO136575B - - Google Patents

Description

The present invention relates to an explosive package for mixing at the point of use, and which includes two components that are mixed to form an explosive.

It is known to produce an explosive in two parts, each of which is not an explosive, and then to mix the two parts together at the point of use shortly before use to form the explosive. The two parts are stored, transported and otherwise processed separately before mixing. As each of the parts in itself is not explosive by nature, the special care for storage, transport and handling as for an explosive is not required.

U.S. patent 2,892,377 relates to individually packing ammonium nitrate in a watertight container with a soft elastic wall at one end. Ammonium nitrate is not an explosive in itself, but is made explosive by adding a liquid fuel. An injection syringe is used to inject the liquid fuel through the elastic wall and into the ammonium nitrate.

U.S. patent 2,929,325 relates to packing particulate ammonium nitrate in one container and a particulate fuel in another container telescopically compatible with the first container. A rubber membrane covers the open end of the inner container and serves to keep the two materials apart. At the point of use, the two parts are telescopically brought together until a cutting blade on the closed end of the outer container perforates the membrane. The combined parts are then shaken to mix the two parts of the explosive.

On-site mixing of intrinsically non-explosive liquid and solid parts of a two-part explosive is also described in U.S. Pat. patent 3-419-443 • The special explosives mentioned in this patent are examples of two-component explosives that can be used in the package for mixing at the point of use according to the present invention.

From the U.S. patent 3-521,745 is known a mixing package for separate storage and subsequent mixing of two or three materials, in particular cosmetics, adhesives and cleaning solutions, which package consists of a rigid container covered by a thin sealing plate, and connected by a rigid extension which is also covered of a sealing plate and connected to a bellows-shaped top piece in which a cutting piston device is arranged for perforating the two sealing plates by exerting a downward pressure on the top piece.

The present explosive pack constitutes a constructional improvement of the construction according to the above-mentioned U.S. Pat. patent. Firstly, the construction of the present explosives package enables the outer container to be made of relatively thin plastic material which is common in the production of many plastic bottles. In reality, the outer container as shown in fig. 1, a thin-walled plastic bottle that has been cut off at the top and then joined together again. Secondly, the present perforating device enables the perforation to be carried out by a simple one-handed clamping operation. The thin-walled bottle is designed so that it easily deforms inwards when squeezed. The squeeze can be performed while holding the bottle in one hand. The common construction of such bottles facilitates this procedure. In contrast, in the U.S. it must patent specified container is either set down or supported by the user's other hand at the bottom when the top bellows is squeezed downwards. Furthermore, the known bottle is of a special construction. It has several sections screwed together and separated by diaphragms. •The present explosive packing thus has a much simpler construction than the known packing and is more convenient to use.

The present invention relates to an improved package for mixing at the point of use of a two-component explosive. Generally speaking, the package for the mixture at the point of use according to the present invention comprises a plastic bottle with a screw cap at the upper end. A metal box is placed in the lower part of the bottle. A perforation device is placed inside the bottle. One of the non-explosive components (eg liquid hydrazine) is placed inside the box. The other part of the explosive (e.g. powdered ammonium nitrate) can optionally be transported to the place of use in a separate container (e.g. another plastic bottle). Shortly before use, the cap on the package is removed for mixing at the point of use, and the other part of the explosive is poured into the space in the bottle above the box. The bottle cap is then placed back in place, and downward pressure is applied to the cap, causing the side walls of the bottle to buckle and the perforating device to move downwards through the top of the can. The bottle is then turned over and/or shaken to effect a thorough mixing of the two materials.

The present invention thus relates to an explosive pack with an inner container (12', 12") which forms a chamber for an intrinsically non-explosive first component (B) of an explosive, an outer container (14', 14") which surrounds the inner container (12<*>, 12") and protrudes above this forming a space above the container (12', 12") to receive an intrinsically non-explosive second component (A) of the explosive, in that the outer container (14'> 14") ends above the inner container (12<*>, 12") in an access opening for the container (14<*>, 14"), a closing device (16, 98) for come the opening, and a perforation device to create an opening in the inner container (12<*>, 12") and allow mixing of the two components (A and B) in the outer container (14'» 14") to form the explosive, characterized in that the perforating device includes an elongated handle (90, 106) projecting upwards from the inner container (12', 12") along the inner part of the outer container (14", 14") in its length above the inner container (12', 12"), and a perforation part (92, 108) connected to the lower end of the handle (90, 106) and projecting over a part of the inner container (12', 12")

and that the outer container (14<*>, 14") is easily bendable by side-clamping it near the handle (90, 106), so that such clamping can be used to move the handle (90, 106) on the perforating device laterally inwardly causing a downward swinging movement of the perforating member (92, 108) to create the opening in the inner container (12<*>, 12").

The explosive pack can further preferably be provided with a relatively rigid packing sleeve (112) which surrounds at least the part of the outer container (14") which is brought in to move the perforating device (92, 108) through part of the inner container (12) "), the packing sleeve (112) serves to prevent unwanted inward movement of the wall of the outer container (14").

Fig. 1 is a side view on an enlarged scale and partly in

section, of the mixing bottle as these are taken towards the concave side of the perforation device,

fig. 2 shows part of a section along the line 14-14 in fig. 1, and

fig. 3 is a drawing like fig. 1 of another embodiment.

In fig. 1, the field mixing bottle 14' is made of polyethylene plastic or another suitable similar material, as shown to include an upper part 74 and a lower part J6 which are welded together at 78- Before the two parts 74 and 76 are welded together, a reinforcing device is introduced in the lower part 76. It includes a box 12' which is completely sealed and contains the liquid component. For example, the box can be made so that it includes connected side and bottom wall parts and a top which is attached to the upper edge of the side wall with a seam according to conventional can lid application methods.

A cylindrical sleeve 82 is shown around the box 12', just below the rebate 80. The sleeve 82 carries a pair of diametrically opposed upright ears 84. An intermediate part of a perforator part 86 is attached to each ear 84 e.g. with a rivet 88- The perforator portion 86 includes a raised handle portion 90 and a lower perforation portion 92 which is constructed much like a conventional beer can opener. This can easily be seen in fig. 2 where the perforation portion 92 is shown with a pointed end portion which initially rests on the top 22' of the box 12*.

Before use, the solid component A is poured into the bottle 14'j and the cap 16 is put on. The user then applies a side pressure on the bottle 14<*> near the cutter handles 90. This clamping swings the cutter part 92 downward and causes the pointed end to cut a hole in the top 22<*> of the box 12'. The bottle 14' is then turned upside down and/or shaken to effect a mixture of the liquid component B with the solid component A. Fig. 3 shows the plastic mixing bottle 14" with a threaded upper part 94. An upper part 96 is threaded onto this threaded part 94- The top part 96 includes a spout-shaped outlet usually closed with a cap 98- In this embodiment, the can 12" is only shown resting on the bottom 100 of the bottle 14" • In diametrically opposed positions, a cutting tool 102 is placed on the edge part 104 of the can 12" . As in the embodiment shown in fig. 1 and 2, this tool 102 includes an upright handle portion 106 and a box-cutting or perforating portion 108 projecting substantially at right angles thereto. It also includes a fitting part HO which holds the tool 102 in position to the upper folded edge part of the box 12". In use, this embodiment is used in the same way as the embodiments in Figs. 1 and 2. Fig. 3 shows the bottle 14" surrounded of a rigid packing sleeve 112. In this particular embodiment, the packing sleeve is shown protruding only up to where the upper part 96 is united with the bottle 14" • The same type of rigid packing sleeve can be used for the other embodiments, but made to protrude up to or even flush with the top of the cap. The purpose of the packing sleeve 114 is to prevent unwanted pinching or buckling of the plastic side wall of the field mix bottle. The use of such a packing sleeve in combination with mixing bottles is considered to form part of the present invention .

As an example, the solid component A may be a mixture of ammonium nitrate and ammonium chlorate, and the liquid component B may be a mixture of hydrazine, ammonium nitrate and water. A typical composition of this type of explosive is as follows:

According to the invention, the side wall of the container 14' > 14" is translucent. A powdered dye is added to the solid component A or to the inside of the bottle 14', 14" above the box 12*, 12". The dye is of a type that will cause the mixture to become sharply or strongly colored on mixing. In this way, a person can determine by sight whether the box 12', 12" has been punctured and the liquid B has been brought into mixing contact with the solid A.

The mixing bottle 14' > 14" can be carried as a non-explosive as neither of the two components A or B is able to detonate. Shortly before the use of the explosive, the components A and B are mixed by the following method: The user presses the sides of the container 14' , 14"

in the direction of each other. This causes a downward movement of the tip of the perforators (92, 108) through the top wall 22<*> of the container 12', 12". After an opening is formed in the wall 22<«>, the bottle 14'5 14" is shaken to cause mixing of the two components A and B. This shaking is in no way dangerous when the preferred explosive mixture is used, because such an explosive can only be initiated with a detonator.

After mixing, the formed explosive mixture AB (which is a liquid) can be poured from the bottle 14', 14" into or onto different things or materials, depending on the application. The explosive AB can also be used directly inside a container l4<*>> 14 ". For a discussion of various applications of the explosive AB outside the bottle, reference is made to the above-mentioned U.S. Pat. patent 3-419,443-The explosive AB is initiated by any standard commercial detonator, e.g. a No. 8 detonator. Both electric and fuse types are satisfactory. If the explosive AB is used inside the container 14", the detonator should be immersed at least halfway in the explosive AB to ensure initiation.

Claims (2)

1. Explosive pack with an inner container (12', 12") which forms a chamber for an inherently non-explosive first component (B) of an explosive, an outer container (14'5 14") surrounding the inner container (12', 12") and projecting above it to form a space above the container (12', 12") to receive a per se non- explosive second component (A) of the explosive, the outer container (14', 14") ending above the inner container (12<*>, 12") in an access opening for the container (14', 14")> a closing device (16, 98) for the access opening, and a perforation device for creating an opening in the inner container (12<*>, 12") and allowing mixing of the two components (A and B) in the outer container (14* > 14") to form the explosive, characterized in that the perforating device includes an elongated handle (90, 106) projecting upwards from the inner container (12', 12") along the inner part of the outer container (14', 14" ) in its length over the inner container (12', 12"), and a perforation part (92, 108) connected to the lower end of the handle (90, 106) and projecting over a part of the inner container (12<* >, 12") and that the outer container (14* > 14") is easily bendable by side-clamping it near the handle (90, 106), so that such clamping can be used to move the handle (90, 106) on the perforating device laterally inwardly causing a downward swinging movement of the perforation portion (92, 108) to create the opening in the inner container (12', 12"). 2. Explosive package according to claim 1, characterized in that it has a relatively rigid sealing sleeve (112) which surrounds at least that part of the outer . container (14") which is brought in to move the perforating device through a portion of the inner container (12"), the packing sleeve (112) serving to prevent unwanted inward movement of the wall of the outer container (14").