WO2022014530A1 - 無線起爆システム及び無線起爆システム用中継装置及び無線起爆システムを用いた無線起爆方法 - Google Patents
無線起爆システム及び無線起爆システム用中継装置及び無線起爆システムを用いた無線起爆方法 Download PDFInfo
- Publication number
- WO2022014530A1 WO2022014530A1 PCT/JP2021/026119 JP2021026119W WO2022014530A1 WO 2022014530 A1 WO2022014530 A1 WO 2022014530A1 JP 2021026119 W JP2021026119 W JP 2021026119W WO 2022014530 A1 WO2022014530 A1 WO 2022014530A1
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- WIPO (PCT)
- Prior art keywords
- detonator
- relay device
- frequency
- radio signal
- antenna
- Prior art date
Links
- 238000005474 detonation Methods 0.000 title claims abstract description 103
- 238000000034 method Methods 0.000 title claims description 66
- 238000005422 blasting Methods 0.000 claims abstract description 135
- 230000005540 biological transmission Effects 0.000 claims abstract description 91
- 238000003780 insertion Methods 0.000 claims abstract description 78
- 230000037431 insertion Effects 0.000 claims abstract description 78
- 238000012545 processing Methods 0.000 claims abstract description 17
- 230000008569 process Effects 0.000 claims description 54
- 239000002360 explosive Substances 0.000 claims description 47
- 238000004891 communication Methods 0.000 claims description 27
- 239000003990 capacitor Substances 0.000 claims description 13
- 238000011144 upstream manufacturing Methods 0.000 claims description 13
- 239000003721 gunpowder Substances 0.000 abstract 2
- 239000011435 rock Substances 0.000 description 10
- 238000010586 diagram Methods 0.000 description 8
- 239000002689 soil Substances 0.000 description 8
- 238000009412 basement excavation Methods 0.000 description 7
- 238000002360 preparation method Methods 0.000 description 6
- 230000000694 effects Effects 0.000 description 5
- 230000005672 electromagnetic field Effects 0.000 description 4
- 230000002093 peripheral effect Effects 0.000 description 4
- 230000004044 response Effects 0.000 description 3
- 230000005611 electricity Effects 0.000 description 2
- 238000007789 sealing Methods 0.000 description 2
- 238000006467 substitution reaction Methods 0.000 description 2
- 230000008859 change Effects 0.000 description 1
- 239000004927 clay Substances 0.000 description 1
- 230000005684 electric field Effects 0.000 description 1
- 238000004880 explosion Methods 0.000 description 1
- 230000006870 function Effects 0.000 description 1
- 238000005259 measurement Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 230000035699 permeability Effects 0.000 description 1
Images
Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F42—AMMUNITION; BLASTING
- F42D—BLASTING
- F42D1/00—Blasting methods or apparatus, e.g. loading or tamping
- F42D1/04—Arrangements for ignition
- F42D1/045—Arrangements for electric ignition
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21D—SHAFTS; TUNNELS; GALLERIES; LARGE UNDERGROUND CHAMBERS
- E21D9/00—Tunnels or galleries, with or without linings; Methods or apparatus for making thereof; Layout of tunnels or galleries
- E21D9/006—Tunnels or galleries, with or without linings; Methods or apparatus for making thereof; Layout of tunnels or galleries by making use of blasting methods
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F42—AMMUNITION; BLASTING
- F42D—BLASTING
- F42D3/00—Particular applications of blasting techniques
- F42D3/04—Particular applications of blasting techniques for rock blasting
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F42—AMMUNITION; BLASTING
- F42B—EXPLOSIVE CHARGES, e.g. FOR BLASTING, FIREWORKS, AMMUNITION
- F42B3/00—Blasting cartridges, i.e. case and explosive
- F42B3/10—Initiators therefor
- F42B3/12—Bridge initiators
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F42—AMMUNITION; BLASTING
- F42D—BLASTING
- F42D1/00—Blasting methods or apparatus, e.g. loading or tamping
- F42D1/08—Tamping methods; Methods for loading boreholes with explosives; Apparatus therefor
Definitions
- One form of this disclosure relates to a wireless detonation system used at excavation sites such as tunnels, crushing sites such as rocks, and crushing sites of structures such as buildings.
- the present embodiment relates to a relay device for wireless detonation used in the wireless detonation system and a wireless detonation method using the wireless detonation system.
- the wireless detonator system used for blasting work at tunnel excavation sites, etc. has a wireless detonator detonator and a blasting operation device.
- the radio detonator detonator is loaded together with the explosive into a plurality of charge holes drilled in the excavation direction on the face surface to be blasted.
- the charge hole has, for example, a diameter of several cm and a depth of about several m.
- the blasting operation device is installed at a remote location away from the face surface.
- the radio detonator and the blasting control device each have a transmit / receive antenna.
- the radio detonation system of Japanese Patent No. 5630390 has a blasting operation device side antenna installed near the face surface.
- the blasting operation device side antenna is installed, for example, at a position about 1 m away from the face surface in a loop shape having a size surrounding a plurality of charge holes on the blasting surface.
- the antenna on the blasting operation device side wirelessly transmits a control signal including operating energy and an explosion signal to the wireless detonator detonator.
- the explosive side antenna receives operating energy and control signals from the blasting control device.
- the operating energy is stored in the power storage element of the wireless detonator detonator.
- the wireless detonator detonator transmits a response signal including its own operating state based on the control signal via an antenna on the explosive side by radio waves.
- the blasting operation device receives the radio wave via the antenna. From the response signal, the blasting operation device recognizes that the charging of the wireless detonator detonator is completed. After that, the blasting operation device sends a detonation signal to the radio detonator detonator, and the radio detonator detonator detonates the explosive.
- the blasting operation device side antenna transmits operating energy from the outside of the face surface to the explosive side antenna in the charge hole.
- a large blasting operation device side antenna is installed near the blasting surface.
- the radio detonation system of Japanese Patent No. 6612769 installs a large blasting operation device side antenna at the ignition location. Therefore, it was troublesome to install a large antenna on the blasting operation device side. In addition, there are restrictions on the place where the antenna on the blasting operation device side can be installed, and workability may not be good.
- the blasting operation device side antenna transmits operating energy and control signals to the explosive side antenna via the bedrock.
- the blasting operation device-side antennas of Japanese Patent No. 5630390, Japanese Patent No. 4309001, and Japanese Patent No. 6612769 are easy to pass through the bedrock, for example, at a low frequency of 1 k to 500 kHz and with a relatively large power (for example, exceeding several watts). Sends operating energy and control signals. Therefore, it may be necessary to take measures such as electromagnetic wave shielding so that electromagnetic waves do not leak to the outside of the tunnel.
- the wireless detonator system has a blasting operation device, a detonator detonator, and a relay device.
- the blasting operation device is installed away from the blasting target and transmits a first downlink radio signal of the first frequency.
- the detonator detonator comprises an explosive-side receiving antenna that is loaded into the charge hole to be blasted and receives a second downlink radio signal of a second frequency lower than the first frequency.
- the relay device includes a first receiving antenna that receives the first downlink radio signal, a relay processor that receives and processes the first downlink radio signal and transmits the second downlink radio signal of the second frequency, and a second downlink radio.
- a second transmitting antenna for transmitting a signal is provided. The second transmitting antenna is loaded into the insertion hole to be blasted along with the charge hole.
- the relay device and the detonator detonator communicate wirelessly at the second frequency, which is a relatively low frequency.
- the relay device and the detonator detonator wirelessly communicate with each other at a low frequency that passes through the bedrock that constitutes the blasting target. Since both the relay device and the detonator detonator are installed in the holes formed in the blasting target, they are located close to each other. Therefore, for example, the relay device and the detonator can communicate with each other with a radio signal having a small power of several watts or less.
- the relay device and the blasting operation device wirelessly communicate with each other by the first frequency, which is a high frequency. Therefore, it is possible to prevent the signal from leaking to the periphery such as outside the tunnel that is the target of blasting.
- the detonator detonator has an explosive side transmitting antenna that transmits a second upstream radio signal of the second frequency.
- the relay device includes a second receiving antenna that receives the second uplink radio signal, a relay processor that receives and processes the second uplink radio signal and transmits the first uplink radio signal of the first frequency, and the first uplink radio. It has a first transmitting antenna that transmits a signal.
- the blasting operation device receives the first uplink radio signal. Therefore, the above-mentioned effect can be obtained not only in the downstream radio signal transmitted from the blasting operation device to the detonator detonator via the relay device, but also in the reverse upstream radio signal.
- the explosive side receiving antenna and the explosive side transmitting antenna are common antennas.
- the first receiving antenna and the first transmitting antenna are common antennas.
- the second receiving antenna and the second transmitting antenna are common antennas. Therefore, the number of parts in the entire system can be reduced.
- the relay device has a housing in which a part or all of the insertion hole is inserted.
- the first receiving antenna, the second transmitting antenna, and the relay processor are integrally provided in the housing.
- the repeater has a plurality of housings that are inserted into the insertion holes.
- a first receiving antenna is provided in any of the plurality of housings.
- a second transmitting antenna is provided in one of the plurality of housings.
- a relay processor is provided in one of a plurality of housings. Therefore, the relay device is supported by the blasting target via the housing. Therefore, the relay device is easily inserted into and supported by the blasting target.
- the housing has a back end that is installed behind the insertion hole.
- a second transmitting antenna is provided at the rear end.
- a first receiving antenna is provided at the front end of the housing on the opposite side of the back end. Therefore, the second transmitting antenna is located near the detonator detonator loaded in the back side of the charge hole. Therefore, the relay device and the detonator detonator can communicate with each other with a signal with a smaller electric power.
- the first receiving antenna is located near the opening of the insertion hole. Therefore, the first receiving antenna can communicate with the blasting operation device by a wireless signal without being relatively disturbed by the rock mass or the like constituting the blasting target.
- the front end of the housing is installed together with the first receiving antenna so as to protrude from the blasting target from the insertion hole. Therefore, the relay device and the blasting operation device can communicate with each other by wireless signals without being obstructed by the bedrock or the like constituting the blasting target. Further, the first receiving antenna protrudes from the blasting target by using the housing held by the blasting target. Therefore, the first receiving antenna is supported by the blasting target with a simple structure.
- the second frequency is 1 kHz to 500 kHz transmitted through the bedrock.
- the first frequency is 1 MHz to 10 GHz. Therefore, the relay device and the detonator detonator can preferably communicate wirelessly in the bedrock. Further, the frequency bands of the first frequency and the second frequency are separated. Therefore, interference between the signal of the first frequency and the signal of the second frequency is suppressed, and erroneous communication can be suppressed.
- the present disclosure has a detonator loading unit that loads the detonator detonator into the charging hole.
- the detonator loading unit has a loading unit side communication device capable of communicating with a radio signal of the second frequency to the explosive side receiving antenna of the detonator detonator before being loaded into the charge hole. Therefore, the process of communicating the detonator tube and the communication device on the loading unit side and the process of loading the detonator tube into the charging hole can be efficiently performed in a series of flows. Further, the explosive side receiving antenna received from the loading unit side communication device and the explosive side receiving antenna received from the relay device can be shared. Therefore, the number of parts of the detonator can be reduced.
- the detonator detonator has a power receiving coil that receives operating energy and a capacitor that stores operating energy.
- the detonator loading unit has a feeding coil that supplies operating energy to the power receiving coil of the detonator detonator before it is loaded into the charging hole. Therefore, the capacitor of the detonator detonator can maintain the state in which the operating energy is not stored or is small until immediately before the detonator detonator is loaded into the charging hole. Therefore, when transporting the detonator detonator to the blasting target, it can be transported in a stable state without detonating energy.
- power is supplied to the detonator detonator immediately before loading into the charge hole. Therefore, a capacitor having a relatively small capacity can be used. Thus, the cost of the detonator detonator can be reduced. In addition, the work can be done efficiently because the power supply time can be shortened.
- the relay device has a power receiving coil that receives operating energy from the feeding coil of the detonator loading unit, and a capacitor that stores operating energy. Therefore, the relay device can also be fed by using the feeding coil that feeds the detonator detonator. Therefore, the number of parts in the entire system can be reduced. Further, immediately before inserting the relay device into the insertion hole, the capacitor of the relay device is charged with electricity. Therefore, the storage capacity of the capacitor can be reduced to the minimum amount required for communication.
- a detonator loading unit is provided in the explosive delivery unit that delivers the explosive to be loaded in the charge hole. Therefore, the step of loading the detonator detonator into the charge hole and the step of loading the explosive to the front side of the detonator detonator of the charge hole can be efficiently performed in a series of flows.
- the relay device for a wireless detonation system has a first receiving antenna, a relay processor, and a second transmitting antenna.
- the first receiving antenna receives the first downlink radio signal of the first frequency from the blasting operation device installed away from the blasting target.
- the relay processor receives and processes the first downlink radio signal, and transmits and processes the second downlink radio signal having a second frequency lower than the first frequency.
- the second transmitting antenna transmits the second downlink radio signal to the receiving antenna on the explosive side of the detonator detonator loaded in the charge hole to be blasted.
- the first receiving antenna, the relay processor, and the second transmitting antenna are mounted on the housing. The housing is loaded into the insertion hole to be blasted alongside the charge hole.
- the relay device and the detonator detonator communicate wirelessly at the second frequency, which is a relatively low frequency.
- the relay device and the detonator detonator wirelessly communicate with each other at a low frequency that passes through the bedrock that constitutes the blasting target. Since both the relay device and the detonator detonator are installed in the holes formed in the blasting target, they are located close to each other. Therefore, for example, the relay device and the detonator can communicate with each other with a radio signal having a small power of 10 W or less.
- the relay device and the blasting operation device wirelessly communicate with each other by the first frequency, which is a high frequency. Therefore, it is possible to prevent the signal from leaking to the periphery such as outside the tunnel that is the target of blasting.
- the relay device for a wireless detonation system has a second receiving antenna, a relay processing machine, and a first transmitting antenna.
- the second receiving antenna receives the second uplink radio signal of the second frequency transmitted from the detonator detonator.
- the relay processing machine receives and processes the second uplink radio signal, and transmits and processes the first uplink radio signal of the first frequency.
- the first transmitting antenna transmits the first uplink radio signal.
- the second receiving antenna, the relay processor, and the first transmitting antenna are mounted on the housing. Therefore, the above-mentioned effect can be obtained not only in the downstream radio signal transmitted from the blasting operation device to the detonator detonator via the relay device, but also in the reverse upstream radio signal.
- the first receiving antenna and the first transmitting antenna are common antennas.
- the second receiving antenna and the second transmitting antenna are common antennas. Therefore, the number of parts in the entire system can be reduced.
- a second transmitting antenna is provided at the rear end of the housing installed at the back of the insertion hole.
- a first receiving antenna is provided at the front end of the housing on the opposite side of the back end. Therefore, the second transmitting antenna is located near the detonator detonator loaded in the back side of the charge hole. Therefore, the relay device and the detonator detonator can communicate with each other with a signal with a smaller electric power.
- the first receiving antenna is located near the opening of the insertion hole. Therefore, the first receiving antenna can communicate with the blasting operation device by a wireless signal without being relatively disturbed by the rock mass or the like constituting the blasting target.
- the front end of the housing is installed together with the first receiving antenna so as to protrude from the blasting target from the insertion hole. Therefore, the relay device and the blasting operation device can communicate with each other by wireless signals without being obstructed by the bedrock or the like constituting the blasting target. Further, the first receiving antenna protrudes from the blasting target by using the housing held by the blasting target. Therefore, the first receiving antenna is supported by the blasting target with a simple structure.
- the second frequency is 1 kHz to 500 kHz transmitted through the bedrock
- the first frequency is 1 MHz to 10 GHz. Therefore, the relay device and the detonator detonator can preferably communicate wirelessly in the bedrock. Further, the frequency bands of the first frequency and the second frequency are separated. Therefore, interference between the signal of the first frequency and the signal of the second frequency is suppressed, and erroneous communication can be suppressed.
- the blasting operation device is installed at a position away from the blasting target.
- a relay device is installed in the insertion hole to be blasted.
- the first antenna of the blasting operation device and the relay device communicate with each other by a radio signal of 1 MHz to 10 GHz, which is the first frequency.
- An exploding detonator is installed in the charge hole to be blasted.
- the detonator detonator and the second antenna of the relay device communicate with each other by a radio signal of 1 kHz to 500 kHz, which is the second frequency.
- the relay processor of the relay device receives and processes the signal of the first frequency, and processes the transmission of the signal of the second frequency. Further, the relay processor of the relay device receives and processes the signal of the second frequency, and also processes the transmission of the signal of the first frequency.
- the relay device and the detonator detonator communicate with each other by a radio signal of 1 kHz to 500 kHz that passes through, for example, the bedrock that constitutes the blasting target. Since both the relay device and the detonator detonator are installed in the holes formed in the blasting target, they are located close to each other. Therefore, for example, the relay device and the detonator can communicate with each other with a radio signal having a small power of 10 W or less. On the other hand, the relay device and the blasting operation device communicate with each other by a relatively high radio signal of 1 MHz to 10 GHz. Therefore, it is possible to prevent the signal from leaking to the periphery such as outside the tunnel that is the target of blasting.
- the blasting operation device transmits the first downlink radio signal of the first frequency to the relay device.
- the relay processor of the relay device receives and processes the first downlink radio signal, and transmits and processes the second downlink radio signal of the second frequency.
- the relay device transmits the second downlink radio signal to the detonator detonator. Therefore, it is possible to prevent the downlink radio signal of the first frequency transmitted from the blasting operation device to the relay device from leaking to the periphery such as outside the tunnel to be blasted.
- the downlink radio signal of the second frequency transmitted from the relay device to the detonator detonator passes through the bedrock or the like constituting the blasting target. Therefore, a downlink radio signal can be suitably transmitted from the blasting operation device to the detonator detonator via the relay device.
- the detonator detonator transmits the second upstream radio signal of the second frequency to the relay device.
- the relay processor of the relay device receives and processes the second uplink radio signal, and transmits and processes the first uplink radio signal of the first frequency.
- the relay device transmits the first uplink radio signal to the blasting operation device. Therefore, the above-mentioned effect can be obtained not only in the downstream radio signal transmitted from the blasting operation device to the detonator detonator via the relay device, but also in the reverse upstream radio signal.
- the detonator loading unit wirelessly supplies power to the detonator detonator and the relay device in the vicinity of the blasting target.
- the detonator loading unit stores the detonator detonator and loads it into the charge hole to be blasted.
- the relay device in which the detonator loading unit is stored is loaded into the insertion hole to be blasted. Therefore, the step of charging the detonator tube and loading it into the charging hole, or the step of charging the relay device and loading it into the insertion hole can be efficiently performed in a series of flows in the vicinity of the blasting target. Further, power is supplied to the detonator detonator immediately before loading into the charge hole or the relay device immediately before loading into the insertion hole. Therefore, a storage circuit such as a capacitor having a relatively small capacity can be used. Thus, the cost of the detonator detonator and the relay device can be reduced.
- the radio detonation system 1 is used to explode explosives to excavate or crush structures such as tunnels, seabeds, rocks, and buildings.
- the tunnel 70 has a face surface 71 at the back.
- a plurality of charge holes 72 are drilled in the face surface 71 at predetermined intervals in the vertical direction and the horizontal direction.
- the charge hole 72 extends in the depth direction of the tunnel 70.
- each charge hole 72 is loaded with a detonator detonator 10 and a plurality of explosives 2.
- the entrance of the charge hole 72 in front of the explosive 2 is sealed with a sealing member 73 such as clay.
- one or a plurality of insertion holes 74 for installing the relay device 30 are drilled in the face surface 71.
- the insertion holes 74 are located at predetermined intervals in the vertical direction and the horizontal direction with respect to the plurality of charge holes 72 into which the explosive 2 is loaded.
- the insertion hole 74 extends in the depth direction of the tunnel 70 substantially parallel to the plurality of charge holes 72.
- the relay device 30 is inserted into the insertion hole 74.
- a part of the housing 31 of the relay device 30 protrudes from the entrance of the insertion hole 74.
- the relay device 30 wirelessly communicates with each of the plurality of detonators 10 in the charge hole 72.
- the radio detonation system 1 has a blasting operation device 40 installed in the cave bed of the tunnel 70 or outside the tunnel 70.
- the blasting operation device 40 is arranged at a position separated from the face surface 71 by a distance L1.
- the distance L1 is set to, for example, 100 m to 1000 m.
- the blasting operation device 40 has a transmission / reception antenna 47 and can communicate with the relay device 30 wirelessly. Therefore, the blasting operation device 40 can wirelessly communicate with each of the plurality of detonators 10 in the charge hole 72 via the relay device 30.
- the detonator detonator 10 and the explosive 2 are loaded into each charge hole 72 by using the detonator loading unit 51.
- the detonator loading unit 51 is provided in, for example, a vehicle-type explosive delivery unit 50.
- the detonator loading unit 51 is equipped with a power supply device 52 for charging the detonator detonator 10.
- the power feeding device 52 supplies power to the detonator tube 10 immediately before loading the detonator tube 10 into the charging hole 72.
- the power feeding device 52 may be a handy type that is provided separately from the detonator loading unit 51 and can be carried.
- the detonator detonator 10 will be described in detail according to FIGS. 4 and 5.
- the detonator detonator 10 has a substantially cylindrical detonator body 11.
- a power receiving coil 12 is wound in an annular shape around the substantially central portion of the outer peripheral surface of the detonator body 11.
- the number of turns of the power receiving coil 12 is one or more turns, for example, ten or more turns.
- the power receiving coil 12 generates a current having a specific frequency and amplitude when exposed to an electromagnetic field.
- the electric current is used as electric power for controlling and detonating the detonator detonator 10.
- the power receiving coil 12 also serves as a transmitting / receiving antenna for transmitting / receiving various signals having a specific frequency.
- the power receiving coil 12 transmits various signals by flowing a current having a specific frequency and amplitude.
- the power receiving coil 12 receives various signals having a specific frequency and amplitude when exposed to a specific electromagnetic field.
- the frequency of the electromagnetic wave is, for example, 1 k to 500 kHz, preferably 10 k or more, for example, 200 kHz so that the permeability in the soil or the bedrock is good.
- the detonator detonator 10 has a detonator ignition portion 13 projecting from one end surface of the detonator main body 11.
- the detonator ignition unit 13 extends along the longitudinal direction of the detonator body 11.
- the detonator ignition unit 13 is inserted into the parent die 2a, which is one of the explosives 2.
- the detonator detonator 10 has a tuning circuit 22 electrically connected to the power receiving coil 12, a rectifying element 23, and a storage circuit 25.
- the tuning circuit 22 tunes to the reception frequency of the current generated when the power receiving coil 12 receives electric power.
- the rectifying element 23 rectifies the current input from the tuning circuit 22 into a direct current.
- the power storage circuit 25 is, for example, a capacitor or the like, and stores the electric power rectified by the rectifying element 23.
- the power storage circuit 25 stores electric power for operating each electronic component of the detonator detonator 10 and electric power for igniting the detonator ignition unit 13.
- the detonator detonator 10 has a detonator modem 24 for using the power receiving coil 12 as an antenna.
- the detonator modem 24 has a receiving circuit (demodulation circuit) 24a and a transmitting circuit (modulation circuit) 24b.
- the receiving circuit 24a and the transmitting circuit 24b are connected to the power receiving coil 12 and the control circuit (CPU) 21, respectively.
- a current is generated when the power receiving coil 12 receives a signal.
- the receiving circuit 24a converts (demodulates) an analog signal based on this change in current into a digital signal.
- the transmission circuit 24b converts (modulates) the digital signal transmitted from the control circuit 21 into an analog signal.
- the detonator detonator 10 has a memory 26 connected to the control circuit 21.
- the ID number (serial number) unique to the detonator detonator 10 and the algorithm are recorded in advance in the memory 26.
- the detonation delay time is recorded based on a signal for setting the detonation delay time demodulated by the receiving circuit 24a.
- the detonator detonator 10 has a detonator switch 27 and a resistance measurement circuit 28 connected to the control circuit 21.
- the detonator switch 27 switches between a connected state in which the power storage circuit 25 and the detonator ignition unit 13 are electrically connected and a disconnected state.
- the detonator switch 27 shuts off the power storage circuit 25 and the detonator ignition unit 13.
- the detonator switch 27 connects the power storage circuit 25 and the detonator ignition unit 13 when an on signal is output from the control circuit 21.
- the resistance measuring circuit 28 measures the electric resistance of the detonator ignition unit 13 based on the output from the control circuit 21 in order to determine whether the detonator ignition unit 13 is normal or not.
- the relay device 30 has a cylindrical housing 31.
- the housing 31 has a front end 31a at one end and a back end 31b at the other end.
- the front end 31a is arranged at a position protruding from the entrance of the insertion hole 74.
- the back end 31b is arranged on the back side far from the entrance of the insertion hole 74.
- the relay device 30 has a first transmission / reception antenna 35 at the front end 31a.
- the relay device 30 has a second transmission / reception antenna 37 at the rear end 31b.
- the relay device 30 has a control circuit (CPU) 32, and the control circuit 32 includes a relay processor that receives and processes an input signal and transmits a signal of a different frequency.
- the relay processing machine receives and processes, for example, a signal of 1M to 10GHz and transmits a signal of 1k to 500kHz.
- the relay processor receives and processes, for example, a signal of 1 k to 500 kHz, and transmits a signal of 1 M to 10 GHz.
- the relay device 30 has a power supply 33 for supplying electric power to the control circuit 32 and a memory 34.
- the control circuit 32 records information in the memory 34 based on a command, reads data stored in the memory 34, or calculates based on an algorithm stored in the memory 34.
- the relay device 30 has a first modem 36 and a second modem 38.
- the first modem 36 has a first antenna side receiving circuit 36a and a first antenna side transmitting circuit 36b.
- the first antenna side receiving circuit 36a and the first antenna side transmitting circuit 36b are connected to the first transmitting / receiving antenna 35 and the control circuit 32, respectively.
- the first antenna side receiving circuit 36a demodulates the analog signal received by the first transmitting / receiving antenna 35 into a digital signal.
- the first antenna side transmission circuit 36b modulates the digital signal transmitted from the control circuit 32 into an analog signal.
- the first transmission / reception antenna 35 transmits / / receives radio waves of, for example, 1 M to 10 GHz, which are difficult to penetrate in the soil or rock, and preferably transmits / / receives radio waves of 100 MHz or higher, for example, 920 MHz.
- the second modem 38 has a second antenna side receiving circuit 38a and a second antenna side transmitting circuit 38b.
- the second antenna side receiving circuit 38a and the second antenna side transmitting circuit 38b are connected to the second transmitting / receiving antenna 37 and the control circuit 32, respectively.
- the second antenna side receiving circuit 38a demodulates the analog signal received by the second transmitting / receiving antenna 37 into a digital signal.
- the first antenna side transmission circuit 36b modulates the digital signal transmitted from the control circuit 32 into an analog signal.
- the second transmitting / receiving antenna 37 transmits / / receives, for example, a radio wave of 1 k to 500 kHz, which has good transparency in the soil or rock, and preferably transmits / / receives a radio wave of, for example, 200 kHz.
- the blasting operation device 40 has a control circuit (CPU) 43, an input unit 41, and a display unit 42.
- the control circuit 43 outputs an electric signal to each electric component based on the input of the electric signal from each electric component of the blasting operation device 40.
- the input unit 41 includes, for example, a keyboard, a switch, a touch panel, and the like.
- the display unit 42 includes, for example, a display, a lamp for turning on / off, and the like. The operator operates the input unit 41 while checking the information displayed on the display unit 42.
- the input unit 41 and the display unit 42 are electrically connected to the control circuit 43, respectively.
- the blasting operation device 40 has a power supply 44 for supplying electric power to the control circuit 43 and a memory 45.
- the control circuit 43 records information such as the ID number of the detonator detonator 10 in the memory 45 based on the command, reads the data stored in the memory 45, or calculates based on the algorithm stored in the memory 45.
- the blasting operation device 40 has a transmission / reception antenna 47 and an operation machine modem 46.
- the operating modem 46 has a receiving circuit 46a and a transmitting circuit 46b.
- the receiving circuit 46a and the transmitting circuit 46b are connected to the transmitting / receiving antenna 47 and the control circuit 43, respectively.
- the receiving circuit 46a demodulates the analog signal received by the transmitting / receiving antenna 47 into a digital signal.
- the transmission circuit 46b modulates the digital signal transmitted from the control circuit 43 into an analog signal.
- the transmit / receive antenna 47 transmits / / receives radio waves of, for example, 1 M to 10 GHz.
- the wireless detonation system 1 has an explosive detonator 10 and an explosive delivery unit 50 that delivers explosives 2 in each charge hole 72.
- the explosive delivery unit 50 has a boom 50b mounted on the vehicle 50a.
- the boom 50b is supported by the vehicle 50a so that it can be expanded and contracted or tilted.
- a detonator loading unit 51 is provided at the end of the boom 50b.
- the detonator loading unit 51 moves into the charging hole 72 by expanding / contracting or tilting the boom 50b.
- the detonator loading unit 51 holds the detonator detonator 10 or releases the detonator detonator 10.
- the detonator detonator 10 is loaded into the charging hole 72.
- the detonator loading unit 51 has a power supply device 52 that supplies operating energy to the power receiving coil 12 of the detonator detonator 10 before being loaded into the charging hole 72.
- the power feeding device 52 has a cylindrical body 52a that is tubular and has openings on both sides.
- the cylinder body 52a has a feeding coil (antenna) 53 wound in an annular shape.
- the feeding coil 53 is wound along the outer peripheral surface of the cylinder body 52a.
- the number of turns of the feeding coil 53 is one or more turns, for example, ten or more turns.
- the opening 52b of the cylinder body 52a has an inner diameter larger than the outer diameter of the power receiving coil 12 wound around the outer peripheral surface of the detonator body 11.
- the feeding coil 53 transmits a specific electromagnetic wave by generating an electric field or a magnetic field around the feeding coil 53 when a current having a specific frequency, amplitude, and wavelength flows.
- the feeding coil 53 receives various signals having a specific frequency and amplitude when exposed to a specific electromagnetic field.
- the feeding coil 53 communicates with the power receiving coil 12 at, for example, 1 k to 500 kHz, preferably 200 kHz, for example.
- the detonator loading unit 51 has a loading unit side communication device 55 that can communicate with the power receiving coil 12 of the detonator detonator 10 before being loaded into the charge hole 72.
- the loading unit side communication device 55 includes a control circuit (CPU) 58, an input unit 56, and a display unit 57.
- the control circuit 58 outputs an electric signal to each electric component based on the input of the electric signal from each electric component of the loading unit side communication device 55.
- the input unit 56 includes, for example, a keyboard, a switch, a touch panel, and the like.
- the display unit 57 includes, for example, a display, a lamp for turning on / off, and the like. The operator operates the input unit 56 while checking the information displayed on the display unit 57.
- the input unit 56 and the display unit 57 are electrically connected to the control circuit 58, respectively.
- the loading unit side communication device 55 has a power supply 59 that supplies electric power to the control circuit 58, a memory 60, and a power supply circuit 61.
- the control circuit 58 records information such as the ID number of the detonator detonator 10 in the memory 60 based on the command, reads out the stored data in the memory 60, or calculates based on the algorithm stored in the memory 60.
- the power supply circuit 61 is electrically connected to the power supply 59 and the power supply coil 53.
- the control circuit 58 outputs a current from the power supply 59 to the power supply coil 53 via the power supply circuit 61 based on the command.
- the loading unit side communication device 55 has a loading unit modem 62 connected to the feeding coil 53 and the control circuit 58.
- the loading unit modem 62 has a receiving circuit 62a and a transmitting circuit 62b.
- the receiving circuit 62a and the transmitting circuit 62b are connected to the feeding coil 53 and the control circuit 58, respectively.
- the receiving circuit 62a demodulates the analog signal received by the feeding coil 53 into a digital signal.
- the transmission circuit 62b modulates the digital signal transmitted from the control circuit 58 into an analog signal.
- the transmission circuit 62b outputs, for example, a current having a specific frequency of 1 k to 500 kHz related to a setting signal of the detonation delay time and the like and a specific code signal set to the feeding coil 53.
- the operator drills a plurality of charge holes 72 and one or more insertion holes 74 in the face surface 71 in preparation for blasting as referred to FIG. 1 (step S1 in FIG. 6).
- the charge hole 72 and the insertion hole 74 are drilled to, for example, a diameter of about 5 cm and a depth of about 2 m.
- the detonator body 11 of the detonator detonator 10 is inserted into the cylinder body 52a of the power feeding device 52 along the longitudinal direction (step S2).
- the power receiving coil 12 is arranged inward in the radial direction of the feeding coil 53.
- the operator operates the input unit 56 (see FIG. 5) to start the charging process of the detonator tube 10 (step S3).
- the control circuit 58 of the communication device 55 on the loading unit side receives an input signal from the input unit 56 and outputs a current to the feeding coil 53 via the feeding circuit 61 (step S11 in FIG. 7). ..
- the feeding coil 53 generates, for example, a magnetic field having a frequency of 1 k to 500 kHz (step S12).
- the power receiving coil 12 of the detonator detonator 10 receives the magnetic field and generates an electric current (step S13).
- the tuning circuit 22 tunes to the frequency of the current generated by the power receiving coil 12 (step S14).
- the rectifying element 23 rectifies the received current into a direct current (step S15).
- the power storage circuit 25 stores electric power by being supplied with a direct current (step S16). Before the current is generated in the power receiving coil 12, the voltage of the power storage circuit 25 is 0V. When the voltage of the power storage circuit 25 is less than a predetermined value, it does not respond to the transmission of the inquiry signal of the ID number from the communication device 55 on the loading unit side (step S17). When responding, the power for controlling the detonator detonator 10 and the power for igniting the detonator ignition unit 13 are sufficiently stored in the power storage circuit 25.
- the power receiving coil 12 receives the inquiry signal of the ID number (step S18), and the receiving circuit 24a demodulates the signal (step S19).
- the control circuit 21 transmits the ID number of the detonator detonator 10 to the transmission circuit 24b (step S20).
- the transmission circuit 24b modulates the signal (step S21) and transmits it to the power receiving coil 12.
- the power receiving coil 12 transmits the modulated signal by, for example, a radio wave of 1 k to 500 kHz (step S22).
- the feeding coil 53 receives the signal as shown in FIG. 5 (step S23).
- the receiving circuit 62a demodulates the signal (step S24) and transmits it to the control circuit 58.
- the control circuit 58 confirms the ID number of the detonator detonator 10 (step S25), and records the ID number in the memory 60.
- the control circuit 58 transmits a setting signal of the detonation delay time according to the ID number of the detonator detonator 10 to the transmission circuit 62b (step S26).
- the transmission circuit 62b modulates the signal (step S27), and the feeding coil 53 generates a magnetic field having a frequency of, for example, 1 k to 500 kHz, and transmits a setting signal of the detonation delay time (step S28).
- the power receiving coil 12 receives the signal (step S29), and the receiving circuit 24a demodulates the signal (step S30).
- the memory 26 records the detonation delay time based on the command of the control circuit 21 (step S31).
- the control circuit 21 transmits a signal for completing the setting of the detonation delay time to the transmission circuit 24b (step S32).
- the transmission circuit 24b modulates the signal (step S33) and transmits it to the power receiving coil 12.
- the power receiving coil 12 transmits the modulated signal by, for example, a radio wave of 1 k to 500 kHz (step S34).
- the feeding coil 53 receives the signal (step S35), the receiving circuit 62a demodulates the signal (step S36), and transmits the signal to the control circuit 58.
- the control circuit 58 confirms that the detonation delay time of the detonator tube 10 has been set (step S37).
- the display unit 57 displays that the charging process (preparation) of the detonator detonator 10 is completed (step S38).
- the power feeding device 52 is provided at the end of the boom 50b of the detonator loading unit 51.
- the power feeding device 52 is provided at a place different from the boom 50b.
- the power feeding device 52 is provided separately from the detonator loading unit 51.
- the operator pulls out the detonator detonator 10 that has been charged from the cylinder body 52a of the power feeding device 52 (step S4 in FIG. 6).
- the operator sets the charged detonator detonator 10 in the explosive delivery unit 50.
- the detonator loading unit 50 loads the detonator detonator 10 and the explosive 2 into the charging hole 72 (step S5).
- the detonator detonator 10 is loaded with the parent die 2a connected to the detonator ignition unit 13 facing forward. A plurality of additional dies 2b are loaded on the front side of the parent die 2a.
- the inlet of the charge hole 72 is sealed by the sealing member 73.
- the operator inserts the relay device 30 into the insertion hole 74 (step S6).
- the rear end 31b having the second transmission / reception antenna 37 is arranged on the far side from the entrance of the insertion hole 74.
- the front end 31a having the first transmission / reception antenna 35 protrudes from the entrance of the insertion hole 74 and is supported by the housing 31.
- the operator installs the blasting operation device 40 at a remote location a predetermined distance from the face surface 71 (step S7). ).
- the explosive delivery unit 50 provided with the detonator loading unit 51 (see FIG. 2) is retracted to a remote location at a predetermined distance from the face surface 71.
- the operator operates the input unit 41 to start the detonation preparation process for the detonator detonator 10 (step S8).
- the control circuit 43 of the blasting operation device 40 receives a signal from the input unit 41 and transmits a detonator preparation signal confirming the soundness of the detonator ignition unit 13 to the transmission circuit 46b (Ste S41 in FIG. 8).
- the transmission circuit 46b modulates the signal (step S42), and the transmission / reception antenna 47 transmits a downlink signal by, for example, a radio wave of 1M to 10 GHz (step S43).
- the first transmitting / receiving antenna 35 of the relay device 30 receives the downlink signal (step S44), and the first antenna side receiving circuit 36a demodulates the signal (step S45).
- the relay processor of the control circuit 32 receives and processes, for example, a high frequency signal of 1M to 10 GHz and transmits a low frequency signal of 1 k to 500 kHz (step S46).
- the second antenna side transmission circuit 38b modulates the signal (step S47), and the second transmission / reception antenna 37 transmits a downlink signal by radio waves of, for example, 1 k to 500 kHz (step S48).
- the power receiving coil 12 receives the downlink signal (step S49), and the receiving circuit 24a demodulates the signal (step S50).
- the resistance measuring circuit 28 measures the electric resistance of the detonator ignition unit 13 based on the output from the control circuit 21 (step S51).
- the control circuit 21 determines whether or not the soundness (electricity) of the detonator ignition unit 13 is good or bad from the measured resistance value (step S52).
- the control circuit 21 transmits a signal of good or bad of the soundness of the detonator ignition unit 13 to the transmission circuit 24b (step S53).
- the transmission circuit 24b modulates the signal (step S54), and the power receiving coil 12 (for example, a transmission / reception antenna) transmits an uplink signal by radio waves of, for example, 1 k to 500 kHz (step S55).
- the second transmitting / receiving antenna 37 receives the upstream signal (step S56), and the second antenna side receiving circuit 38a demodulates the signal (step S57).
- the relay processor of the control circuit 32 receives and processes a low frequency signal of, for example, 1 k to 500 kHz, and transmits a high frequency signal of 1 M to 10 GHz (step S58).
- the first antenna side transmission circuit 36b modulates the signal (step S59), and the first transmission / reception antenna 35 transmits an uplink signal by, for example, a radio wave of 1M to 10 GHz (step S60).
- the transmission / reception antenna 47 receives the upstream signal (step S61), and the reception circuit 46a modulates (for example, demodulates) the signal (step S62).
- the control circuit 43 causes the display unit 42 to display that the detonator detonator 10 is ready for detonation (step S64).
- the soundness of the detonator ignition unit 13 of the detonator detonator 10 having a predetermined ID number is not good (step S63)
- the soundness of the ID number of the detonator detonator 10 and the detonator ignition unit 13 is good on the display unit 42. Display that it is not.
- the operator operates the input unit 41 to start the detonation process for the detonator detonator 10 (step S9 in FIG. 6).
- the operator operates the input unit 41 of the blasting operation device 40, and the control circuit 43 receives the signal from the input unit 41 and transmits the detonation signal to the transmission circuit 46b (step S71 in FIG. 9). ).
- the transmission circuit 46b modulates the signal (step S72), and the transmission / reception antenna 47 transmits a downlink signal by, for example, a radio wave of 1M to 10 GHz (step S73).
- the first transmitting / receiving antenna 35 of the relay device 30 receives the downlink signal (step S74), and the first antenna side receiving circuit 36a demodulates the signal (step S75).
- the relay processor of the control circuit 32 receives and processes, for example, a high-frequency signal of 1M to 10 GHz and transmits a low-frequency signal of 1 k to 500 kHz (step S76).
- the second antenna side transmission circuit 38b modulates the signal (step S77), and the second transmission / reception antenna 37 transmits a downlink signal by radio waves of, for example, 1 k to 500 kHz (step S78).
- the power receiving coil 12 receives the downlink signal (step S79), and the receiving circuit 24a demodulates the signal (step S80).
- the control circuit 21 activates an internal timer when the detonation signal is received. It is determined whether or not the time by the timer has reached the detonation delay time recorded in the memory 26 (step S81). The determination is repeated until the timer count time reaches the detonation delay time. When the count time of the timer reaches the detonation delay time, the control circuit 21 outputs an ON signal to the detonation switch 27 (step S82).
- the detonator switch 27 is turned on to be in a connected state (step S83), and the power storage circuit 25 transmits power to the detonator ignition unit 13 via the detonator switch 27 (step S84).
- the detonator ignition unit 13 ignites (step S85), and the explosive 2 (see FIG. 3) detonates.
- the wireless detonation system 1 has a blasting operation device 40, a detonator detonator 10, and a relay device 30 as shown in FIG.
- the blasting operation device 40 is installed away from the face surface 71 and transmits a first downlink radio signal of the first frequency.
- the detonator detonator 10 includes a power receiving coil 12 that is loaded in the charging hole 72 of the face surface 71 and receives a second downlink radio signal having a second frequency lower than the first frequency.
- the relay device 30 is a relay processor of the first transmission / reception antenna 35 that receives the first downlink radio signal and the control circuit 32 that receives and processes the first downlink radio signal and transmits the second downlink radio signal of the second frequency.
- a second transmission / reception antenna 37 for transmitting a second downlink radio signal.
- the second transmission / reception antenna 37 is loaded into the insertion hole 74 of the face surface 71 which is aligned with the charge hole 72.
- the relay device 30 and the detonator detonator 10 wirelessly communicate with each other at the second frequency, which is a relatively low frequency.
- the relay device 30 and the detonator detonator 10 wirelessly communicate with each other at a low frequency that passes through the bedrock or the like constituting the blasting target. Since the relay device 30 and the detonator tube 10 are both installed in the charge hole 72 or the insertion hole 74 formed in the face surface 71, they are located close to each other. Therefore, for example, the relay device 30 and the detonator detonator 10 can communicate with each other with a radio signal having a small power of 10 W or less.
- the relay device 30 and the blasting operation device 40 wirelessly communicate with each other by the first frequency, which is a high frequency. Therefore, it is possible to prevent the signal from leaking to the periphery such as outside the tunnel 70 which is the target of blasting.
- the detonator detonator 10 has a power receiving coil 12 for transmitting a second upstream radio signal of the second frequency.
- the relay device 30 is a relay processor of the second transmission / reception antenna 37 that receives the second uplink radio signal and the control circuit 32 that receives and processes the second uplink radio signal and transmits the first uplink radio signal of the first frequency. And has a first transmit / receive antenna 35 that transmits a first uplink radio signal.
- the blasting operation device 40 receives the first uplink radio signal. Therefore, the above-mentioned effect can be obtained not only in the downlink radio signal transmitted from the blasting operation device 40 to the detonator tube 10 via the relay device 30, but also in the reverse upstream radio signal.
- the explosive side receiving antenna and the explosive side transmitting antenna are common power receiving coils 12.
- the first receiving antenna and the first transmitting antenna are the common first transmitting / receiving antenna 35.
- the second receiving antenna and the second transmitting antenna are the common second transmitting / receiving antenna 37. Therefore, the number of parts of the entire wireless detonation system 1 can be reduced.
- the relay device 30 has a housing 31 in which a part or the whole is inserted into the insertion hole 74.
- the housing 31 is integrally provided with a first transmission / reception antenna 35, a second transmission / reception antenna 37, and a control circuit 32 provided with a relay processor. Therefore, the relay device 30 is supported by the blasting target via the housing 31. Therefore, the relay device 30 is easily inserted into and supported by the blasting target.
- the housing 31 has a back end 31b installed on the back side of the insertion hole 74.
- a second transmitting / receiving antenna 37 is provided at the rear end.
- the first transmission / reception antenna 35 is provided at the front end of the housing 31 on the opposite side of the back end. Therefore, the second transmission / reception antenna 37 is located near the detonator detonator 10 loaded in the back side of the charge hole 72. Therefore, the relay device 30 and the detonator detonator 10 can communicate with each other by a signal with a small power of, for example, 10 W or less.
- the first transmission / reception antenna 35 is located near the opening of the insertion hole 74. Therefore, the first transmission / reception antenna 35 can communicate with the blasting operation device 40 by a wireless signal without being relatively disturbed by the rock mass or the like constituting the blasting target.
- the front end 31a of the housing 31 is installed together with the first transmission / reception antenna 35 so as to protrude from the face surface 71 from the insertion hole 74. Therefore, the relay device 30 and the blasting operation device 40 can communicate with each other by wireless signals without being obstructed by the rock mass or the like constituting the blasting target. Further, the first transmission / reception antenna 35 protrudes from the face surface 71 by using the housing 31 held by the blasting target. Therefore, the first transmission / reception antenna 35 is supported by the blasting target with a simple structure.
- the second frequency is 1 kHz to 500 kHz that passes through the bedrock.
- the first frequency is 1 MHz to 10 GHz. Therefore, the relay device 30 and the detonator detonator 10 can preferably wirelessly communicate in the bedrock. Further, the frequency bands of the first frequency and the second frequency are separated. Therefore, interference between the signal of the first frequency and the signal of the second frequency is suppressed, and erroneous communication can be prevented.
- the detonator loading unit 51 has a loading unit side communication device 55 capable of communicating with a power receiving coil 12 of the detonator detonator 10 before being loaded into the charging hole 72 by a radio signal of the second frequency. Therefore, the step of communicating the detonator tube 10 and the communication device 55 on the loading unit side and the step of loading the detonator tube 10 into the charging hole 72 can be efficiently performed in a series of flows. Further, the power receiving coil 12 received from the loading unit side communication device 55 and the power receiving coil 12 received from the relay device 30 can be shared. Therefore, the number of parts of the detonator detonator 10 can be reduced.
- the detonator detonator 10 has a power receiving coil 12 for receiving operating energy and a storage circuit 25 for storing operating energy.
- the detonator loading unit 51 has a feeding coil 53 that supplies operating energy to the power receiving coil 12 of the detonator detonator 10 before being loaded into the charging hole 72. Therefore, the power storage circuit 25 can maintain a state in which the operating energy is not stored until immediately before the detonator tube 10 is loaded into the charge hole 72. Therefore, when the detonator detonator 10 is transported to the face surface 71, it can be transported in a stable state with low energy. Further, power is supplied to the detonator detonator 10 immediately before being loaded into the charge hole 72. Therefore, for example, a capacitor having a relatively small capacity can be used for the power storage circuit 25. Thus, the cost of the detonator detonator 10 can be reduced. In addition, the work can be done efficiently because the power supply time can be shortened.
- a detonator loading unit 51 is provided in the explosive delivery unit 50 that delivers the explosive to be loaded in the charge hole 72. Therefore, the step of loading the detonator tube 10 into the charge hole 72 and the step of loading the explosive to the front side of the detonator tube 10 of the charge hole 72 can be efficiently performed in a series of flows.
- the relay device 30 has a second transmission / reception antenna 37, a control circuit 32 including a relay processing device, and a first transmission / reception antenna 35.
- the second transmission / reception antenna 37 receives the second uplink radio signal of the second frequency transmitted from the detonator detonator 10.
- the relay processing machine receives and processes the second uplink radio signal, and transmits and processes the first uplink radio signal of the first frequency.
- the first transmission / reception antenna 35 transmits the first uplink radio signal.
- the second transmission / reception antenna 37, the relay processor, and the first transmission / reception antenna 35 are mounted on the housing 31. Therefore, the above-mentioned effect can be obtained not only in the downlink radio signal transmitted from the blasting operation device 40 to the detonator tube 10 via the relay device 30, but also in the reverse upstream radio signal.
- the blasting operation device 40 is installed at a position away from the blasting target.
- the relay device 30 is installed in the insertion hole 74 to be blasted.
- the blasting operation device 40 and the first transmission / reception antenna 35 of the relay device 30 communicate with each other by a radio signal of 1 MHz to 10 GHz, which is the first frequency.
- the detonator detonator 10 is installed in the charge hole 72 to be blasted.
- the detonator tube 10 and the second transmission / reception antenna 37 of the relay device 30 communicate with each other by a radio signal of 1 kHz to 500 kHz, which is the second frequency.
- the relay processor of the relay device 30 receives and processes the signal of the first frequency, and processes the transmission of the signal of the second frequency. Further, the relay processor of the relay device 30 receives and processes the signal of the second frequency, and also processes the transmission of the signal of the first frequency.
- the relay device 30 and the detonator detonator 10 communicate with each other by a radio signal of 1 kHz to 500 kHz that passes through, for example, the bedrock constituting the blasting target. Since the relay device 30 and the detonator tube 10 are both installed in the charge hole 72 or the insertion hole 74 formed in the face surface 71, they are located close to each other. Therefore, for example, the relay device 30 and the detonator detonator 10 can communicate with each other with a radio signal having a small power of 10 W or less. On the other hand, the relay device 30 and the blasting operation device 40 communicate with each other by a relatively high radio signal of 1 MHz to 10 GHz. Therefore, it is possible to prevent the signal from leaking to the periphery such as outside the tunnel 70 which is the target of blasting.
- the blasting operation device 40 transmits the first downlink radio signal of the first frequency to the relay device 30.
- the relay processor of the relay device 30 receives and processes the first downlink radio signal, and transmits and processes the second downlink radio signal of the second frequency.
- the relay device 30 transmits the second downlink radio signal to the detonator detonator 10. Therefore, the downlink radio signal of the first frequency transmitted from the blasting operation device 40 to the relay device 30 can be prevented from leaking to the periphery such as outside the tunnel 70 to be blasted.
- the downlink radio signal of the second frequency transmitted from the relay device 30 to the detonator detonator 10 passes through the bedrock or the like constituting the blasting target. Therefore, a downlink radio signal can be suitably transmitted from the blasting operation device 40 to the detonator detonator 10 via the relay device 30.
- the wireless detonation system 80 of the second embodiment has the relay device 81 shown in FIG. 10 in place of the relay device 30 of the wireless detonation system 1 shown in FIG.
- the relay device 81 has a power receiving coil 85 wound in an annular shape on the outer peripheral surface of the substantially cylindrical housing 82 instead of the second transmitting / receiving antenna 37 (see FIG. 5).
- the number of turns of the power receiving coil 85 is one or more turns, for example, ten or more turns.
- the power receiving coil 85 generates an electric current when exposed to an electromagnetic field, and the electric current is used as electric power for operating the relay device 81.
- the power receiving coil 85 also serves as a second transmitting / receiving antenna for transmitting / receiving a radio signal of, for example, 1 k to 500 kHz.
- the relay device 81 has a tuning circuit 86 electrically connected to the power receiving coil 85, a rectifying element 87, and a storage circuit 84 instead of the power supply 33 (see FIG. 5).
- the tuning circuit 86 tunes to the reception frequency of the current generated when the power receiving coil 85 receives electric power.
- the rectifying element 87 rectifies the current input from the tuning circuit 86 into a direct current.
- the power storage circuit 84 is, for example, a capacitor or the like, and stores the power rectified by the rectifying element 87 as the power for operating each electronic component of the relay device 81.
- the control circuit 58 of the communication device 55 on the loading unit side receives an input signal from the input unit 56 and outputs a current to the feeding coil 53 via the feeding circuit 61 (step of FIG. 11).
- the feeding coil 53 generates, for example, a magnetic field having a frequency of 1 k to 500 kHz (step S102).
- the power receiving coil 85 of the relay device 81 receives the magnetic field and generates a current (step S103).
- the tuning circuit 86 tunes to the frequency of the current generated by the power receiving coil 85 (step S104).
- the rectifying element 87 rectifies the received current into a direct current (step S105).
- the power storage circuit 84 stores electric power by being supplied with a direct current (step S106).
- the voltage of the power storage circuit 84 is less than a predetermined value, it does not respond to the transmission of the inquiry signal of the ID number from the communication device 55 on the loading unit side (step S107).
- the power for operating the relay device 81 is sufficiently stored in the power storage circuit 84.
- the power receiving coil 85 receives the inquiry signal of the ID number (step S108), and the second antenna side receiving circuit 38a demodulates the signal (step S109).
- the control circuit 83 transmits the ID number of the power storage circuit 84 to the second antenna side transmission circuit 38b (step S110).
- the second antenna side transmission circuit 38b modulates the signal (step S111), and the power receiving coil 85 transmits the signal by radio waves of, for example, 1 k to 500 kHz (step S112).
- the feeding coil 53 receives the signal as shown in FIG. 10 (step S113).
- the receiving circuit 62a demodulates the signal (step S114) and transmits it to the control circuit 58.
- the control circuit 58 confirms the response of the ID number of the relay device 81 to confirm the completion of charging (step S115), and causes the display unit 57 to indicate that the charging process of the relay device 81 is completed.
- the relay device 81 includes a power receiving coil 85 that receives operating energy from the feeding coil 53 of the detonator loading unit 51, and a storage circuit 84 that stores operating energy.
- the relay device 81 can also be fed by using the feeding coil 53 that feeds the detonator tube 10 (see FIG. 5). Therefore, the number of parts of the entire wireless detonation system 80 can be reduced.
- the relay device 81 is stored in the power storage circuit 84 immediately before being inserted into the insertion hole 74. Therefore, the storage capacity of the storage circuit 84 can be reduced to the minimum amount required for communication.
- the detonator loading unit 51 wirelessly supplies power to the detonator detonator 10 (see FIG. 1) and the relay device 81 in the vicinity of the blasting target.
- the detonator detonator 10 in which the detonator loading unit 51 is stored is loaded into the charge hole 72 (see FIG. 1) to be blasted.
- the relay device 81 in which the detonator loading unit 51 is stored is loaded into the insertion hole 74 (see FIG. 1) to be blasted. Therefore, the step of charging the detonator tube 10 and loading it into the charging hole 72, or the step of charging the relay device 81 and loading it into the insertion hole 74 can be efficiently performed in a series of flows in the vicinity of the face surface 71. ..
- the power feeding device 52 is provided in the detonator loading unit 51.
- the detonator detonator 10 is sent to the detonator loading unit 51 by the explosive delivery unit 50.
- the detonator tube 10 is inserted into the cylinder body 52a from the inlet of the cylinder body 52a of the power feeding device 52.
- the detonator tube 10 is charged by the power feeding device 52, and then the detonator tube 10 is discharged from the outlet of the cylinder body 52a by the detonator loading unit 51. Therefore, the detonator detonator 10 moves in a straight line, penetrates the cylinder body 52a, and is loaded into the charging hole 72.
- the wireless detonation system 90 of the third embodiment has the relay device 91 shown in FIG. 12 in place of the relay device 30 of the wireless detonation system 1 shown in FIG.
- the relay device 91 has a cylindrical housing 92 having a front end 92a at one end and a back end 92b at the other end.
- the back end 92b is arranged in the inner part of the insertion hole 74 having substantially the same depth as the detonator detonator 10 inserted into the charge hole 72.
- the front end 92a is housed inside the insertion hole 74 and is arranged on the front side of the back end 92b.
- the relay device 91 has a first transmission / reception antenna 93 at the front end 92a and a second transmission / reception antenna 95 at the rear end 92b.
- the first transmission / reception antenna 93 extends toward the front side of the insertion hole 74 and protrudes from the entrance of the insertion hole 74.
- the first transmission / reception antenna 93 transmits / receives radio waves of, for example, 1 M to 10 GHz, preferably 100 MHz or more, for example, 920 MHz, which are difficult to transmit in the soil or rock.
- the second transmission / reception antenna 95 transmits / receives radio waves having good transparency in the soil or bedrock, for example, 1 k to 500 kHz, preferably 200 kHz.
- the relay device 91 has a first modem 94 arranged on the front end 92a side and a second modem 96 arranged on the back end 92b side.
- a relay processing machine 97 and a power supply are provided between the first modem 94 and the second modem 96.
- the relay processing machine 97 receives and processes the input signal, and transmits and processes signals having different frequencies.
- the first modem 94 demodulates the analog signal received by the first transmission / reception antenna 93 into a digital signal.
- the first modem 94 modulates the digital signal transmitted from the second modem 96 via the relay processor 97 into an analog signal.
- the second modem 96 demodulates the analog signal received by the second transmission / reception antenna 95 into a digital signal.
- the second modem 96 modulates the digital signal transmitted from the first modem via the relay processor 97 into an analog signal.
- the front end 92a of the housing 92 is accommodated and installed inside the insertion hole 74.
- the first transmission / reception antenna 93 extends from the front end 92a toward the entrance of the insertion hole 74 and protrudes from the entrance of the insertion hole 74. Therefore, between the relay device 91 installed at the back side of the insertion hole 74 and the blasting operation device 40 outside the insertion hole 74, it is difficult to pass through the soil or the bedrock, for example, at the first frequency of 1M to 10GHz. Can be sent and received well.
- the housing 92 can be made compact with respect to the insertion hole 74. Therefore, it is easy to insert the relay device 91 into the insertion hole 74 and install it.
- the wireless detonation system 100 of the fourth embodiment has the relay device 101 shown in FIG. 13 in place of the relay device 30 of the wireless detonation system 1 shown in FIG. Further, the wireless detonation system 100 has a second relay device 108.
- the relay device 101 is configured in the same manner as the relay device 91 (see FIG. 12).
- the rear end 102b of the housing 102 of the relay device 101 is arranged in the inner part of the insertion hole 74.
- the front end 102a of the housing 102 is housed inside the insertion hole 74 and is arranged on the front side of the back end 102b.
- the front end 102a is provided with a first transmission / reception antenna 103 for transmitting / receiving radio waves of, for example, 1 M to 10 GHz, preferably 100 MHz or more, for example, 920 MHz.
- a second transmission / reception antenna 105 for transmitting / receiving radio waves of, for example, 1 k to 500 kHz, preferably, for example, 200 kHz is provided at the rear end 102b.
- the relay device 101 has a first modem 104 on the front end 102a side, a second modem 106 on the rear end 102b side, a relay processing machine 107 arranged between them, and a power supply (not shown). ..
- the relay processing machine 107 receives and processes the input signal, and transmits the signal having a different frequency.
- the first modem 104 and the second modem 106 demodulate the analog signals received by the first transmit / receive antenna 103 and the second transmit / receive antenna 105 into digital signals, respectively.
- the first modem 104 and the second modem 106 modulate the digital signals transmitted from the second modem 106 and the first modem 104 into analog signals via the relay processor 107, respectively.
- the second relay device 108 is installed at the entrance of the insertion hole 74.
- the second relay device 108 has a cylindrical housing 109.
- the housing 109 has a front end 109a arranged at a position protruding from the entrance of the insertion hole 74 and a back end 109b arranged behind the entrance of the insertion hole 74.
- a first transmission / reception antenna 110 is provided at the front end 109a, and a second transmission / reception antenna 112 is provided at the rear end 109b.
- the first transmission / reception antenna 110 protrudes from the entrance of the insertion hole 74 together with the front end 109a.
- the first transmitting / receiving antenna 110 and the second transmitting / receiving antenna 112 transmit / receive radio waves of, for example, 1 M to 10 GHz, preferably 100 MHz or more, for example, 920 MHz, which are difficult to transmit in the soil or rock.
- the second relay device 108 has a modem 111, a relay processor 113, and a power supply (not shown).
- the modem 111 demodulates the analog signal received by the first transmit / receive antenna 110 or the second transmit / receive antenna 112 into a digital signal.
- the relay processing machine 113 receives and processes the signal input from the modem 111, regenerates the signal in the same frequency band, and performs the transmission processing.
- the modem 111 modulates the digital signal transmitted from the relay processor 113 into an analog signal. Modulated signals are transmitted from the first transmit / receive antenna 110 and the second transmit / receive antenna 112.
- the front end 102a of the housing 102 is housed and installed inside the insertion hole 74.
- a second relay device 108 is installed at the entrance of the insertion hole 74.
- the front end 109a protrudes from the entrance of the insertion hole 74
- the rear end 109b is housed inside the insertion hole 74. Therefore, between the relay device 101 installed at the back side of the insertion hole 74 and the blasting operation device 40 outside the insertion hole 74, transmission / reception can be performed satisfactorily at the first frequency which is difficult to penetrate in the soil or the bedrock.
- the housing 102 can be made compact with respect to the insertion hole 74. Therefore, it is easy to insert the relay device 101 installed on the back side of the insertion hole 74 into the insertion hole 74.
- one form of the present disclosure has been described with reference to the above structure, it is possible for those skilled in the art to be able to make many substitutions, improvements and changes without departing from the purpose of the one form of the present disclosure. it is obvious. Accordingly, one form of the present disclosure may include all substitutions, improvements and modifications that do not deviate from the spirit and purpose of the attached claims. For example, one form of the present disclosure is not limited to the above-mentioned special structure, and can be modified as follows.
- the wireless detonation systems 1, 80 can be used for excavation work of the tunnel 70 as described above. Instead of this, it may be applied to, for example, crushing work of a structure such as a building or excavation work of the seabed.
- the detonator detonator 10 of the above embodiment has a power receiving coil 12 that also serves as a transmission / reception antenna. Instead of this, the detonator detonator 10 may have a transmission / reception antenna separate from the power receiving coil 12, or a receiving antenna and a transmitting antenna separate from the power receiving coil 12 and separate from each other.
- the blasting operation device 40 may have a receiving antenna and a transmitting antenna that are separate from each other, instead of the transmitting / receiving antenna 47.
- the loading unit side communication device 55 of the above embodiment has a feeding coil 53 that also serves as a transmission / reception antenna.
- the loading unit-side communication device 55 may have an antenna separate from the feeding coil 53, or a receiving antenna and a transmitting antenna separate from the feeding coil 53 and separate from each other.
- the relay device 81 has, for example, a second transmission / reception antenna separate from the power reception coil 85, or a second reception antenna and a second transmission antenna separate from the power reception coil 85 and separate from each other. Is also good.
- the relay device 30 of the above embodiment has a housing 31 in which a first transmission / reception antenna 35, a second transmission / reception antenna 37, and a control circuit 32 provided with a relay processing machine are integrally provided in the housing 31.
- the relay device 30 may have, for example, three housings, and the first transmission / reception antenna 35, the second transmission / reception antenna 37, and the control circuit 32 may be provided in any of the three housings.
- the loading unit side communication device 55 of the above embodiment is mounted on the detonator loading unit 51.
- the loading unit side communication device 55 may be, for example, a handy type separate from the detonator loading unit 51.
- the detonator loading unit 51 may have a plurality of loading unit side communication devices 55.
- the detonator loading unit 51 and the explosive delivery unit 50 may be separate.
- the detonator loading unit 51 may be charged by the detonator loading unit 51 and loaded into the charging hole 72 by a nearby operator, or may be automatically performed according to a program prepared in advance.
- the detonator detonator 10 of the above embodiment has one power storage circuit 25.
- the detonator detonator 10 may have, for example, two power storage circuits 25.
- one storage circuit 25 can store the operating energy of each electronic component
- the other storage circuit 25 can store the ignition energy of the detonator ignition unit 13.
- the detonator detonator 10 may be, for example, a non-rechargeable type having a power source in which electric power is stored in advance.
- the power sources of the relay devices 91, 101 and the second relay device 108 may be either rechargeable or non-rechargeable.
- An example is a second relay device 108 that regenerates and transmits a signal received at the second frequency at the same second frequency.
- the second relay device 108 may transmit the received signal as it is to the inside or the outside of the insertion hole 74.
- One relay device 30 or 81 may be used for each blasting, or a plurality of relay devices 30 and 81 may be used.
- the radio signal of the first frequency may have the same frequency for uplink and downlink, and may have different frequencies within the range of, for example, 1M to 10GHz.
- the radio signal of the second frequency may have the same frequency for uplink and downlink, and may have different frequencies within the range of, for example, 1 k to 500 kHz.
- the relay device 30 may be configured to be arranged only at the front end of the insertion hole 74, for example.
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Abstract
Description
Claims (21)
- 無線起爆システムであって、
発破対象から離間して設置されかつ第1周波数の第1下り無線信号を送信する発破操作装置と、
前記発破対象の装薬孔に装填されかつ前記第1周波数よりも低い第2周波数の第2下り無線信号を受信する爆薬側受信アンテナを備える起爆***と、
前記第1下り無線信号を受信する第1受信アンテナと、前記第1下り無線信号を受信処理し、前記第2周波数の前記第2下り無線信号で送信処理する中継処理機と、前記第2下り無線信号を送信する第2送信アンテナを備える中継装置を有し、
前記第2送信アンテナが前記装薬孔と並んだ前記発破対象の挿入孔に装填される無線起爆システム。 - 請求項1に記載の無線起爆システムであって、
前記起爆***は、前記第2周波数の第2上り無線信号を送信する爆薬側送信アンテナを有し、
前記中継装置は、前記第2上り無線信号を受信する第2受信アンテナと、前記第2上り無線信号を受信処理し、前記第1周波数の第1上り無線信号で送信処理する中継処理機と、前記第1上り無線信号を送信する第1送信アンテナを有し、
前記発破操作装置が前記第1上り無線信号を受信する無線起爆システム。 - 請求項2に記載の無線起爆システムであって、
前記爆薬側受信アンテナと前記爆薬側送信アンテナが共通のアンテナであり、
前記第1受信アンテナと前記第1送信アンテナが共通のアンテナであり、
前記第2受信アンテナと前記第2送信アンテナが共通のアンテナである無線起爆システム。 - 請求項1~3のいずれか1つに記載の無線起爆システムであって、
前記中継装置は、前記挿入孔に一部または全部が挿入されるハウジングを有し、前記ハウジングに前記第1受信アンテナと前記第2送信アンテナと前記中継処理機が一体に設けられる、
または前記中継装置は、前記挿入孔に挿入される複数のハウジングを有し、前記複数のハウジングのいずれかに前記第1受信アンテナが設けられ、前記複数のハウジングのいずれかに前記第2送信アンテナが設けられ、前記複数のハウジングのいずれかに前記中継処理機が設けられる無線起爆システム。 - 請求項4に記載の無線起爆システムであって、
前記ハウジングは、前記挿入孔の奥側に設置される奥側端を有し、前記奥側端に前記第2送信アンテナが設けられ、
前記奥側端の反対側の前記ハウジングの手前端に前記第1受信アンテナが設けられる無線起爆システム。 - 請求項5に記載の無線起爆システムであって、
前記ハウジングの前記手前端が前記第1受信アンテナとともに前記挿入孔から前記発破対象から飛び出て設置される無線起爆システム。 - 請求項1~6のいずれか1つに記載の無線起爆システムであって、
前記第2周波数は、岩盤を透過する1kHz~500kHzであり、
前記第1周波数は、1MHz~10GHzである無線起爆システム。 - 請求項1~7のいずれか1つに記載の無線起爆システムであって、
前記起爆***を前記装薬孔に装填する***装填ユニットを有し、
前記***装填ユニットは、前記装薬孔に装填する前の前記起爆***の前記爆薬側受信アンテナに対して前記第2周波数の無線信号で通信可能な装填ユニット側通信装置を有する無線起爆システム。 - 請求項8に記載の無線起爆システムであって、
前記起爆***は、動作用エネルギーを受信する受電コイルと、前記動作用エネルギーを蓄電するコンデンサを有し、
前記***装填ユニットは、前記装薬孔に装填される前の前記起爆***の前記受電コイルに前記動作用エネルギーを給電する給電コイルを有する無線起爆システム。 - 請求項9に記載の無線起爆システムであって、
前記中継装置は、前記***装填ユニットの前記給電コイルから動作用エネルギーを受信する受電コイルと、前記動作用エネルギーを蓄電するコンデンサを有する無線起爆システム。 - 請求項8~10のいずれか1つ記載の無線起爆システムであって、
前記装薬孔に装填される爆薬を送出する爆薬送出ユニットに前記***装填ユニットが設けられた無線起爆システム。 - 無線起爆システム用中継装置であって、
発破対象から離間して設置された発破操作装置から第1周波数の第1下り無線信号を受信する第1受信アンテナと、
前記第1下り無線信号を受信処理し、前記第1周波数よりも低い第2周波数の第2下り無線信号で送信処理する中継処理機と、
前記第2下り無線信号を前記発破対象の装薬孔に装填された起爆***の爆薬側受信アンテナへ送信する第2送信アンテナと、
前記第1受信アンテナと前記中継処理機と前記第2送信アンテナが装着されたハウジングを有し、前記ハウジングが前記装薬孔と並んだ前記発破対象の挿入孔に装填される無線起爆システム用中継装置。 - 請求項12に記載の無線起爆システム用中継装置であって、
前記起爆***から送信された前記第2周波数の第2上り無線信号を受信する第2受信アンテナと、
前記第2上り無線信号を受信処理し、前記第1周波数の第1上り無線信号で送信処理する中継処理機と、
前記第1上り無線信号を送信する第1送信アンテナを有し、
前記第2受信アンテナと前記中継処理機と前記第1送信アンテナが前記ハウジングに装着されている無線起爆システム用中継装置。 - 請求項13に記載の無線起爆システム用中継装置であって、
前記第1受信アンテナと前記第1送信アンテナが共通のアンテナであり、
前記第2受信アンテナと前記第2送信アンテナが共通のアンテナである無線起爆システム用中継装置。 - 請求項12~14のいずれか1つに記載の無線起爆システム用中継装置であって、
前記挿入孔の奥側に設置される前記ハウジングの奥側端に前記第2送信アンテナが設けられ、
前記奥側端の反対側の前記ハウジングの手前端に前記第1受信アンテナが設けられる無線起爆システム用中継装置。 - 請求項15に記載の無線起爆システム用中継装置であって、
前記ハウジングの前記手前端が前記第1受信アンテナとともに前記挿入孔から前記発破対象から飛び出て設置される無線起爆システム用中継装置。 - 請求項12~16のいずれか1つに記載の無線起爆システム用中継装置であって、
前記第2周波数は、岩盤を透過する1kHz~500kHzであり、
前記第1周波数は、1MHz~10GHzである無線起爆システム用中継装置。 - 無線起爆システムを用いた無線起爆方法であって、
発破対象から離間した位置に設置された発破操作装置と前記発破対象の挿入孔に設置された中継装置の第1アンテナが相互に第1周波数である1MHz~10GHzの無線信号で通信し、
前記発破対象の装薬孔に設置された起爆***と前記中継装置の第2アンテナが相互に第2周波数である1kHz~500kHzの無線信号で通信し、
前記中継装置の中継処理機が前記第1周波数の信号を受信処理しかつ前記第2周波数の信号で送信処理し、また、前記中継装置の前記中継処理機が前記第2周波数の信号を受信処理しかつ前記第1周波数の信号で送信処理する無線起爆方法。 - 請求項18に記載の無線起爆方法であって、
前記発破操作装置が前記第1周波数の第1下り無線信号を前記中継装置へ送信し、
前記中継装置の前記中継処理機が前記第1下り無線信号を受信処理し、前記第2周波数の第2下り無線信号で送信処理し、
前記中継装置が前記第2下り無線信号を前記起爆***へ送信する無線起爆方法。 - 請求項18または19に記載の無線起爆方法であって、
前記起爆***が前記第2周波数の第2上り無線信号を前記中継装置へ送信し、
前記中継装置の前記中継処理機が前記第2上り無線信号を受信処理し、前記第1周波数の第1上り無線信号で送信処理し、
前記中継装置が前記第1上り無線信号を前記発破操作装置へ送信する無線起爆方法。 - 請求項18~20のいずれか1つに記載の無線起爆方法であって、
***装填ユニットが前記発破対象の近傍において前記起爆***と前記中継装置に無線方式で給電し、
前記***装填ユニットが蓄電された前記起爆***を前記発破対象の前記装薬孔に装填し、
前記***装填ユニットが蓄電された前記中継装置を前記発破対象の前記挿入孔に装填する無線起爆方法。
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CN202180048951.4A CN115836190A (zh) | 2020-07-13 | 2021-07-12 | 无线起爆***、无线起爆***用中继装置以及使用无线起爆***的无线起爆方法 |
US18/015,758 US20230287791A1 (en) | 2020-07-13 | 2021-07-12 | Wireless detonation system, relay device for wireless detonation system, and wireless detonation method using wireless detonation system |
CA3185519A CA3185519A1 (en) | 2020-07-13 | 2021-07-12 | Wireless detonation system, relay device for wireless detonation system, and wireless detonation method using wireless detonation system |
EP21842041.2A EP4180624A1 (en) | 2020-07-13 | 2021-07-12 | Wireless detonation system, relay device for wireless detonation system, and wireless detonation method using wireless detonation system |
AU2021309601A AU2021309601A1 (en) | 2020-07-13 | 2021-07-12 | Wireless detonation system, relay device for wireless detonation system, and wireless detonation method using wireless detonation system |
JP2022536345A JPWO2022014530A1 (ja) | 2020-07-13 | 2021-07-12 | |
KR1020237000931A KR20230035579A (ko) | 2020-07-13 | 2021-07-12 | 무선 기폭 시스템 및 무선 기폭 시스템용 중계 장치 및 무선 기폭 시스템을 사용한 무선 기폭 방법 |
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JP2019066092A (ja) | 2017-09-29 | 2019-04-25 | 日油株式会社 | 無線起爆*** |
Cited By (2)
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WO2023249559A1 (en) * | 2022-06-22 | 2023-12-28 | Orica International Pte Ltd | Systems and methods/processes |
WO2024081975A1 (en) * | 2022-10-11 | 2024-04-18 | Detnet South Africa (Pty) Ltd | Starter detonator |
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US20230287791A1 (en) | 2023-09-14 |
JPWO2022014530A1 (ja) | 2022-01-20 |
CA3185519A1 (en) | 2022-01-20 |
CN115836190A (zh) | 2023-03-21 |
AU2021309601A1 (en) | 2023-02-23 |
KR20230035579A (ko) | 2023-03-14 |
EP4180624A1 (en) | 2023-05-17 |
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