DE3533389A1 - Electronic explosive time fuze - Google Patents

Abstract

A capacitor (19) and a carrier board (23) are arranged one behind the other in a tubular sleeve (10). The carrier board (23) carries an integrated circuit (24) which (?) lead with a contact panel (17), for connection to the fuze wires (13), via conductor tracks (25) or wires which are guided along the side of the capacitor (19). A programming panel (32) consisting of conductor strips (32a to 32f) which can be cut through is provided on the carrier board (23), on which programming board (32) different delay times can be set by deliberately cutting through individual conductor strips. <IMAGE>

Description

Electronic time detonator

The invention relates to an electronic detonator with a by impulses of a blasting machine chargeable capacitor, one of the impulses of the Blasting machine for setting an integrated circuit utilizing the delay time, which controls the expiry of the delay time after setting, one when it expires the delay time with current charged primer and with fuse wires to Connect the blasting machine to the integrated circuit.

It is known to replace the one commonly used in explosives.

Time detonators used an electronic pyrotechnic delay charge Use circuit that takes over the delay function. The electronic Time delay is considerably more precise and is subject to lower specimen variations than the pyrotechnic delay. Thus explosive charges to increase the explosive effect Detonated at different times it is necessary to equip the explosive charges with detonators with different delay times cause. For this purpose, both the detonator detonators with a pyrotechnic delay as well as those with electronic delays already in their manufacture set up so that the previous delay time or an intended delay time stage arises. However, this requires a large number of different ones Detonator detonators differentiating their delay times from one another. The size The variety of types requires high manufacturing and storage costs.

The well-known electronic detonators differ from the pyrotechnic detonators in that they have a larger volume and require a large amount of space and that their production complex and expensive is.

The invention is based on the object of an electronic time detonator to create the type mentioned, despite the high packing density of its components allows a simple connection technology, is mechanically insensitive and a has high functional reliability.

The solution to this problem is that a The carrier plate carrying the integrated circuit and having electrical conductor tracks and the capacitor are housed one behind the other in a tubular sleeve, that the carrier plate has a first connection field with soldering points for fastening the legs of the capacitor and that on the support plate or on an additional plate part a second connection field with soldering points for fastening the detonator wires leading out of the sleeve is provided.

In the detonator according to the invention, all circuit components are with the exception of the capacitor, housed in a chip that is on the carrier plate is attached. The carrier plate and the capacitor are in a tubular shape Housed sleeve, which can have the same shape and dimensions like the cases of pyrotechnic detonators.

The carrier plate on which the integrated circuit is attached, contains conductor tracks to which the connection points of the integrated circuit are bonded are. At.

this support plate then becomes the legs of the capacitor soldered on, with capacitor and carrier plate aligned along a common axis are.

The capacitor is therefore attached to one end of the carrier plate. Soldering on both the electrical and the mechanical Fixing between carrier plate and capacitor causes. The carrier plate forms together with the capacitor a narrow, elongated assembly that forms the shape the narrow sleeve is largely adapted. This creates a compact, narrow one Construction. The capacitor is with its legs, which can be short in length, soldered to the conductor tracks of the carrier plate. The capacitor is in relation to that Support plate not upright, but arranged lying down, with the legs run parallel to the carrier plate. This allows relatively long soldered connections produce, with the consequence of a high strength of the soldered connection and a high level of security against shocks and vibrations.

According to a preferred development of the invention, it is provided that a plate part carrying the second connection field over at least one side is connected to the support plate on the web leading along the capacitor. Of the The web can have at least one conductor track, one end of which leads to a soldering point the second connection field leads and the other end by bonding with the integrated Circuit is connected. In this variant there is a single plate-shaped circuit carrier present, which consists of the carrier plate and the plate part and on which both Connection fields are provided. The bridge bridges the length of the capacitor and should be as narrow as possible.

In an alternative variant of the invention, this is the second connection Field-bearing plate part arranged separately from the carrier plate and the soldering points the second connection field are via wires that run along the side of the capacitor with connected to the integrated circuit. In this variant, the length of the capacitor bridged by thin wires, so that the diameter of the capacitor is almost so can be made large as the inner diameter of the sleeve.

According to a preferred embodiment of the invention is on the Printed circuit board a programming field formed from conductor tracks, which is used for setting selectable delay times can be changed by external influences is. Such a programming field enables numerous delay times to use the same circuit and just before assembling the detonator change the desired delay time by acting on the programming field. The programming field can, for example, consist of a matrix arrangement of conductor tracks exist that can be connected or disconnected by bridges to create different ones generate electrical bit patterns that determine the delay time. Explosive detonator with different delay times differ only by their corresponding modified programming fields. An intervention in the interior of the integrated circuit not necessary.

The conductor tracks of the programming field are preferably integrated with the Circuit connected so that the delay time by interrupting one of these Conductor tracks or a combination of these conductor tracks is changeable. The conductor tracks are initially attached to the carrier plate in an undamaged state and they can by mechanical action or e.g.

interrupted by means of laser beam cutting.

The invention also offers the possibility of usually used separately to dispense with prefabricated detonators by attaching to the carrier plate a squib is generated. For this purpose, a glow wire is used directly with connection points connected to the carrier plate.

In the following, with reference to the drawings, exemplary embodiments the invention explained in more detail.

1 shows a longitudinal section through an electronic detonator, Fig. 2 is a section through the electronic detonator at right angles to the Section of Fig. 1, Fig. 3 on an enlarged scale a representation of the detail III from FIG. 1, FIG. 4 an alternative embodiment of the squib, and FIG. 5 a block diagram of the essential components in the integrated circuit are included.

The one in FIGS. 1 to 3 shown detonator has an elongated Housing in the form of a cylindrical tubular sleeve 10 made of metal, e.g. B. made of copper. The sleeve 10 is closed at the front end 11 and they has at its rear end an opening 12 through which two detonator wires 13 from the outside into the inside of the sleeve. The fuse wires 13 are on one Part of their Length enclosed by a plug 14 made of plastic, which is fixed at the rear end of the sleeve 10 by indentations 15 of the sleeve jacket is. The detonator wires 13 are each provided with an insulating jacket and only theirs front ends 13 'are stripped. The ends protruding from the plug 14 13 'are at the mutually insulated soldering points 16a, 16b of the connection field 17 soldered on. The connection field 17 consists of conductor tracks that are located on the surface a plate part 18 extend.

In front of the plate part 18 in the sleeve 10 is the cylindrical capacitor 19 arranged, which almost fills the cross section of the sleeve 10. The legs 20 of the Capacitor 19 protrude from its front face.

Each of the legs 20 is at a soldering point 21a or 21b of a connection field 22 soldered on. These solder points consist of conductor tracks that are on the carrier plate 23 are arranged. The carrier plate 23 extends diametrically in the sleeve 10. It consists of epoxy resin, ceramic material or some other non-conductor.

On the rigid support plate 23, the integrated circuit 24 is in Form of a silicon chip attached by gluing. The connection points of the chip are with thin wires 26 connected to the corresponding conductor tracks 25 by bonding. Further conductor tracks, which also have contact with the integrated circuit 24, lead to connection points 27a, 27b, which at the front end of the carrier plate 23 are provided. At these connection points 27a, 27b, the legs are a Squib 28 soldered on, which is free into a cavity beyond the front end of the carrier plate 29 of the sleeve 10 protrudes into it. In the front end of the sleeve 10 or

The initial charge 30 is housed in the case head, which is released when it burns down the squib 28 is ignited and the surrounding (not shown) explosives detonates.

In the present embodiment, the plate part 18 is over two longitudinal webs 31a, 31b connected to the carrier plate 23 so that it is with the carrier plate forms an integral part. Conductor tracks lead on the webs 31a, 31b that connect the solder points 16a, 16b to the integrated circuit 24. The webs 31a, 31b enclose a recess 23 'in which the capacitor 19 is arranged is. Alternatively, there is the option of just a single bar on one side of the capacitor 19 to be used, so that the recess 23 'to one side is open. In this case, the connected to the soldering points 16a, 16b Conductor tracks expediently on opposite sides of the single web be arranged, wherein in the region of the carrier plate 23 is a through-hole must be provided through the support plate to the at the bottom of the Conductor track located on the carrier plate with the chip arranged on the top to be able to connect.

In another variant (not shown) is the plate part 18 completely separated from the carrier plate 23, so that no webs 31a, 31b provided are seen. The connection of the soldering points 16a, 16b with the corresponding conductor tracks of the carrier plate 23 then takes place via insulated Wires that run along the side of the capacitor 19.

On the carrier plate 23 is a programming field consisting of conductor tracks 32 arranged, which in the present embodiment consists of six conductor strips 32a to 32f, which are "connected to one another" at one of their ends and at ground potential are laid, while the other ends are connected to the chip by bonding wires C 26 integrated circuit 24 are connected. Each individual conductor strip 32a to 32f can be with a mechanical separator or with a sharply focused Laserstral are severed, so that the connection of the relevant connection point the electronic circuit with bias potential is canceled if a severing occurs of the ladder strip is done.

In Fig. 4, the squib 28'l consists of a filament 33, which is between two connection points 34a, 34b extends at the front end of the support plate 23 and bridged a recess 35 of the carrier plate. The recesses 36 serve to guide the glow wire while soldering the filament to the connection points.

In Fig. 5 are the essential components of the integrated circuit 24, along with the capacitor connected to this circuit 19 and the conductor strips 32a to 32f, which are on the carrier plate 23 appropriate are.

An input line 37 connected to one of the detonator wires 13 is applied with pulses from an external ignition machine (not shown). These pulses are fed to the capacitor 19 via a rectifier arrangement 38, to charge it. The capacitor 19 then supplies a voltage potential to supply the other components and finally also for the power of the squib 28. The pulses on input line 37 are fed to a six-stage input counter 39, which is designed as a binary counter and can count from 0 to 63. The six output lines of the input counter 39 become one input of one Equivalence gate 40 supplied. The other input of the equivalence gate 40, the also has six places, is connected to the six conductor strips 32a to 32f, the other ends of which are at ground potential. If at one point of the other entrance of the equivalence gate is ground potential, this means a logical "0" signal and when the conductor strip is interrupted, this means a "1" signal.

The output of the equivalent gate 40 is one with the stop input Reference counter 41 connected.

This reference counter 41 is designed as an up / down counter. It counts up the impulses appearing at its counter input C, if at the Forward control input V has a forward signal and it counts the Pulses of the counting input C backwards, if there is a downward signal at the downward input R. pending. The forward signal is supplied by the input counter 39, as long as it The count is in the range from 0 to 63. The countdown signal is from the Input counter 39 supplied when its counter status overflows. The count input C of the reference counter 41 is connected to an oscillator 42.

The output of the reference counter 41 is via a logic circuit 43, which detects the count "0,0,0 ... 0", connected to an electronic switch 44, which is closed as soon as the count of the reference counter 41 reaches the value 0 Has. When the blasting machine delivers 37 pulses on input line, the input counter becomes 39 counted up from the value 0.

If there is coincidence between the two inputs of the equivalence gate 40 exists, the equivalence gate delivers a pulse to the stop input S of the reference counter 41. This reference counter counts from 0 until the stop signal appears Pulses of the oscillator high and keeps those present when the stop signal arrives Fixed count value until a downward signal appears at its input R.

This downward signal is delivered after the count of the Input counter has reached the value 64. The reference counter 41 now counts from that count value contained in it from downwards and when it has reached the value 0, will The electronic switch 44 is closed via the loop circuit 43, so that the Primer is powered.

At the programming field 32 can be interrupted by one or more Conductor strips 32a to 32f can be set to any value between 0 and 63. if the conductor strip 32a is interrupted, the stop signal for the reference counter 41 already generated with the first pulse that the input counter 39 receives.

If, on the other hand, only the conductor strip 32f is interrupted, then that is Stop signal generated as soon as the input counter 39 has received the 32nd pulse. In this way, that counter reading of the reference counter can be displayed on the programming field 32 41, which is the upper limit of the charging (counting up) of the Reference counter 41 forms. This charging of the reference counter represents a measure for represents the time it takes to count down the reference counter to zero is, so the delay time.

In practice, numerous detonators are used on a single detonator connected, which are programmed for different delay times and all of which have the same pulses applied to their input lines 37. The reference counters of the detonators are charged according to the individual Programming different levels. After the blasting machine a certain Number of pulses (here: 64 pulses), the reference counter is charged all detonator detonators terminated and r then the down counting follows, where then the zero levels of the reference counters are reached at different times will.

Claims (9)

Claims 1. Electronic time detonator with a pulse a blasting machine chargeable capacitor (19), one the pulses of the blasting machine for setting an integrated circuit (24) utilizing the delay time, which expires after the delay time has been set controls, a squib that is energized when the delay time has elapsed (28, 28 ') and detonator wires (13) for connecting the blasting machine to the integrated Circuit, d a d u r c h characterized that the integrated circuit (24) supporting, electrical conductor tracks (25) having carrier plate (23) and the capacitor (19) are housed one behind the other in a tubular sleeve (10) that the Carrier plate (23) has a first connection field (22) with soldering points (21a, 21b) for attachment the legs (20) of the capacitor (19) and that on the support plate or on an additional plate part (18) a second connection field (17) with soldering points (16a, 16b) are provided for fastening the igniter wires (13) leading out of the sleeve is. 2. Explosive detonator according to claim 1, characterized in that the The capacitor (19) is arranged essentially coaxially in the sleeve (10) and the Support plate t (23) - seen in the sleeve cross-section - essentially on the entire inner width of the sleeve extends. 3. Detonator according to claim 1 or 2, characterized in that that the second connection field (17) carrying plate part (18) over at least a web (31a, 31b) with the carrier plate, which runs along the side of the capacitor (19) (23) is connected. 4. time detonator according to claim 3, characterized in that the Web (31a, 31b) has at least one conductor track (25), one end of which becomes a Soldering point (16a, 16b) of the second connection field (17) and the other end thereof is connected by bonding to the integrated circuit (24). 5. Detonator according to claim 1 or 2, characterized in that the plate part (18) carrying the second connection field (17) from the carrier plate (23) is arranged separately, and that the soldering points (16a, 16b) of the second connection field (17) via wires that run along the side of the capacitor (19) with the integrated Circuit (23) are connected. 6. time detonator according to one of claims 1 to 5, characterized in that that on the carrier plate (23) a programming field (32) made of conductor strips (32a to 32b) is formed, the setting of selectable delay times by external Influence is changeable. 7. time detonator according to claim 6, characterized in that the Conductor strips (32a to 32f) of the Programming field (32) with the integrated circuit (24) are connected so that the delay time by Interrupt one of the conductor strips or a combination of these conductor strips is changeable. 8. time detonator according to one of claims 1 to 7, characterized in that that the carrier plate (23) has conductor tracks (25) on both of its sides, and that at least one point a via of a conductor track one side to a conductor path on the other side is present. 9. time detonator according to one of claims 1 to 8 ,. characterized in that the squib (28 ') has a glow wire (33) has, the ends of which directly with connection points (34a, 34b) of the carrier plate (23) are connected.