This invention relates to a detonator assembly. The invention is described hereinafter with reference to the use of a detonator assembly in a unidirectional wireless through-the-earth initiation blasting system but this is exemplary and non-limiting.
In a blasting system of the aforementioned kind magnetic signals are transmitted from a control centre via a loop antenna which is positioned around a blast site. A number of boreholes are formed at the blast site and each borehole contains one or more detonator assemblies. Communication is unidirectional i.e. only from the control centre to each detonator assembly. Typically each detonator assembly does not have sufficient on-board energy to transmit a return signal though the earth to the control centre. It is however essential to ensure that each detonator assembly reliably receives magnetic signals from the control centre and is responsive thereto.
An object of the invention is to provide a detonator assembly which, at least in some deployment situations, enables the functioning of the detonator assembly to be monitored.
The invention provides a detonator assembly which includes a detonator arrangement comprising a detonator, a receiver which is responsive to a magnetic signal from a control centre and a control circuit which, in response to a signal from the receiver, regulates firing of the detonator, and which is characterised in that a fibre optic cable is connected to and extends from the detonator arrangement, and in that the detonator arrangement includes a transmitter/receiver module which is in signal communication with the fibre optic cable and the control circuit.
In the detonator arrangement the principal operations thereof are regulated by means of magnetic signals received by the receiver and transferred to the control circuit.
Status signals relating to the detonator arrangement, e.g. notification of sleep or arm modes, can be transmitted via the fibre optic cable to a remote end thereof. Conversely, predetermined signals which may be of an interrogating or command nature, can be transmitted via the fibre optic cable to the transmitter/receiver module for processing by the control circuit. Such predetermined signals exclude all signals which could lead to firing of the detonator.
Under dark conditions, e.g. if the detonator arrangement is used in an underground situation, light which is emitted from an end of the fibre optic cable which is remote from the detonator arrangement is visible. That light enables the position of a detonator arrangement to be ascertained and also indicates that a detonator assembly has been deployed in the respective blast hole.
The invention also provides a method of operating a detonator assembly which includes a detonator arrangement and a fibre optic cable which at one end is connected to the detonator arrangement and which, at an opposing end, forms a communication interface, wherein the method includes the steps of deploying the detonator arrangement (28) in a borehole whereby the fibre optic cable which extends in the borehole from the detonator arrangement and the communication interface is located at a mouth of the borehole, engaging in two-way communication with the detonator arrangement via the communication interface and, when required, of transmitting a fire command to the detonator arrangement using a through-the-earth magnetic signal from a control centre.
The invention is further described by way of example with reference to the accompanying drawings in which:
Each detonator assembly 26 (see
Positioned inside or attached to the housing 30 are a transmitter/receiver module 44, a receiver 46, a control circuit 48, a power source 50 and a detonator 52. An explosive material 54 inside the borehole 12 is exposed to the detonator 52, as is known in the art.
The module 44 is directly connected to an end of the fibre optic cable 32 and is capable of receiving signals transmitted at light frequency via the cable 32. In the return direction the module 44 can transmit signals at light frequency, which signals are generated by the control circuit 48, to the communication interface 42. Signals from the module 44 are emitted at a visible light frequency by the communication interface 42 and, conversely, light signals which are incident on the interface 42 are transmitted via the cable 32 to the transmitter/receiver 44. Thus, through the use of a transmitter/receiver (not shown) which preferably is mobile and carried by an operator, two-way communication with the control circuit 48 is possible.
The receiver 46 is responsive to magnetic signals which are transmitted from the control centre 24 via the loop antenna 16. The control circuit 48, in response to arm and fire signals from the control centre 24, can cause the detonator 52 to initiate and fire the explosive 54. This aspect is conventional.
Operation of the detonator assembly 26 is powered by means of energy drawn from the power source 50.
The detonator assemblies 26 are deployed in the various boreholes 12 in a conventional manner. Each detonator arrangement 28 is suspended from the respective support line 34.
In general terms the firing aspect of the system is unidirectional in that essential control and operational instructions are transmitted from the transmitter 18 to each of the detonator arrangements 28 by means of magnetic signals, typically through the earth. The receiver 46 in each detonator arrangement detects such magnetic signals and, as is known in the art, the control circuit 48, in response to the detected magnetic signals, controls arming and firing operation of the detonator 52.
Although each detonator arrangement 28 includes a power source 50 to enable the arrangement to function, the power output of the source 50 is not adequate to enable communication from the detonator arrangement to the control centre 24 to take place via through-the-earth transmission. The use of the fibre optic cable 32 does however allow a degree of limited two-way communication to take place with the detonator arrangement. A mobile interrogating unit, not shown, carried for example by an operator, can be coupled to the communication interface 42 and signals can be transmitted via the cable 32 to the transmitter/receiver module 44. The signals are processed by the control circuit 48 and return signals are transmitted from the transmitter/receiver module 44 via the cable 32 to the interface 42, at which point the signals, at light frequency, are detected by the interrogating unit.
Through the use of the fibre optic cable 32 a technician at a mouth 43 of the borehole can access the interface 42 and communicate to a limited extent, in a bidirectional manner, with the control circuit 48 in the detonator arrangement 28. The extent of this communication is dependent, at least, on the power which is available from the power source 50. Information on the strength of a magnetic signal transmitted from the control centre 24 and previously detected by the receiver 46 and stored in a memory in the control circuit 48, can be transmitted to the interrogating unit. This makes it possible for the light signal from the communication interface 42 to convey information on the status of the detonator arrangement 28 e.g. whether the detonator arrangement is in an awake or a sleep mode, whether the detonator arrangement has received an arm or synchronising signal, or the like. Of vital importance is the capability of the arrangement to indicate, via a signal which is transmitted from the communication interface 42, whether a magnetic control signal transmitted through the earth from the control centre 24, will be reliably received by the control circuit 48.
Light which is emitted from the interface 42 is also useful in identifying the position of a detonator assembly and of indicating (confirming) that a respective detonator assembly has been deployed into a borehole.
Number | Date | Country | Kind |
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2020/06083 | Oct 2020 | ZA | national |
Filing Document | Filing Date | Country | Kind |
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PCT/ZA2021/050054 | 9/28/2021 | WO |