This invention relates to a wireless detonator assembly.
A wireless detonator assembly installed in a borehole, once rendered operative by means of an arm command which is sent wirelessly, is initiated upon receipt of a fire command, also sent wirelessly. It is essential, as far as is possible, to eliminate the possibility that initiation can take place inadvertently e.g. due to receipt of a stray signal.
An object of the present invention is to address at least to some extent the aforementioned aspect.
The invention provides a wireless detonator assembly which includes a receiver, a memory unit, a power source, control logic, a detonator and explosive material which is initiated, after receipt of an arm command, upon receipt by the receiver of a fire command, wherein the memory unit includes a printed circuit board with a stored key which is hardwired during manufacture of the receiver and wherein the control logic allows initiation of the detonator after receipt of the fire command if a received reference key, extracted from the arm command, is the same as the stored key.
The arm command may be sent by a control device to the receiver.
If the received reference key equals the stored key then the control logic, using energy drawn from the power source, enables a fire voltage to be generated. As is known in the art the fire voltage may be used to charge a capacitor which, upon execution of the fire command, under the control of the control logic, is discharged to initiate the detonator.
The invention is further described by way of example with reference to the accompanying drawings wherein:
The blast site 12 includes a plurality of boreholes 20 which are formed in a known manner. Each borehole 20 is loaded with explosive 22 and at least one wireless detonator assembly 16.
The control device 14 includes at least one of the following, viz: a surface blast control unit 23, an underground blast control unit 24 and a near field communication card 26. The control device 14 further includes an encoder 28 and a transmitter 30.
The wireless detonator assembly 16 is typically used in an underground location and, in that event, the blast site 12 is a blast zone in an underground excavation. Primary benefits of using a wireless detonating arrangement are that there are no trailing wires or conductors leading to the detonators in the various boreholes, and generally the number of personnel required at the blast site is reduced. Thus there is enhanced reliability and safety in operation.
The transmitter 30 can operate at a radio frequency or it can transmit magnetic signals through the ground. The transmitter 30 has an antenna 34 which is configured accordingly. These types of transmission techniques are known in the art and for this reason are not further described.
The wireless detonator assemblies 16 are substantially identical to one another. Each assembly 16 includes a first part 16A and a second part 16B. These parts are interconnected to one another at an assembly location, not shown, at the blast site 12—a process which takes place immediately before placement of the detonator assemblies into the respective boreholes.
The first part 16A includes a housing 34 which contains or to which is mounted an antenna 36, a receiver 38, a memory unit 40, a logic module 42 and a power supply 44.
The second part 16B includes a housing 50 into which is loaded an explosive material 52.
When the first part 16A is connected to the second part 16B a detonator 56 is connected to terminals on the logic module 42 and is exposed to the explosive material 52. An advantage of this technique is that the part 16A is separate from the explosive 52, and the detonator 56 is separated from the explosive 52. Thus the likelihood of inadvertent initiation taking place is negligible.
The receiver 38 includes a printed circuit board 64 (see
The key 70 which is hardwired into the printed circuit boards 64 of the various receivers 38 is stored as a reference key in the control device 14 i.e. in the surface blast control unit 23 or in the underground blast control unit 24 or otherwise is carried on a proprietary near field communication card 26. Any of these approaches can be used: the choice thereof depends on the system adopted at the blasting site.
When the detonator assemblies 16 at the blast site 12 are to be armed the reference key 70 which is available from one of the units 23 or 24 or from the NFC card 26 is encoded by the encoder 28 and is then transmitted in a signal 74 via the transmitter 30 simultaneously to the wireless detonator assemblies 16 in the various boreholes 20.
As is shown in
The use of the hardwired key 70 on the printed circuit board 64 of each detonator assembly 16 means that firing of a detonator 56 can only take place if the identical key (the reference key) is available from the control device 14 i.e. from one of the mechanisms 23, 24 or 26, according to requirement.
Number | Date | Country | Kind |
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NA/P/2020/0010 | Apr 2020 | NA | national |
Filing Document | Filing Date | Country | Kind |
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PCT/ZA2021/050006 | 2/2/2021 | WO |