Two wire daisy chain

Abstract

A detonator which, in response to a command, uses a first modulation process to generate a first signal and, in response to an event, uses a second modulation process to generate a second signal.

Claims

1. A connector for connecting a detonator to a two-wire bus, wherein the connector includes a sensor and at least a first switch which is operable in response to the sensor, wherein the sensor is capable of distinguishing a first signal received by the sensor from a second signal received by the sensor on the basis of modulation processes used in the generation of the first and second signals.

2. A connector according to claim 1 wherein the sensor causes operation of the first switch only upon detection of the second signal by the sensor.

3. A connector according to claim 2 wherein the switching action of the first switch is implemented through the use of field effect transistors.

4. A connector according to claim 1 wherein the first signal has a first current amplitude and the second signal has a second current amplitude which is higher than the first current amplitude.

5. A connector according to claim 1 wherein the second signal is at a higher level of modulation than the first signal.

6. A connector according to claim 1 which includes first and second switches which are respectively responsive to signals which have different levels of current modulation.

7. A connector according to claim 1 wherein operation of the first switch results in one of the following: (i) one wire of the two-wire bus is open circuited and then closed, and (ii) both wires of the two-wire bus are open circuited and then closed.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is further described by way of examples with reference to the accompanying drawings in which:

(2) FIG. 1 illustrates a detonator system according to the invention,

(3) FIG. 2 is a block diagram representation of certain electronic components in a detonator included in the detonator system,

(4) FIG. 3 illustrates typical signals at different levels of current modulation produced by a detonator in the system,

(5) FIG. 4 illustrates a circuit in a connector used in the detonator system, and

(6) FIG. 5 shows a possible variation to the invention.

DESCRIPTION OF PREFERRED EMBODIMENTS

(7) FIG. 1 of the accompanying drawings illustrates a detonator system 10 according to the invention which includes a surface harness in the form of an elongate two-wire bus 12 which extends to a plurality of boreholes 14 in rock at a site which is to be blasted. The bus 12 is connected to control equipment 16 which is used to control the blasting process. Each borehole contains a respective detonator 20 which is connected via two wires 22 and 24, through the medium of an appropriate connector 26, shown in dotted outline in each instance, to the two-wire bus 12.

(8) FIG. 2 illustrates in block diagram form certain components in a detonator 20. The detonator has a processor or asic 30 and a circuit 32 which may be distinct from the processor/asic or which may be incorporated in the processor/asic. The circuit 32, in response to the detection by the processor/asic of at least one designated or predetermined event 34, produces an output signal 36.

(9) The connector 26 includes a sensing circuit 40 (shown in block form in FIG. 1) and at least one switch 42 which is operable by the sensing circuit under certain conditions as is described hereinafter. The operation of the connector is described, firstly, in general terms and then in more detail with specific reference to FIG. 4 which is a diagram of a circuit in the connector.

(10) In the detonator system 10 the bus 12 has two wires 12A and 12B only Each detonator is connected by means of two wires 22, 24 only to the bus via a corresponding connector 26. Once all the detonators have been connected to the bus the control equipment 16 transmits a first command signal on the bus.

(11) The first command signal is received by the first detonator i.e. the detonator which is closest to the control equipment. The remaining detonators, which are downstream from the first detonator, are isolated from the first command signal because the switch 42, in the first connector, is open. An identity number can be assigned to, or can be read from, the first detonator and validation or other checks can be done on the first detonator. The first detonator can also be programmed at this stage, if required. The specifics of the detonator command sequences are not considered further herein as these are well known in the art and are dependent, inter alia, on the design of the detonator.

(12) Commands to the first detonator from the control equipment are processed by the processor 30 in the detonator. A signal 36, in response to the commands, is generated by the circuit 32 using techniques which are known in the art. The signal 36, shown in a representative manner only in FIG. 3, is at a first level of current modulation and comprises a plurality of pulses 36A (FIG. 3). Each pulse has a relatively low level 46 of current amplitude and the sensing circuit 40 is not responsive thereto. The pulses 36A thus pass through the connector 26, from the detonator to the control equipment 16, without any effect on the sensing circuit 40. In this manner secure and effective two-way communication between the control equipment and the first detonator is established.

(13) Assume that at least one designated event occurs. This event may be selected for the purpose and, by way of example only, may be one or more of the following: a) the end of a sequence of commands to the detonator from the control equipment; b) reception of a command, by the detonator, that is not addressed to the detonator by the control equipment; c) a state change in the detonator. The state change may be one or more of the following: i) the assignment of an identifier to the detonator; ii) the reading of a detonator identifier; iii) the programming of the detonator; and iv) the assignment of a time delay to the detonator; d) an instruction from the control equipment to the detonator to activate or deactivate at least one switch in the connector; e) the expiry of a time period during which no commands are received by the detonator; and f) a variation (decrease or increase) in the average voltage level on the two-wire bus.

(14) For example validation checks may have been carried out successfully on the first detonator and an identifier may have been assigned to the first detonator. When this occurs the processor 30 (in the first detonator) actuates the circuit 32 to produce a second output signal 36B (see FIG. 3) which has a level 48 of current modulation which is significantly higher than the level 46 of current modulation for the first signal 36A. The sensing circuit 40 in the connector is responsive to the higher level of current modulation and, upon detecting the signal 36B, the circuit 40 causes closure of the corresponding switch 42 (referring to FIG. 1). The control equipment can then address the second detonator in the sequence in a unique and secure manner. Command signals directed to the second detonator are prevented from reaching the first detonator through the use of suitable links.

(15) For example a command signal may be uniquely linked to the first or second detonator, or to the state of the first or second detonator, in a way which ensures that the signal can only reach the second detonator.

(16) The aforementioned process continues in succession down the two-wire bus. Each detonator thus, in sequence, is uniquely and directly addressable by the control equipment 16 in a manner which allows for secure bidirectional communications. Each detonator, in turn, is uniquely identified. Upon the occurrence of a designated or predetermined event at each detonator the following detonator is enabled in the sense that it is connected to the control equipment by closure of the switch in the preceding connector. An inherent time delay of a minimum duration is not associated with each connector and switch closure takes place in the shortest possible time.

(17) The switch 42, in the illustrated example, is closed by the second signal 36B which is generated by the circuit 32 of the associated detonator upon detection of a predetermined event by the associated processor/asic 30. It is possible for the circuit 32 to generate a third signal, not shown, at a level of modulation which is distinct from the levels 46 and 48. The sensor 40, or an additional sensor, could be responsive to the third signal and this could be used to open the switch 42.

(18) In a variation of the invention (shown in FIG. 5) each connector (marked 26A) includes two switches 42A and 42B respectively, each of which is responsive to a signal from the circuit 32 with a respective degree of modulation. The switches 42A and 42B are in series and, in this event, at least two predetermined events would have to be detected for both switches to be closed and to be kept closed so that a succeeding detonator could be connected to the control equipment.

(19) FIG. 4 is a circuit diagram of a detonator 20 and a connector 26 which, as noted, includes a sensing circuit 40 and at least the first switch 42.

(20) The connector circuit includes four field effect transistors 50, 52, 54 and 56 respectively (which are used to implement the switching action of the switch 42, notionally shown in FIG. 1), input terminals 60 and 62, and output terminals 64 and 66 respectively. A resistor 68 is connected in line with the wire 22 to the detonator 20.

(21) A capacitor 70 is connected across the gate and source of each of the transistors 50 and 52 respectively. A capacitor 72 is connected across the gate and source of each of the transistors 54 and 56 respectively.

(22) Assume that the terminal 60 is positive with respect to the terminal 62. The current to the detonator 20 passes through the resistor 68. In normal operation, or during talk back from the detonator to the control equipment 16, the voltage developed across the resistor 68 is insufficient to switch either of the transistors 50 and 52 on. Thus the transistors 54 and 56 are held off. As a result voltage modulated signals, from the control equipment 16 to the detonator, that are present at the terminals 60 and 62 are not present at the terminals 64 and 66, i.e. the switch 42 (shown in FIG. 1) is effectively off.

(23) If the detonator draws a higher current then the voltage across the resistor 68 increases and the transistors 50 and 52 are turned on. When the transistor 52 turns on the transistor 54 turns on and so does the transistor 56. The transistor 56, when turning on, produces a latching action in that the transistor 50 is held on even though the voltage across the resistor 68 might drop below the initial high value at which the transistors 50 and 52 were turned on. The voltage across the resistor 68 would drop in this way when the high current consumption or sink of the detonator 20 terminates.

(24) At this stage each of the transistors 50 to 56 is conducting. This remains the case even for brief alternate polarity signalling on the terminals 60 and 62 for the capacitors 70 and 72 respective hold the transistors 50 and 54 on.

(25) Consequently a signal which is presented at the terminals 60 and 62 is present at the terminals 64 and 66. If power is removed from the terminals 60 and 62, or if the polarity of the signal applied to these terminals is reversed for a sufficiently long period to allow either of the capacitors 70 and 72 to discharge, the switch (42) embodied in the connector opens. Diodes 80 and 82 prevent the capacitors 70 and 72 from discharging forcibly if the polarity at the terminals 60 and 62 is reversed by the control equipment. These capacitors normally discharge via resistors 84 and 86 which are connected in parallel with the capacitors, with a polarity reversal or if power is removed.

(26) In the circuit shown in FIG. 4 switching is effected in both wires 12A and 12B of the two-wire bus. The circuit of the connector can however be reconfigured to use fewer components or to effect switching in only one of the wires 12A and 12B.

(27) The principles described herein can be used, with substantial benefit, in conjunction with known techniques in the art and, in particular, in combination with the markers which are described in the specification of International Patent Application No. PCT/ZA2004/00079 to provide flexible or various time delays to the detonators or to adjust these time delays. Clearly time assignments or delays can be transmitted from the control equipment 16 to respective detonators.

(28) In FIG. 1 the two-wire bus 12 is shown as a separate component. This however is not necessarily the case for the bus could be formed as part of the harnesses or wires 22 and 24 which extend to the respective detonators.

(29) The functioning of the connector 26 is preferably carried out by means of circuitry included in a housing of the connector. An equivalent effect, which is intended to fall within the scope of the present invention, can however be achieved by providing suitable circuitry in an appropriate module which is associated with the detonator wires 22, 24, if required.

(30) In the arrangement shown in FIG. 1 it is assumed that the two-wire bus 12 is laid out and that, when a connector is coupled to the bus, a break in one of the wires (in the illustrated example the wire 12B) is made. This is in accordance with the techniques described in the specification of South African Patent Application No. 2009/06238. This is not necessarily the case for in an alternative arrangement suitable lengths of the two-wire bus are connected individually between respective adjacent pairs of connectors.

(31) The circuit shown in FIG. 4 is polarity-sensitive in that the terminal 60 must be positive with respect to the terminal 62 during switching. It is possible though, to reconfigure the circuit so that it can function in a polarity-insensitive manner.