The present disclosure involves blasting technology in general, and particularly relates to electronic detonators, logging techniques and loggers.
In blasting operations, detonators and explosives are buried in the ground, for example, in holes (e.g., bore holes) drilled into rock formations, etc., and the detonators are wired for external access to blasting machines that provide electrical signaling to initiate detonation of explosives. Electronic detonators have been developed which implement programmable delay times such that an array of detonators can be actuated in a controlled sequence. Such electronic detonators typically include an internally stored unique identification number, referred to herein as a detonator serial ID number, and logger devices can be used to program individual electronic detonators with a corresponding delay time according to a blasting plan. Within a given blasting plan, each detonator may be assigned a “detonator number” or “detonator ID”, typically corresponding to a given location or position within a blasting site. In many applications, a blasting site can include hundreds or even thousands of electronic detonators located in a large number of holes, which are referred to herein as positions.
Electronic detonator data for a given blasting site is often logged using one or more loggers, which do not include the capability to fire the detonators being logged. In certain contexts the logging may be performed many weeks or months before blasting occurs, and the electronic detonators are often logged one at a time as they are individually connected to the logger device. Logging, moreover, can involve assignment of the detonator ID for a given blasting plan. Certain electronic detonators have been developed, in which logging of electronic detonators may involve an operator connecting each detonator, and pressing buttons or keys on the logger to read the detonator data, which can include the serial ID number, any assigned detonator ID according to a blasting plan, as well as any delay time. Conventional electronic detonator logging can be time-consuming, with the user being required to connect each detonator, interact with the user interface of the logger to initiate individual read operations, as well as any programming and programmed data verification operations, typically involving navigating through prompt screens on the logger. In a large blasting operation having thousands of detonators, conventional logging can take several hours, even where multiple loggers are used.
Thus, conventional electronic detonator logging processes are time-consuming, and thus costly in terms of manpower. Optical scanning of tags or other visible indicia on a detonator is possible, and sometimes quick, but there is no electrical interface in such technology between the logger and the electronics inside the detonator. Moreover, at the end of logging, the detonators cannot be checked electrically to make sure they are all present on a branch line, nor to perform diagnostics where only optical scanning of tag data is used.
Accordingly, there is a need for improved electronic detonator logging techniques and apparatus to facilitate expeditious and safe logging of detonator data.
Various aspects of the present disclosure are now summarized to facilitate a basic understanding of the disclosure, wherein this summary is not an extensive overview of the disclosure, and is intended neither to identify certain elements of the disclosure, nor to delineate the scope thereof. Instead, the primary purpose of this summary is to present some concepts of the disclosure in a simplified form prior to the more detailed description that is presented hereinafter. Disclosed examples includes logging apparatus, methods and electronic detonators in which the logger transmits read request messages to preprogrammed electronic detonators without transmitting any delay programming messaging, receives and stores electronic detonator data from a given one of the preprogrammed electronic detonators, and the status flag in the given electronic detonator is updated to prevent the given electronic detonator from responding to subsequent read request messages.
The following description and drawings set forth certain illustrative implementations of the disclosure in detail, which are indicative of several exemplary ways in which the various principles of the disclosure may be carried out. The illustrated examples, however, are not exhaustive of the many possible embodiments of the disclosure. Other objects, advantages and novel features of the disclosure will be set forth in the following detailed description of the disclosure when considered in conjunction with the drawings, in which:
Referring now to the figures, several embodiments or implementations of the present disclosure are hereinafter described in conjunction with the drawings, wherein like reference numerals are used to refer to like elements throughout, and wherein the various features are not necessarily drawn to scale. The disclosure relates to methods and logger apparatus for safe logging of detonator data and/or for safe programming of electronic detonator delay times.
Referring initially to
The user utilizes one or more buttons on a keypad 110 according to options presented on a display 106 to enter an automatic logging mode (“AUTOLOG”), and the logger 100 is programmed to allow a user to exit this mode via one or more predefined keystrokes. In the automatic logging mode, the logger 100 sends a series of query or “read request” messages in repetitive fashion without requiring the user to otherwise interact with the user interface 106, 110. In this mode, the logger 100 automatically transmits read request messaging via the wires to one or more connected detonators 10, and any previously unlogged detonators 10, if properly connected and functioning, respond with one or more responsive messages or data packets (hereinafter “responsive messaging”) including one or more of the detonator's unique serial ID number, any programmed detonator number or detonator ID, and/or any previously programmed delay time value. In the automatic logging mode, if two or more detonators 10 are connected to the wires 11, the logger 100 may detect simultaneous responses from multiple detonators 10, and identify such as “crosstalk”, for example, by detecting cyclic redundancy code (CRC) errors in the responsive messaging, and will then retry the read request message until a proper responsive message from a single detonator is received in response. In certain implementations, the logger 100 may discriminate between multiple reply messages from more than one detonator 10 connected to the terminals 104, and can determine the number of detonators 10 with which it is currently connected. In this respect, one possible suitable communication protocol can be implemented with the logger 100 operating as a master for communication along a pair of branch wires with multiple detonators 10 responding to identification request messages and thereafter to messages addressed individually according to the corresponding detonator serial ID numbers. Thus, if the device 100 is connected to a group of detonators 10 in certain modes, it will initially obtain the group of corresponding serial ID numbers from corresponding connected electronic detonators 10.
As shown in
The logger 100 in certain embodiments is battery-powered, and the RS-232 port 114 can be used to either connect the logger 100 for data exchange with another logger or other external device (not shown) and/or for charging the internal battery (not shown). In certain embodiments, a nickel cadmium or lithium ion battery, a Ni metal hydride battery or alkaline cells can be used with voltage restrictions consistent with inherently safe or intrinsically safe operation. In other possible embodiments, a lead acid battery may be used. Power can be provided via the charge input 124 from an external device connected to the connector 114 (e.g., five pin connector 114 on the front face of the illustrated logger device 100 in
The logger 100 in certain embodiments is an inherently safe device for use by blasting personnel at a blasting site 200 without danger of accidentally actuating electronic detonators 10. In this regard, the interface circuitry 105 coupled with the detonator wiring terminals 104 in certain embodiments is low-power circuitry and the logger 100 is not provided with suitable power, energy or voltage from the power supply 127 or elsewhere to initiate arming or firing of connected electronic detonators 10. In addition, the logger apparatus 100 and components thereof are generally operated under control of a processor 120 (
The processor 120 may be any suitable electronic processing device, including without limitation a microprocessor, microcontroller, DSP, programmable logic, etc. and/or combinations thereof, which performs various operations by executing program code such as software, firmware, microcode, etc. The logger 100 includes an electronic memory 130 which can store program code and/or data, including electronic storage of detonator data 132 such as serial ID numbers, detonator numbers, for instance, corresponding to blast site position numbers, and detonator delay values. In certain embodiments, moreover, the memory 130 can also store corresponding geographic location data, such as latitude, longitude and/or elevation. The memory 130 may be any suitable form of electronic memory, including without limitation EEPROM, flash, SD, a multimedia card, and/or a USB flash drive operatively associated with the USB port 112 (
Referring also to
In the illustrated embodiment, the processor 120 is programmed to maintain the logger 100 in the automatic logging mode until the user interacts with the user interface 106, 110 to exit the automatic logging mode. At 206, the user connects one or more preprogrammed detonators 10 to the logger 100. In one example, to facilitate stopping and restarting the automatic logging process, when automatic logging is started, the logger 100 initially attempts a verification process to verify any previously logged detonators 10 that should already be connected on the bus. This sets status flag (e.g., an internal bus detect bit) in any previously logged detonator(s) 10, preventing the previously logged detonator(s) 10 from responding to an auto bus detect (ABD) command packet. The logger 100 in certain examples also shows if any of the previously logged detonators 10 are now missing from the bus. After the verify process is complete, the logger 100 begins automatic logging using ABD command packets and continues until stopped by operator input. During operation in the automatic logging mode, moreover, the processor 120 operates in a generally continuous or repetitive fashion to issue a series of read request messages at 208 until a response is received from one of a plurality of connected detonators 10. The logger 100 transmits a read request at 208 via the electrical interface 104, 105. While operating in the automatic logging mode, the logger 100 does not transmit any programming messaging to the connected detonator 10, and does not require user interaction with the keyboard 110 or the display 106. This advantageously saves a significant amount of user time in sequentially logging electronic detonators 10, during which time the user does not need to press any buttons on the keyboard 110. The automatic logging mode finds utility in a variety of situations, including without limitation a quality control process in which detonators 10 are preprogrammed by any suitable means, with quality inspection personnel utilizing a logger 100 in the automatic logging mode to log the previously programmed delay for verification with respect to a blasting plan or design timing sequence.
At 210 in
First, the logger 100 broadcasts an auto bus detect command packet on the wires 11. All detonators 10 receiving the command that have not previously been detected on the wires 11 (as indicated by their respective bus detect status flag settings) calculate a “clock” value that correlates to their serial IDs and/or delay time information, and then enter a wait state. The correlated clock value can, for example, be calculated from an 11-bit number derived from the CRC-8 of the combined serial ID and selected data bits (e.g., 8 bits) of the delay register word of the auto bus detect command packet, so that adequate time is afforded between each possible clock value for the initiation of a response (including any delay as described below) from a corresponding detonator 10. Thereafter, the logger 100 begins issuing a “clock” sequence on the wires 11 that continues (except when halted or aborted as described below) until it reaches a number that correlates to the highest possible detonator serial ID in the system (for example, using the 11-bit number described above, there may be 2,048 possible clock values). Time is allowed between the end of the auto bus detect command packet and issuance of a clock that correlates to the first possible serial ID, to permit calculation by the detonator ASICs of the clock values that correlate to their serial IDs. This can be accomplished by including a wait time (e.g., 10 μs in one embodiment) between the end of the detection command packet and the leading edge of the first transition of the clock. To enable current talkback, the wires 11 are preferably held low during this time, but can alternately be held high. When the clock value for a particular unlogged detonator 10 is reached, the ASIC of that detonator 10 responds. In one example, time (during which the wires 11 are held high or low, preferably low) is permitted for the initiation of a response that is delayed by a predetermined period. The system may preferably be configured so that if the wires 11 are not pulled low before a predetermined timeout period (e.g., 4.096 ms), the detection process will abort.
Upon sensing a response from one or more detonators 10, the logger 100 halts the clock sequence and holds the wires 11 (preferably low) until the full response packet is received, at which point the clock sequence resumes. Alternately, adequate time for the transmission of a full packet could be permitted between the counting of each clock value that correlates to a possible serial ID, however, this would be slower. The logger 100 records at least the serial ID (and optionally also the device settings) of any responding detonators 10. If more than one ASIC begins responding simultaneously, the logger 100 preferably ignores such responses and preferably resumes the clock sequence as it would otherwise. The process starting with the auto bus detect command packet is then repeated using a different delay time or a different dummy serial ID until no unlogged detonators 10 respond (i.e., until a full clock sequence is counted out without any devices responding), at which point it is deemed that all detonators 10 connected to the wires 11 are identified (i.e., logged).
When the auto bus detect sequence is complete, the logger 100 then sends (in any desired order such as by serial ID) a known detonator read back command to each individual known detonator 10, i.e., all those that responded to the auto bus detect command, as well as all those that were initially identified to the logger 100 by the logger. By this command, the logger 100 requests a verify talk back of a single detonator 10 of which the serial ID is known. In response to this command, the detonator 10 provides its serial ID, delay time, scratch information, and status flags (notably including its charge status). This command preferably sets the wires detection flag high so that the device no longer responds to an auto bus detect command.
This operation continues with the logger 100 awaiting responsive messaging from the detonators 10 without transmitting any programming messaging to the connected electronic detonator 10 and without requiring user interaction with the user interface 106, 110. It is noted that the user, at any time, may initiate a mode change in the logger 100, for example, by pressing a dedicated key or a predefined sequence of keys on the keypad 110 in order to take the logger 100 out of the automatic logging mode (YES at 212 in
At 214, once the logger 100 receives responsive messaging from a previously unlogged given detonator 10 (YES at 210), the logger 100 obtains electronic detonator data 132 from the responsive messaging at 214, and stores this in the memory 130. In one example, the logger 100 receives and stores detonator data, such as one or more of a serial number, and ID number and/or a previously programmed delay time value from the responding given electronic detonator 10 at 214 without transmitting any delay programming messaging to the given electronic detonator 10 and without requiring user interaction with the user interface 106, 110. For each given responding electronic detonator 10, the logger 100 in the illustrated example determines at 210 whether a serial ID number received in responsive messaging from the responding electronic detonator 10 has been previously logged by performing a check of the memory 130. If not, the logger 100 sends a verify command to the given electronic detonator 10 at 216 to cause the detonator 10 to update its status flag, which then prevents the given electronic detonator 10 from responding to subsequent read request messages.
In accordance with further aspects of the present disclosure, the electronic detonators 10 are configured to respond to verify command from the logger 100 and update their status flag, and thereafter to refrain from responding to subsequently received read request messages from the logger 100. In this manner, the system implements the auto logging mode operation to quickly log a plurality of connected preprogrammed electronic detonators 10 without requiring user intervention between loggings. The individual detonators 10 include a pair of wires 11 that allow operative electrical connection of the electronic detonator 10 with the logger 100, and the wires 11 allow exchange of electrical signals between the logger 100 and the electronic detonators 10. As shown in
The logger 100 remains in the automatic logging mode until the user interacts with the user interface (e.g., at 212) In certain examples, after sending the verify command to cause the detonator 10 to update its status flag at 216, the logger 100 returns to check if the user has pressed a user interface key to finish logging at 212, and if not (NO at 212), returns to transmit another read request (ABD packet). In this manner, the logger 100 automatically logs all the connected electronic detonators 10, and obtains previously programmed delay values and other logger data from the connected detonators 10. In certain examples, the logger processor 120 is programmed to cause the logger 100 to provide an audible, vibratory or visual indication to the user via the user interface 106 at 218 and/or 220 indicating that the given electronic detonator 10 has been logged during operation in the automatic logging mode without transmitting any delay programming messaging to the connected electronic detonators 10 and without requiring user interaction with the user interface 106, 110. The logger 100 repeats the automatic logging processing at 208-220 for further ones of the connected preprogrammed electronic detonators 10. The logger 100 stores the received detonator data for each detonator 10 (e.g., serial number, detonator ID number and/or delay time) in the electronic memory 130 at 214 in
Continuing in
The above examples are merely illustrative of several possible embodiments of various aspects of the present disclosure, wherein equivalent alterations and/or modifications will occur to others skilled in the art upon reading and understanding this specification and the annexed drawings. In particular regard to the various functions performed by the above described components (assemblies, devices, systems, circuits, and the like), the terms (including a reference to a “means”) used to describe such components are intended to correspond, unless otherwise indicated, to any component, such as hardware, processor-executed software and/or firmware, or combinations thereof, which performs the specified function of the described component (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the illustrated implementations of the disclosure. In addition, although a particular feature of the disclosure may have been disclosed with respect to only one of several implementations, such feature may be combined with one or more other features of the other implementations as may be desired and advantageous for any given or particular application. Also, to the extent that the terms “including”, “includes”, “having”, “has”, “with”, or variants thereof are used in the detailed description and/or in the claims, such terms are intended to be inclusive in a manner similar to the term “comprising.”
The present application claims priority to and the benefit of U.S. Provisional Patent Application No. 62/541,164, filed Aug. 4, 2017 and entitled AUTOMATIC METHOD AND APPARATUS FOR LOGGING PREPROGRAMMED ELECTRONIC DETONATORS, the entirety of which is hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/US2018/044915 | 8/2/2018 | WO | 00 |
Number | Date | Country | |
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62541164 | Aug 2017 | US |