RU2066829C1 - Detonator - Google Patents

Abstract

FIELD: means for initiation at blasting and intended for intensifying the transmission of initiating signal from various electric and non-electric sources. SUBSTANCE: detonator is made in the form of a tubular housing with a bottom on one end and open end face on the other for placing of the device for transmission of actuating signal. The bottom of the housing carries an explosive charge and a buffer element engageable with it and made in the form of a disc with an interference fit. The buffer element can have at least one opening and be provided with a membrane or net. Besides, the detonator can be furnished with a delay unit in the form of a bush retarding compound installed between the signal transmitting device and buffer element. EFFECT: enhanced reliability. 5 cl, 9 dwg

Description

 The invention relates to the field of initiating means, namely to detonators used in blasting operations, and triggered both by an electric pulse and by a non-electric one, and by the response time, both instantaneous and delayed.

 Known detonators containing a hollow tubular body with a solid bottom, equipped with a charge of explosives (VV). A device transmitting a response signal, for example, according to US Pat. No. 3,776,135 of December 4, 73, is located in the open end of the housing. However, the problems of reliability of operation, as well as safety both in manufacturing and in service, were not completely solved in this design.

 In US patent N 3885499 dated 05/27/75 g, selected as the closest analogue, these problems are partially resolved. The detonator according to this patent contains a hollow tubular body with a continuous bottom at one end, an explosive charge, pressed at the bottom of the body and a signal transmission device for triggering at the open end. At the same time, this detonator did not provide complete safety both during charge pressing and during transportation with vibration inevitable for it. The inevitable charge loosening and even the formation of small free particles of explosive chips can lead to their activation both from friction and from the effects of electrostatic charges.

 The challenge facing this invention is to create an improved design of the detonator, providing both increased reliability of its actions, and safety during assembly and during transportation.

 The essence of the invention lies in the fact that the detonator is equipped with a buffer element made in the form of a disk and installed in the housing with an interference fit until it is in direct contact with the charge B. V. The detonator can be equipped with a delay unit made in the form of a sleeve with a delayed composition installed between the device, signal transmission for operation and buffer element. In addition, the buffer element can be made with at least one hole for transmitting the signal, and the buffer element can be equipped with a membrane or mesh that transmits the initiating element. The diameter of the buffer element exceeds the diameter of the channel of the housing.

 The illustrations below show both the various versions of this detonator and its parts.

 In FIG. 1 and FIG. 2 shows detonators triggered by a non-electric signal, but in FIG. 1 is a longitudinal section through an instant detonator, and FIG. 2 slow motion.

 In FIG. 3 is a longitudinal section through an instantaneous electric detonator.

 In FIG. 4 shows a buffer element in a cross section of a detonator along a plane 4-4.

 In FIG. 5 shows a longitudinal section thereof.

 In FIG. 6 shows a buffer element covered by a grid, and in FIG. 7 is a longitudinal section thereof.

 In FIG. 8 a buffer element closed by a diaphragm, and in FIG. 9 its longitudinal section.

 The instantaneous detonator of FIG. 1 comprises a hollow tubular body 1 made with a bottom at one end and with a central channel in the sleeve with walls 2 having an open end into which the device for transmitting a non-electric signal for actuation 3 is inserted, the walls of the sleeve 2 are in direct contact with the buffer element 4, which in turn, adjoins the explosive explosive charge, consisting of the main charge 5 and the initiating charge 6.

 In FIG. 2 shows a delayed detonator, and therefore, between the sleeve 2 and the buffer element 4 in the housing 1 is placed a sleeve with a retarding composition 7.

 In FIG. 3 shows an instantaneous detonator operating from an electrical impulse. The principle of operation of the electric initiator may be different, but in FIG. 3 shows the glow bridge 8, recessed in the additional initiating charge 9.

 The buffer element 4 (in FIGS. 4 and 5) embodying the principle of the present invention fits snugly against the explosive charge (5 and 6) and thereby holds the explosive material in a compressed state. Preferably, the buffer element is made of easily deformable shock absorbing material, such as cardboard, polyethylene, rubber, etc. For reliable transmission of the initiating signal, the buffer element is made with at least one hole (pos. 5 in Fig. 4), the dimensions of which guarantee the passage of the signal. On the other hand, the hole 5 cannot be very large, otherwise the buffer element 4 will not fulfill its function of preserving the explosive charge integrity (5 and 6).

 The central hole 5 of the buffer element 4 can be covered with a grid 6, as shown in FIG. 6 and 7, or a thin membrane 7, as can be seen in FIG. 8 and 9. But both the grid 6 and the membrane 7 should not impede the passage of the initiating signal, guaranteeing the reliability of the detonator.

 The detonator operates as follows.

 With the passage of an initiating pulse, electric or non-electric in nature, it passes through the buffer element, penetrates through the grid or membrane, if installed, and triggers the initiating 6 and the main explosive charge 7. But the presence of the buffer element sharply increases the protection of the detonator from external forces, for example, from the action of a shock wave from detonation in an adjacent cord.

 Thus, the shock resistance of detonators with buffer elements is three times higher than the shock resistance of similar detonators without a buffer element. Impact security is especially great, i.e. safety of the detonator which uses a buffer element with a membrane.

Claims (5)

 1. A detonator comprising a hollow tubular body with a continuous bottom at one end and with an open end at the other end, an explosive charge placed at the bottom of the body, and a signal transmission device for operating at the open end, characterized in that it is equipped with a buffer element, made in the form of a disk and installed in the housing with an interference fit until it is in direct contact with the explosive charge.  2. The detonator according to claim 1, characterized in that it is equipped with a delay unit, made in the form of a sleeve with a delayed composition, installed between the device for transmitting a signal for actuation and the buffer element.  3. The detonator according to paragraphs. 1 and 2, characterized in that the buffer element for transmitting the initiating signal is made with at least one hole providing transmission of this signal.  4. The detonator according to claims 1 to 3, characterized in that the buffer element is equipped with a membrane or mesh that transmits the initiating signal.  5. The detonator according to claims 1 to 4, characterized in that the diameter of the buffer element exceeds the diameter of the channel of the housing.

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