GB2044415A - Non-electric delay detonator and assembly of a detonating cord and a delay detonator - Google Patents

Description

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SPECIFICATION

Non-electric delay detonator and assembly of a detonating cord and a delay detonator

The present invention relates to a non-electric delay detonator, and to an assembly of a delay detonator and a low-energy detonating cord adapted to actuate the detonator.

The hazards associated with the use of electrical initiation systems for detonating explosive charges in mining operation, i.e., the hazards of premature initiation by stray or extraneous electricity from such sources as lightning, static, galvanic action, stray currents, radio transmitters, and transmission lines, are well-recognized. For this reason, non-electric initiation through the use of a suitable detonating fuse or cord has been looked upon as a widely respected alternative. A typical high-energy detonating cord has a uniform detonation velocity of about 6000 meters per second and comprises a core of 6 to 10 grams per meter of pentaerythritol tetranitrate (PETN) covered with various combinations of materials such as textiles, ■ waterproofing materials, plastics, etc. However, the magnitude of the noise produced when a cord having such PETN core loadings is detonated on the surface of the earth, as in trunklines, often is unacceptable in blasting operations in developed areas. Also, the brisance (shattering power) of such a cord may be sufficiently high that the detonation impulse can be transmitted laterally to an adjacent section of the cord or to a mass of explosive which, for example, the cord contacts along its length. In the latter situation, the cord cannot be used to initiate an explosive charge in a borehole at the bottom (the "bottomhole priming" technique), as is sometimes desired.

Low-energy detonating cord (LEDC) was developed to overcome the problems of noise and high brisance associated with the above-described 6—10 grams per meter cord. LEDC has an explosive core loading of only about 0.02 to 2 grams per meter of cord length, and often only about 0.4 gram per meter. This cord is characterized by low brisance and the production of little noise, and therefore can be used as a trunkline in cases where noise has to be- kept to a minimum, and as a downline for the bottom hole priming of an explosive charge.

Until recently, most LEDC described in the art has a continuous core of a granular cap-sensitive high explosive such as PETN heavily confined in a metal sheath or one or more woven textile sheaths. An improved LEDC which is light-weight, flexible, strong, and non-conductive, detonates at high velocity, and is readily adapted to high-speed continuous manufacturing techniques is described in Belgian Patent 863,290, granted July 25, 1978, the disclosure of which is incorporated herein by reference. This improved cord has a continuous solid core of a deformable bonded detonating explosive composition comprising a crystalline high explosive compound admixed with a binding agent, and a protective plastic sheath enclosing the core, no metal or woven textile layers being present around the core or sheath. Preferably, one or more continuous strands of reinforcing yarn, e.g., running substantially parallel to the core's longitudinal axis, are present outside the core. The loading of crystalline high explosive in the bonded explosive core is about from 0.1 to 2 grams per meter of length.

Because of the low explosive loading of the LEDC core is insufficient to causo the detonation of explosive charges conventionally used in blasting, auxiliary means are used to relay the detonation stimulus from the cord to the charges to be initiated. Delay detonators, actuated by LEDC downlines, are used for this purpose, providing also a delay interval between the initiation of multiple charges. One such detonator, described in U.S. Patent 3,021,786, has an open-ended metal capsule therein enclosing an air gap and having a central aperture. The air gap is between the end of a length of LEDC and an Exothermic-burning delay composition, the initiating impulse from the detonation of the explosive core of the LEDC jumping the air gap, passing through the aperture, and igniting the exothermic-burning composition. Peripheral crimps in the side wall of the detonator shell hold the cord in place, the latter forming a plug closure at the open end of the shell, so that the cord and detonator are formed into a composite unit or assembly at the time that the detonator is manufactured.

In the cord/detonator assembly described in U.S. Patent 3,122,097, the section of LEDC extending into the detonator shell has a lower looped portion positioned adjacent to the metal capsule that forms the air gap. The looped portion of cord is positioned in the shell by means of a resilient plug which is crimped in place so as to close off the open end of the shell. Here, too, the cord and detonator are formed into a composite unit or assembly at the time that the detonator is manufactured. In this assembly, the looped section of cord is said to provide improved initiation characteristics possibly due to increased confinement of the explosive core of a metal-sheathed LEDC.

In the cord/detonator assembly of U.S. Patent 3,709,149, the cord is disposed outside a closed shell that contains an impact-sensitive ignition composition, held, for example, in an empty primed rim-fired or center-fired rifle cartridge casing used as an end closure for a detonator. The cord is external in its entirety to the closed interior of the detonator shell, and its end or side is in direct and abutting contact with the exterior surface of the primer end, thereby permitting utilization of either the side or end output of the cord for ignition.

Another LEDC-actuated delay detonator is described in Canadian Patent 627,435. This detonator has an impact- or friction-sensitive ignition charge abutting one side of a diaphragm that can be deformed by a weak blow. The end of a length of LEDC is to be crimpejd into the open

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end of the detonator shell with its end abutting the other side of the diaphragm. The ignition of the ignition charge by the detonation of the cord abutting the diaphragm occurs by impact or 5 friction in a manner analogous to the blow given by the firing pin of a shot gun, in contrast to ignition by heat or flame. The diaphragm fits tightly in a pocket, and the latter similarly in the detonator shell. Although this detonator is said to 10 be capable of assembly with the cord in the field by crimping, field assembly of such a detonator presents certain problems. The necessary abutment of the cord end against the diaphragm may not always be achieved in practice in the field 15 owing to the vagaries associated with different handlers, the effects of weather, etc. Also, foreign material could enter the shell prior to insertion of the cord, preventing the necessary cord-to-diaphragm abutting relationship. Dislodgement of 20 the diaphragm-pocket unit also is possibility.

LEDC-actuated delay detonators are also described in U.S. Patent 3,306,201, wherein the ignition composition also is actuated by percussion of the detonation stimulus from the 25 cord against an imperforate partition.

According to one aspect, the present invention provides an improved non-electric delay detonator adapted to be actuated by a low-energy detonating cord, preferably a cord having a core 30 explosive loading of less than about 1 gram per meter of length, which detonator comprises a first tubular metal shell integrally closed at one end, the first shell containing, in sequence from the closed end:

35 (a) a base charge of a detonating explosive composition, e.g., pressed granular pentaerythiritol tetranitsrate (PETN);

(b) a priming charge of a heat-sensitive detonating explosive composition, e.g., lead azide; 40 (c) a delay charge of an exothermic-burning composition, e.g., a boron/red lead mixture;

(d) a tubular rigid metal capsule nested within the first shell and having one open extremity and a closure at the other extremity provided with an

45 axial orifice therethrough, the closure on the capsule being adjacent to the delay charge or to a tubular carrier containing the delay charge;

(e) a second tubular metal shell integrally closed at one end, the second shell being

50 deformable and positioned coaxially within the first shell in a manner such as to produce a spacing between the side walls of the second shell and of the capsule, and between the closed end of the second shell and the closure on the capsule; 55 and

(f) a percussion-sensitive ignition charge, e.g., a granular mixture of red lead, boron, and lead azide, in the spacing between the side walls of the second shell and of the capsule, and between the

60 closed end of the second shell and the closure on the capsule, the ignition charge being in contact with the delay charge by virtue of the orifice in the closure on the capsule;

means being provided for sealing off the charges 65 from the atmosphere and for preventing the venting of gases resulting from the burning of the ignition charge, an open cavity extending from one end to the other of the second shell for receiving a low-energy detonating cord adapted by its detonation to produce a pressure pulse that causes the ignition of the ignition charge, and the cavity being provided with a cord-retention means for holding the cord coaxially therein.

A preferred cord-retention means consists of one or more inwardly directed teeth or prongs formed on the inside wall of the second shell or, preferably, on the inner end of the open-ended metal or plastic sleeve that frictionally engages the inside wall of the second shell.

The detonator is a self-contained, sealed unit adapted to be packaged, stored, and transported apart from the detonating cord which is used to actuate it. At the place of use it can be incorporated into a cord-detonator assembly for initiating a blasting charge wherein an end-section of a length of low-energy detonating cord is held coaxially in the cavity of the second shell by the cord-retention means in a manner such that the plane that passes through the end of the cord within the cavity normal to the cord axis passes preferably also through the ignition charge or, if not, is axially spaced from the plane in which the boundary of the ignition charge lies by a distance no greater that about 2.5 millimeters.

Brief Description of the Drawing

In the accompanying drawing, which illustrates specific embodiments of the non-electric delay detonator, and cord/detonator initiating assembly of the invention,

FIG. 1 is a longitudinal cross-section of a delay detonator of the invention; and

FIG. 2 is a view in partial cross-section of a delay detonator of the invention assembled with a low-energy detonating cord for the actuation thereof.

Detailed Description

Referring to FIG. 1, 7 is a first tubular metal shell having one integrally closed end, 2 is a base charge of a detonating explosive composition, 3 is a priming charge of a heat-sensitive detonating explosive composition,4 is a delay carrier in the form of a heavy-walled tube of rigid material containing an axial core 5 of a delay charge of an exothermic-burning composition, and 6 is a tubular rigid metal capsule nested within shell 1 in snug fit therein, capsule 6 having one open extremity 7, and a closed extremity 8 provided with an axial orifice 9. Closed extremity 8 of capsule 6 rests against adjacent delay carrier 4, core 5 being coaxial and in communication with orifice 9. A second tubular metal shell 10, which is deformable and also integrally closed at one end, is positioned coaxially within shell 7 with its closed end the innermost end in a manner such as to produce a spacing between the side walls of shell 10 and capsule 6, and between the closed end of shell 70 and the closed extremity 8 of capsule 6. A percussion-sensitive ignition charge

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7 7 is located in this spacing. Ignition charge 7 7 is in contact with the delay charge in core 5 by virtue of orifice 9.

A deformable grommet or sleeve 72, e.g., one made of rubber or a plastic such as polyethylene, is sandwiched between shells 7 and 70 starting from their open ends and extending to the open extremity 7 of capsule 6. Open cavity 13, which extends from one end to the other of shell 10, acts as a well for the proper axial positioning of a detonating cord therein for the ignition or ignition charge 7 7. Located in cavity 73 is a cord-retention means in the form of an open-ended metal sleeve 14 that frictionally engages the inside wall of shell 10 and has cord-gripping means 15, i.e., a number of inwardly directed prongs, formed on its inner end. While a cord can be inserted into cavity 13 through prong-ended sleeve 14, the prongs prevent the motion of the cord in the opposite direction when tension is applied thereto. Sleeve 14 extends from the open end of shell 10 to a plane which will place the end of the gripped cord in a plane normal to the axis of shell 10 which is axially spaced from the plane in which the boundary 16 if ignition charge 7 7 lies by a distance no greater than about 2.5 millimeters regardless of how incompletely the cord may be pushed into the cavity.

Preferably, the sleeve places the cord so that the cord end is axially spaced from the bottom of shell 10 by no more than about 5 millimeters.

The outer end of metal sleeve 14 is provided with a lip portion 7 7 that extends over the outer ends of shell 70 and grommet 12. Crimp 78 locks shell 10 in place, keeping it from becoming dislodged by the internal pressure produced when charge 7 7 ignites. Grommet 72 and circumferential crimps 19 and 20 in the side of shell 1 seal charges 2, 3, 5, and 7 7 off from the atmosphere.

Ignition charge 7 7 is one which is sensitive to ignition by a pressure pulse produced by the detonation of a low-energy detonating cord positioned coaxially in cavity 73 in a manner such that it is gripped by prongs 15.

The detonator is a self-contained, sealed unit and can be stored, transported, and otherwise handled as required separated from the detonating cord with which it is designed to be used. At the time of use, the detonator can be assembled with the cord used to actuate it by inserting the cord into cavity 73 of shell 10 until it is gripped by prongs 15 and preferably becomes seated against the closed end of shell 10 as is shown in FIG. 2. Separation of the components of the detonator/cord assembly until use offers such advantages as safety and convenience during handling and storage, possible separate classification of the components for transportation, etc.

In the cord/detonator assembly shown in FIG. 2 an end-section of a length of low-energy detonating cord 2 7 is in coaxial position in cavity 13 of shell 10 and has its end touching the closed end of shell 10. Prongs 15 grip cord 27 and thus prevent it from being pulled out of cavity 7 0. In this embodiment, the plane that passes through the end of cord 2 7 within cavity 10 normal to the cord axis also passes through ignition charge 7 7. Cord 2 7 consists of a continuous solid core 22 of a deformable bonded detonating explosive composition, e.g., superfine PETN admixed with a binding agent such as plasticized nitrocellulose; core-reinforcement means 23 consisting of a mass of filaments derived from multi-filament yarns around and in contact with the periphery of core 22 parallel to the core's longitudinal axis; and a protective platic sheath 24, which encloses core 22 and core-reinforcing filaments 23. Cords of this type are described in the aforementioned Belgian Patent 863,290.

The use of the detonator and the cord/detonator initiating assembly of the invention will now be described by way of an example.

The detonator and cord are those shown in the drawing. Shell 7 is a standard detonator shell, e.g., a shell made of commercial bronze, 42 mm long, and having an external diameter of 7.3 mm and a wall and bottom thickness of 0.3 mm. Base charge 2 consists of 0.49 gram of PETN, which has been placed in shell 7 and pressed therein at 1220—1335 Newtons with a pointed press pin. Priming charge 3 is 0.14 gram of an 85/15 mixture (by weight) of dextrinated lead azide and the corse lead salt of dinitrocresylate, this mixture having been loaded into the shell and pressed at the same pressure as the base charge by a flat pin. Delay carrier 4 is a 7-mm-long swaged lead tube, and delay charge 5 is 0.2 gram of a 2/98 boron/red lead mixture, grained with polysulfide rubber. The diameter of the axial core of carrier 4 is 2 mm.

Capsule 6 is made of commercial bronze, is 11.1 mm long, and has a wall thickness of 0.6 mm. Axial orifice 9 is 2 mm in diameter. Capsule 6 is positioned over carrier 4 and pressed at 1220—1335 Newtons by a flat press pin. Ignition charge 7 7 is 0.08 gram of a 1.5/88.5/10 (by weight) boron/red lead/dextrinated lead azide mixture. Shell 70 is made of aluminum, and has a wall thickness of 0.56 mm, a bottom thickness of 0.64 mm, and an overall length of 19.8 mm. The outer diamete of shell 7 0 is 4.9 mm in a 6-mm-long section starting at the closed end; 5.6 mm in a 5-mm-long section starting at the open end; and 5.4 mm in an intermediate section there-between. Grommet 72, made of low-density polyethylene and having a length of 9 mm, an outer diameter of 6.4 mm, and an inside diameter of 5.4 mm, is fitted onto shell 10 in a manner such that the edge surfaces of shell 10 and grommet 72 at the outer end are substantially coplanar. Bronze sleeve 14 has an overall length of 12 mm, an outer diameter of 4.5 mm, an inner diameter of 4 mm, and a 2.5-tum tapered portion having four cord-gripping prongs 75, which reduce the diameter of the sleeve at the gripping end ot 2 mm. Sleeve 14 is fitted into shell 10 in a manner such that lip portion 7 7 rests over the ends of shell 10 and grommet 72. The assembly of shell 10, grommet

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72, and sleeve 14 is pressed into shell 7 at 222—267 Newtons, thereby compacting ignition charge 11 in the spacing between the closed end of shell 10 and closed extemity 8 of capsule 6, and 5 displaced some of charge 11 into the annular space between the facing walls of shell 10 and capsule 6. Vibrating the assembly upside down also moves ignition charge 11 into the annular space. Charge 11 extends about the length (6 10 mm) of the 4.9-mm outer-diameter section of shell 10, as can be seen by X-ray measurements, or by post-firing observation of shell 7 0. The inner end of grommet 12 rests against the surface of capsuled at the capsule's open extremity 7, and 15 prongs 15 terminate in a plane normal to the longitudinal axis of sleeve 14 that is axially spaced from the plane in which the boundary 16 of ignition charge 11 lies by a distance of about 1.8 mm. In this manner, even if cord 21 were inserted 20 into cavity 13 to the extent that it were gripped by prongs 15 without being pushed to the bottom of the shell, which action, as a practical matter,

would normally cause the cord to extend at least about 3 millimeters beyond prongs 15, leaving a 25 4.8-mm gap between the cord end and the bottom of the shell, a 1.2-mm end-portion of the cord would be adjacent to charge 11, and the actuation of the ignition charge would be assured.

Cord 21 has an outer diameter of 2.5 mm, a 30 0.5-mm-diameter core (22), and a 0.6-mm-thick low-density polyethylene sheath (24). The core 22 consists of a mixture of 75% superfine PETN, 21% acetyl tributyl citrate, and 4% nitrocellulose prepared by the procedure described in U.S. 35 Patent 2,992,087. The average particle size of the superfine PETN is less than 15 microns, with all particles smaller than 44 microns. Core-reinforcing filiaments 23 are derived from eight 1000-denier strands of polyethylene terephthalate 40 yarn substantially uniformly distributed on the periphery of core 22. The PETN loading in core 22 is 0.53 gram per meter.

One end of a 7-meter length of cord 2 7 is inserted into cavity 13 of shell 10 as is described 45 above. When cord 2 7 is detonated at its other end by a No. 6 blasting cap having its end in coaxial abutment with the exposed end of cord 27, or by the detonation transmitted to it from another detonating cord, e.g., in the cord/booster assembly 50 described in our co-pending, British Patent application No. 8002496 the detonator fires, giving a delay period of 40 milliseconds. In operation, the detonation of core 22 causes shell 10 to expand and ignition charge 7 7 to be ignited 55 as a result of being suddenly squeezed between shell 70 and capsule 6. The burning of ignition charge 1 7 ignites delay charge 5, which in turn ignites priming charge 3, causing base charge 2 to detonate.

60 For use in the cord/booster assembly of the aforementioned co-pending application No. 8002496 the free end of cord 2 7 of the cord/detonator assembly of this invention is inserted into the cavity of the booster shell as 65 shown in the drawing of the co-pending application. More specifically, cord 13 shown in FIGS. 2 and 3 of the co-pending application is the same as cord 2 7 of this application. This cord is detonated by the detonation of a booster explosive, which in turn is detonated by a detonating cord positioned transversely outside and adjacent to the closed end of the shell containing the booster explosive.

While the detonator of this invention can be adapted to be actuated by any low-energy detonating cord, it is preferred that cords having a core explosive loading of less than about 1 gram per meter be used for this purpose, inasmuch as it is more difficult with heavier cords to maintain the sealed character of the detonator until after the delay charge has burned, a condition that is required if the predetermined delay timing is to be attained. Also, the type of cord described in the aforementioned Belgian patent is preferred because it would not be desensitized should its cut end come into contact with water, as could occur in field assembly.

The particular compositions selected for the various charges in the detonator are not critical to the present invention, provided that the selected compositions function in the specified manner. Thus, the composition selected to be used as the ignition charge has to be one which is ignitible by percussion, i.e., by the sudden impact of the expanding shell 70 while the charge is held within the rigid capsule 6; reliably propagates the initiation stimulus from the detonating cord to the delay charge 5: and is substantially gasless when it decomposes, to prevent rupture of the surrounding capsule. Preferred ignition compositions consist essentially, by weight, of at least about 86% red lead (lead tetroxide), about from 1 to 2.5% boron, and up to about 11 % lead azide, lead styphnate, or a mixture thereof. Certain of these compositions are described in U.S. Patent 3,306,201, the disclosure of which is incorporated herein by reference. More sensitive ignition compositions may be required in detonators to be used with detonating cords having smaller core loadings than in those used with cords having larger loadings.

The exothermic-burning composition used as the delay charge can be any of the gasless exothermic-reacting mixtures of solid oxidizing and reducing agents that bum at a constant rate and that are commonly used in ventless delay detonators. Examples of such mixtures are boron-red lead, boron-red lead-dibasic lead phosphite, aluminum-cupric oxide, magnesium-barium peroxide-selenium, and silicon-red lead. The delay charge may be present in the bore of a metal carrier, e.g., of lead, as is shown in FIG. 1, or it may be a simple layer adjacent to capsule 6 and the priming charge. The delay period is dependent upon the length or depth of the delay charge as well as its degree of compaction and confinement; and therefore this charge usually will be compacted in a heavy-walled carrier tube.

The priming charge can be any heat-sensitive detonating explosive composition which is readily

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initiated by the burning of the delay composition, e.g., lead azide, mercury fulminate, diazodinitrophenol, or a similar composition.

The composition used for the base charge can be any of the conventional base charges, e.g., PETN, cyclotrimethylenetrinitramine, cyclotetramethylenetetranitramine, lead azide, picryl sulfone, nitromannite, TNT, and the like. This charge can be loose or compacted.

The proper functioning of the detonator of this invention depends on (a) the expansion of shell 70 by the pressure pulse resulting from the detonation of a low-energy detonating cord located in the cavity of shell 70; and, in turn, (b) on the ignition of ignition charge 7 7 as a result of the sudden compression caused by this expansion. The presence of the ignition charge in the annular spacing between the side walls of the expansion shell 10 and the capsule 6 is a means of assuring the ignition of the ignition charge should cord 27 fail to be seated against the closed end of shell 70. To provide this gap capability, i.e., the ability for firing the detonator when there is a spacing between the end of cord 2 7 and the closed end of shell 70, the thickness of the ignition charge (wall spacing) should be at least 0.2 mm.

Conditions which lead to the collapse or rupture of shell 70 when charge 7 7 is ignited are to be avoided, otherwise "the reproducibility of the delay period for a given delay charge may be deleteriously affected owing, for example, to a resulting decrease in internal pressure. Collapse and/or rupture of shell 70 is avoided by selecting a proper combination of shell material and wall thickness, and ignition composition and charge thickness (i.e., thickness of the spacing between the side walls of shell 10 and capsule 6). For a given shell material and wall thickness, the thickness of a given ignition composition can be reduced to assure the integrity of the expansion shell. Alternatively, if a reduction in ignition charge thickness is undesirable, e.g., to maintain gap capability, the wall thickness of the shell adjacent to the ignition charge can be increased (to the extent that shell expansion is not severely compromised) as a preventive measure against shell collapse. The outer diameter of expansion shell 70 is not critical provided that the annular spacing around it is sufficiently large to accommodate the required amount of ignition charge. If a single outer diameter of shell 70 is not suitable to accommodate a given size sleeve 74 and grommet 72, as well as the selected thickness of the annular portion of the ignition charge, the diameter of shell 7 0 can be varied along the length of the shell, as shown in FIG. 1.

Because expansion shell 70 has to be deformable by the pressure pulse produced by the detonation of a low-energy detonating cord, it preferably is made of a metal such as aluminum or brass, and preferably has a wall thickness no greater than about 0.8 mm in the region adjacent to the ignition charge.

As has been mentioned previously, the presence of the ignition charge in the spacing between the walls of the expansion shell 7 0 and the capsule 6 permits the detonator to be fired even when the end of cord 2 7 is not seated against the closed end of shell 70. Because the cord is easily pushed into cavity 13 until it reaches the closed end of shell 70, however, the cord-detonator assembly usually, and preferably, will have the cord end touching the shell end.

In the usual and preferred case, therefore, the plane that passes through the end of the cord within cavity 13 normal to the cord axis passes also through the ignition charge. At least about a 2.5 mm end-portion of the cord preferably will be surrounded by the ignition charge whether the cord end touches to shell bottom or there is a gap between the two. With ignition charge surrounding at least a 2.5 mm end-portion of the cord, the presence of foreign matter such as gritty particles in the gap between the cord end and the expansion shell bottom does not deleteriously affect the functioning of the detonator, a feature which is of great importance in a field-assembled detonator where foriegn matter could enter cavity 13 before cord 27 is inserted.

The detonator will also function properly if there is an axial separation between the cord end and the ignition charge boundary, preferably a separation of no greater than about 2.5 mm.

To overcome the variations possible in the location of the cord end relative to the ignition charge when the detonator and cord are assembled in the field, the position of sleeve 14 controls the proper positioning of the cord. The length of sleeve 7 4 is selected so that the axial distance between the plane normal to the sleeve's axis in which its inner end (prongs 15) lies and the plane in which the boundary 16 of ignition charge 7 7 lies does not permit the axial spacing between the cord end and the charge boundary to exceed about 2.5 mm when the cord is just gripped by prongs 15 without further insertion. For example, if the axial distance between the prong ends and the charge boundary were no greater than about 5.5 mm, and if the cord were to be inserted into cavity 13 only to the extent that it were gripped by the prongs near the. end of the cord without further pushing of the cord into the cavity, which action, practically speaking, would normally cause the cord to extend at least about 3 mm beyond the prongs, it would be impossible for the axial spacing between the cord end and the charge boundary to be more than about 2.5 mm. In the same manner, if the axial distance between the prong ends and the bottom of shell 70 were no greater than about 8 mm, the axial spacing between the cord end and the bottom of shell 10 could not exceed about 5 mm.

Claims (1)

1. A non-electric delay detonator adapted to be actuated by a low-energy detonating cord and comprising a first tubular metal shell integrally closed at one end, said first shell containing, in sequence from the closed end:

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(a) a base charge of a detonating explosive .composition;

(b) a priming charge of a heat-sensitive detonating explosive composition;

5 (c) a delay charge of an exothermic-burning composition;

(d) a tubular rigid metal capsule nested within said first shell and having one open extremity and a closure at the other extremity provided with an

10 axial orifice therethrough, said closure on said capsule being adjacent to said delay charge or to a tubular carrier containing said delay charge;

(e) a second tubular metal shell integrally closed at one end, said second shell being

15 deformable arid positioned coaxially within said first shell in a manner such as to produce a spacing between the side walls of said second shell and of said capsule, and between the closed end of second shell and the closure on said 20 capsule; and

(f) a percussion-sensitive ignition charge in the spacing between the side walls of said second shell of said capsule, and between the closed end of said second shell and said closure on said

25 capsule, said ignition charge being in contact with said delay charge by virtue of the orifice in the closure on said capsule; means being provided for sealing off said charges from the atmosphere and for preventing the venting of gasses resulting from 30 the burning of said ignition charge, an open cavity extending from one end to the other of said second shell for receiving a low-energy detonating cord adapted by its detonation to produce a pressure pulse that causes the ignition of said 35 ignition charge, and said cavity being provided with a cord-retention means for holding said cord coaxially therein.

2. A detonator as claimed in Claim 1 wherein a delay charge carrier comprising a heavy-walled 40 tube of rigid material containing an axial core of said delay charge is interposed between said priming charge and the closed extremity of said rigid metal capsule, said axial core being coaxial and in communication with the orifice in the 45 closure on said capsule to permit contact between said delay charge and said ignition charge.

3. A detonator as claimed in Claim 1 or Claim 2 wherein said cord-retention means is an open-ended sleeve having cord-gripping means

50 associated therewith, said sleeve frictionally engaging the inside wall of said second shell and extending from the open end of said second shell toward the center of said cavity.

4. A detonator as claimed in Claim 3 wherein 55 said cord-gripping means comprises at least one inwardly directed prong formed on the inner end of said sleeve.

5. A detonator as claimed in Claim 3 or Claim 4 wherein the inner end of said sleeve lies in a plane

60 normal to the axis thereof that also passes through said ignition charge, or, if not, is spaced from the plane in which the boundary of said ignition charge lies by a distance no greater than about 5.5 millimeters.

65 6. A detonator as claimed in Claim 5 wherein the inner end of said sleeve lies in a plane normal to the axis thereof that is spaced from the bottom of said second shell by a distance no greater than about 8 millimeters.

7. A detonator as claimed in any one of claims 3 to 6 wherein said sleeve is made of metal and, at its outer end, is provided with a lip portion that extends over the end of said second shell or over a conforming lip portion on the end of said second shell.

8. A detonator as claimed in any one of the preceeding claims wherein a deformable grommet is sandwiched between said first and second shells starting from their open ends and extending approximately to the open extremity of said capsule, said shells and grommet being held together by one or more circumferential side crimps.

9. A detonator as claimed in any one of the preceeding claims wherein said ignition charge is a pressed granular mixture comprising, by weight, at least about 86% red lead; from about 1 to 2.5% boron; and up to about 11 % lead azide, lead styphnate, or a mixture othereof.

10. A non-electric assembly for initiating a blasting charge comprising a first tubular metal shell integrally closed at one end, said first shell containing, in sequence from the closed end;

(a) a base charge of a detonating explosive composition;

(b) a priming charge of a heat-sensitive detonating explosive composition;

(c) a delay charge of a exothermic-burning composition;

(d) a tubular rigid metal capsule nested within said first shell and having one open extremity and a closure at the other extremity provided with an axial orifice therethrough, the closure on said capsule being adjacent to said delay charge or to a tubular carrier containing said delay charge:

(e) a second tubular metal shell integrally closed at one end, said second shell being deformable and positioned coaxially within said first shell in a manner such as to produce a spacing between the side walls of said second shell and of said capsule, and between the closed end of said second shell and the closure on said capsule; ~~

(f) a percussion-sensitive ignition charge in the spacing between the side walls of said second shell and of said capsule, and between the closed end of said second shell and said closure on said capsule, said ignition charge being in contact with said delay charge by virtue of the orifice in the closure of said capsule; means being provided for sealing off said charges from the atmosphere and for preventing the venting of gases resulting from the burning of said ignition charge, an open cavity extending from one end to the other of said second shell;

(g) an end-section of a length of low-energy detonating cord in the cavity of said second shell; and

(h) cord-retention means in said cavity for holding said cord in coaxial position therein in a

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manner such that the plane that passes through the end of the cord within said cavity normal to the cord axis also passes through said ignition charge or if not, is spaced from the plane in which 5 the boundary of said ignition charge lies by a distance no greater than about 2.5 millimeters.

11. An assembly as claimed in Claim 10 wherein said detonating cord has an explosive core loading of from about 0.2 to 1 gram per

10 meter of length.

12. An assembly as claimed in Claim 10 or Claim 11 wherein said low-energy detonating cord comprises a continuous solid core of a deformable bonded detonating explosive

15 composition comprising a crystalline high explosive compound admixed with a binding agent, and a protective plastic sheath enclosing ■ said core.

13. An assembly as claimed in any one of

20 Claims 10 to 12 wherein said cord-retention means holds said cord in a manner such that the plane that passes through the end of the cord also passes through said ignition charge.

14. An assembly as claimed in Claim 13

25 wherein the end of said cord is seated against the closed end of said second shell.

15. An assembly as claimed in any one of Claims 10 to 14 wherein said cord-retention means is an open-ended sleeve having cord-

30 gripping means associated therewith, said sleeve frictionally engaging the inside wall of said second shell and extending from the open end of said second shell toward the center of said cavity.

16. An assembly as claimed in Claim 15

35 wherein said cord-gripping means comprises at least one inwardly directed prong formed on the inner end of said sleeve.

17. An assembly as claimed in Claim 15 or 16 wherein the inner end of said sleeve lies in a plane 40 normal to the axis thereof that also passes through said ignition charge or, if not, is spaced from the plane in which the boundary of said ignition charge lies by a distance no greater than about 5.5 millimeters.

45 18. An assembly as claimed in any one of Claims 15 to 17 wherein the inner end of said sleeve lies in a plane normal to the axis thereof that is spaced from the bottom of second shell by a distance no greater than about 8 millimeters. 50 19. A non-electric delay detonator adapted to be actuated by a low-energy detonating cord, said detonator including a body containing a base charge and a priming charge in close proximity thereto and an ignition charge communicating 55 with the priming charge via a delay charge, said detonator body housing an expansion shell which has an opening for admitting a free end of a low-energy detonating cord, the ignition charge being present in an annular space between the 60 expansion shell and the detonator body and the expansion shell including cord-receiving means which is positioned with respect to the ignition charge in said annular spaced so as to assure actuation of the ignition charge whether or not the 65 cord is shoved to the bottom of the expansion shell or not.

20. A non-electric delay detonator substantially as described with reference to Fig. 1 of the accompanying drawings.

70 21. A non-electric assembly for initiating a blasting charge substantially as described with reference to Fig. 2 of the accompanying drawings.

Printed for Her Majesty's Stationery Office by the Courier Press, Leamington Spa, 1980. Published by the Patent Office, 25 Southampton Buildings, London, WC2A1 AY, from which copies may be obtained.