JP2020106249A - Blast system and blast method for drilling bottom of water or seabed - Google Patents

Abstract

To provide a blast system capable of connecting a blast controller and a detonator rationally.SOLUTION: A blast system 1 for drilling a seabed 35 has: an explosive cylinder 30 loaded on the seabed 35; a charge detonator device 2 joined to the explosive cylinder; a blast controller 3 for sending an instruction signal from the sea surface; and a bus line for coupling the blast controller 3 and the charge detonator device 2. The charge detonator device 2 has: a power supplying transmitter for supplying power wirelessly based on the instruction signal from the blast controller 4; an electric storage apparatus for charging the power supplied from the power supplying transmitter wirelessly; and an electric detonator for blasting the explosive cylinder 30 based on the power charged to the electric storage apparatus. A repeater is installed in the middle of the bus line. The bus line has: a control bus line 5 for coupling the blast controller 3 and the repeater; and a blast bus line 6 for coupling the repeater 4 and the explosive cylinder 30.SELECTED DRAWING: Figure 1

Description

The present invention relates to a blasting system and a blasting method for excavating a water bottom or a sea bottom.

Japan has a jurisdiction over 12 times the land area, and mineral resources are buried in that jurisdiction. In recent years, research on mineral resources has been advanced even on the deep sea floor, and development of a method for mining mineral resources on the sea floor is also progressing (Non-Patent Document 1). In that situation, blasting technology using explosives with good economical efficiency is being sought.

Patent Document 1 discloses a method of mining deep-sea bottom mineral resources by blasting. A plurality of blast holes are drilled in a predetermined range of deep sea bottom mineral resources, and a blast hole is loaded with an explosive cartridge. The explosive cartridge is provided with a detonator tube that wirelessly detonates an explosive by ultrasonic waves. A transmitter is suspended from the mother ship in the sea, and an ultrasonic signal is emitted from the transmitter. The detonator element receives the signal and detonates the explosive cartridge. This will blast the seabed.

Patent Document 2 discloses a device that wirelessly supplies electric power to an ignition device provided on the seabed. The apparatus has a loop antenna installed on the sea, and the loop antenna transmits electromagnetic waves into the sea. The ignition device stores an antenna coil, an ignition capacitor circuit, and an ignition circuit. The antenna coil receives an electromagnetic field from the loop antenna and generates a current. The current generated in the antenna coil is charged in the ignition capacitor circuit. The ignition circuit detonates explosives using the electric power charged in the ignition capacitor circuit.

Patent Document 3 discloses an electric detonator used for blasting work on the ground. The electric detonator is connected to the power source by wire. Before the detonation, electric power is supplied from the power source to the detonator via a wire as required. An electric detonator detonates explosives using this electric power.

Patent Document 4 discloses a wireless detonator used for excavating a tunnel on the ground. The detonator includes a detonator loaded in a hole in a facet and a transmitting antenna that wirelessly supplies electric power to the detonator. The transmitting antenna is stretched around the tunnel floor, wall, and ceiling. An electric field or magnetic field is generated by passing a current through the transmitting antenna. The detonator has a receiving coil that generates an electric current by receiving an electric field or a magnetic field, and a power storage unit that stores the electric current from the receiving coil. An electric detonator detonates explosives using the current stored in the power storage unit.

JP, 2018-96075, A JP-A-49-21627 JP, 2010-270950, A International publication 2017/183662

Strategic Innovation Creation Program (SIP) Next Generation Marine Resource Survey Technology (Marine Zipangu Plan) Research and Development Plan Cabinet Office, April 1, 2018

In the detonator disclosed in Patent Documents 1, 2, and 4 described above, a radio wave for charging is difficult to be attenuated in the sea (underwater), and therefore a loop-shaped transmission antenna that emits a long-wave electromagnetic wave is used. It However, the loop-shaped antenna that generates electromagnetic waves of long wavelength is large-scaled and it is not easy to install.

When the electric detonator disclosed in Patent Document 3 is to be used in the sea (underwater), it is conceivable to connect the electric detonator and a power source by wire and then put them into the sea. However, in this case, electric power may be erroneously supplied to the electric detonator. Therefore, it is conceivable to install the electric detonator and then connect the electric detonator to the power source by wire. However, it is not easy to connect an electric detonator to a wire in the sea.

The location of the excavation work may be the deep sea floor. In this case, the distance between the blast controller mounted on the offshore vessel and the detonator including the electric detonator for detonating the explosive installed on the seabed becomes long. As a result, problems such as the need for long-distance electric wires, increased equipment costs, and attenuation of power from the blast controller to the detonator may occur.

Therefore, a blast system that can reasonably connect the blast controller and the detonator has been conventionally required.

One feature of the present disclosure is a blasting system for drilling the seabed or waterbed. The blasting system has an explosive canister loaded on the seabed or the waterbed, a charge detonator joined to the explosive canister, and a blasting controller that sends a command signal from the sea or water. The blast controller and the charging detonator are connected by a bus bar. The charging detonator includes a power feeding communication device, a power storage device, and an electric detonator. The power feeding communication device wirelessly supplies power based on a command signal from the blast control device. The power storage device charges electric power wirelessly supplied from the power feeding communication device. The electric detonator detonates the explosive cylinder based on the electric power charged in the electric storage device. A repeater is installed in the middle of the bus. The busbar has a control busbar connecting the blast controller and the repeater, and a blast busbar connecting the relay and the explosive canister.

Therefore, the busbar is divided into a control busbar and a blast busbar by a repeater. Therefore, it is possible to prevent the busbar from having a single long-distance structure from the ocean to the water or seabed. For example, the control bus bar and the blast bus bar may be made of different materials or different performances. This allows the blast controller and the detonator to be connected reasonably.

The charging detonator wirelessly supplies electric power for the electric detonator. Therefore, it is possible to prevent the electric power from being erroneously supplied to the electric detonator. The charging detonator including the power feeding communication device is joined to the explosive canister, and the power feeding communication device is also close to the explosive canister. Therefore, the wireless distance for power feeding is short, and the charging detonator can be downsized.

According to another feature of the disclosure, the repeater comprises a power supply and supplies the power of the power supply to the charging detonator through the blast bus. Therefore, power is supplied to the charging detonator from the repeater, not the offshore blast controller. Therefore, it is not necessary to supply electric power from the sea to the repeater, and the electric power line for supplying electric power to the control bus connecting them is unnecessary.

According to another feature of the disclosure, the control bus has an optical fiber that carries the command signal from the blast controller as an optical signal. The repeater has a power-supply-side photoelectric conversion communication circuit that converts an optical signal into an electric signal. Therefore, since the control bus is an optical fiber, it is lighter in weight than the electric wire and has a simple structure. Further, since the optical signal is not easily attenuated in the optical fiber, the signal from the blast controller to the charging detonator can be transmitted more accurately.

According to another feature of the disclosure, the charging detonator includes a transmitter circuit for transmitting a notification signal. The repeater has a receiving-side photoelectric conversion communication circuit that converts an electric signal, which is a notification signal received through the blast bus, into an optical signal. The control bus has an optical fiber that transmits a notification signal from the repeater as an optical signal to the blast controller. Therefore, the blast controller can receive the notification signal as an optical signal. Therefore, since the control bus is an optical fiber, it is lighter in weight than the electric wire and has a simple structure. Further, since the optical signal is not easily attenuated in the optical fiber, the signal from the blast controller to the charging detonator can be transmitted more accurately.

According to another feature of the disclosure, the blast busbar connects a plurality of explosive canisters in series. Therefore, the total length of the busbar can be shortened as compared with the form having a plurality of blasting busbars that connect the relay machine and each explosive cylinder.

According to another feature of the disclosure, the repeater has a connector that engages an end of a blast bus bar inserted into the repeater. Therefore, the repeater and the blast busbar can be connected even underwater, which improves workability. Alternatively, by delaying the time when power can be supplied, the safety of installation work of the blasting system is improved.

According to another feature of the present disclosure, the repeater includes a bus bar disconnector that disconnects the blast bus bar from the repeater based on a command signal from the blast controller. Therefore, the relay can be prevented from being involved in the explosion of the blasting work, and the relay can be collected. This allows the repeater to be used repeatedly.

According to another feature of the present disclosure, a busbar disconnecting machine includes a busbar disconnecting detonator for cutting the blast busbar, and a busbar disconnecting explosive that is detonated by the busbar disconnecting detonator. Therefore, it is possible to separate the blast bus and the relay with a relatively simple structure by detonation.

Another feature of the disclosure is a blasting method in a blasting system. The blasting system has a charge detonator that detonates an explosive cylinder loaded on the seabed or the waterbed, and a blasting controller that sends a command signal from the sea or water. The charging detonator and the blast controller are connected by a bus bar via a relay. The blast controller sends a command signal to the charging detonator via the bus. The repeater stores the disconnection time for disconnecting the bus bar from the repeater based on the command signal. The charging detonator stores the detonation time based on the command signal. The relay machine disconnects the bus bar from the relay machine at the disconnection time by using the bus bar disconnector provided in the relay machine. The charging detonator detonates the explosive cylinder in the detonation time after the evacuation time for leaving the repeater from the explosion range has elapsed.

Therefore, before detonating the explosive cylinder by using the charge detonator, the relay can be prevented from being damaged by evacuating it from the explosion affected range of the blasting work, and the relay can be recovered. This allows the repeater to be used repeatedly.

It is a schematic diagram of a blasting system. It is a side view of a relay machine. It is a perspective view of a charge initiation part. It is a perspective view of the detonation cylinder body installed in the seabed or the waterbed. It is a block diagram of the blasting system. It is a flowchart of the blasting operation in the blasting system. It is a partial flowchart of the blasting operation in the blasting system. It is a partial flowchart of the blasting operation in the blasting system.

An embodiment of the present invention will be described with reference to the drawings. As shown in FIG. 1, the blasting system 1 is used, for example, for excavating the seabed 35 in the deep sea 33 by blasting with explosives. The depth of the deep sea 33 is, for example, about 1000 to 1500 m from the sea surface 34 to the sea bottom 35.

As shown in FIG. 1, the blasting system 1 includes a blasting controller 3 installed on a mother ship 32 floating on a sea surface 34, a plurality of explosive cylinders 30 installed on a seabed 35, and a charge detonation provided on each explosive cylinder 30. It has a device 2. The blast controller 3 is connected to the charging detonator 2 by buses 5 and 6. Specifically, the blast controller 3 is connected to the relay 4 by the control bus 5, and the relay 4 is connected to the charging detonator 2 by the blast bus 6. A plurality of charging detonators 2 are connected in series by a blast bus 6.

The blast control machine 3 mounted on the mother ship 32 shown in FIG. 1 has an input device, a display device, and a signal generation device. The input device includes, for example, a keyboard, a switch, a touch panel, and the like. The display device includes, for example, a display and a lamp for turning on/off the light. The operator operates the input device while confirming the information displayed on the display device. For example, the display unit displays the state of the charging detonator 2 and the like. When the operator operates the input device, the signal generator transmits a signal to the control bus 5.

As shown in FIGS. 1 and 2, the control bus 5 has a transmission communication line 5 a for transmitting a signal from the blast controller 3 to the repeater 4. Further, the control bus 5 has a reception communication line 5b for transmitting a signal from the repeater 4 to the blast controller 3. The communication lines 5a and 5b are optical communication lines that communicate using signals as light, for example. The transmission communication line 5a and the reception communication line 5b are protected by being covered with a film. The transmission communication line 5a and the reception communication line 5b are, for example, lightweight optical fibers in which signals are not easily attenuated. The control bus 5 extends to the repeater 4 located near the seabed 35 and is inserted into the repeater 4.

As shown in FIGS. 1 and 2, the relay device 4 mediates the transmission and reception of signals between the blast control device 3 and the charging detonator 2 by way of the bus lines 5 and 6. Further, the repeater 4 is provided with a power supply circuit 4c for supplying electric power required for the charging and detonating device 2. The repeater 4 has a power feeding side photoelectric conversion communication circuit 4a and a receiving side photoelectric conversion communication circuit 4b for transmitting and receiving signals. The photoelectric conversion communication circuits 4a and 4b have photoelectric conversion elements such as photodiodes. The power-supply-side photoelectric conversion communication circuit 4a converts an optical signal from the transmission communication line 5a of the control bus 5 into an electric signal using a photoelectric conversion element. The reception side photoelectric conversion communication circuit 4b converts the electric signal from the blast bus 6 into an optical signal by using the light emitting element and transmits the optical signal to the reception communication line 5b of the control bus 5.

As shown in FIG. 2, the power feeding side photoelectric conversion communication circuit 4a and the receiving side photoelectric conversion communication circuit 4b are electrically connected to the power supply circuit 4c, and are operated by the power from the power supply of the power supply circuit 4c. The power supply circuit 4c supplies electric power to the blast bus 6 based on the signal from the power supply side photoelectric conversion communication circuit 4a. As a configuration therefor, the power supply circuit 4c includes a switch that connects and disconnects the power supply of the power supply circuit 4c and the blast bus 6, a CPU that operates the switch based on a signal from the power supply side photoelectric conversion communication circuit 4a, and a program that operates the CPU. Has a memory for storing. Therefore, when the blast controller 3 issues a command signal, power is supplied from the power source of the repeater 4 to the charging detonator 2.

As shown in FIG. 2, the repeater 4 has a busbar disconnector 4d that disconnects the blast busbar 6 from the repeater 4 before blasting the seabed 35 with the explosive canister 30. When the detonation signal (command signal) is transmitted from the blast controller 3, the detonation signal is sent to the CPU of the power supply circuit 4c via the power supply side photoelectric conversion communication circuit 4a. The memory of the power supply circuit 4c stores the busbar disconnection time (disconnection time) for operating the busbar disconnector 4d based on the initiation signal. The CPU operates the bus bar disconnecting device 4d when the bus bar cutting time is reached. The bus bar cutting time (cutting time) can be set to, for example, 60 seconds or more and about 300 seconds.

As shown in FIG. 2, the bus bar disconnector 4d is provided at the end of the blast bus bar 6 outside the case of the repeater 4. The busbar disconnecting machine 4d has a busbar disconnecting detonator 4h and a busbar disconnecting explosive 4g. The busbar disconnecting detonator 4h is connected to the power source of the power supply circuit 4c, and by supplying power to the busbar disconnecting detonator 4h during the busbar disconnection time, the busbar disconnecting detonator 4h is detonated to cause the busbar disconnecting. Blast 4 g of explosive to cut off the blast bus bar 6, and disconnect the relay 4 from the blast bus bar 6. After the relay device 4 is pulled up to a predetermined place, the explosive canister 30 blows up the seabed 35.

As shown in FIG. 2, the repeater 4 is provided with a connector 4i for connecting the blast bus 6 to the repeater 4. The connector 4i has a claw or the like that fits into the blast bus bar 6 when the blast bus bar 6 is inserted. Therefore, the operator can easily connect the blast bus 6 to the relay even underwater (in the sea).

As shown in FIGS. 2 and 4, the blast bus bar 6 has a communication line 6 a, a reception line 6 b, and a power supply line 6 c that extend from the repeater 4 toward the charging/detonation device 2. The communication line 6a, the reception line 6b, and the power supply line 6c are conducting wires such as copper wires, and are covered with a film having water resistance and water pressure resistance. The communication line 6a is connected to these in order to send the signal from the power-supply-side photoelectric conversion communication circuit 4a to the power-supply circuit 7c of the power-supply communication device 7. The receiving line 6b is connected to these in order to send a signal from the receiving circuit 7f of the power feeding communication device 7 to the receiving side photoelectric conversion communication circuit 4b. The power supply line 6c is connected to the power supply of the repeater 4 to supply power to the power feeding communication device 7.

As shown in FIGS. 3 and 4, the charging detonator 2 has a power feeding communication device 7 that wirelessly transmits power and a power receiver 8 that wirelessly receives power. The power feeding communication device 7 has a cylindrical power feeding container 7a for sealing various components. The power supply container 7a is filled with a liquid, gel or solid filler to prevent water or seawater from entering. The filler is made of a material that is permeable to electromagnetic waves, such as oil or resin. The blast bus bar 6 is laterally inserted through the upper end of the power feeding container 7a.

As shown in FIGS. 3 and 4, the power feeding communication device 7 has a power feeding circuit 7c electrically connected to the blast bus 6 and a power feeding coil 7e connected to the power feeding circuit 7c by a power feeding communication line 7d. The power supply circuit 7c transmits a specific current or signal to the power supply coil 7e in accordance with the electric signal received from the communication line 6a of the blast bus 6.

As shown in FIGS. 3 and 4, the power feeding coil 7e has a coil wound in an annular shape for wirelessly supplying electric power. The number of turns of the coil is 1 or more, for example 10 or more. The power feeding coil 7e is wound around the outer periphery of the assembly hole 7b. The current supplied from the repeater 4 is supplied to the power feeding coil 7e via the power feeding circuit 7c. When an electric current is passed through the power feeding coil 7e, an electric field or a magnetic field is generated around the power feeding coil 7e, and an electromagnetic wave is emitted. When a current having a specific frequency, amplitude, and wavelength flows through the power feeding coil 7e, the power feeding coil 7e generates an electric field or a magnetic field and emits a specific electromagnetic wave. The frequency of the electromagnetic wave is, for example, 100 to 500 KHz.

As shown in FIGS. 3 and 4, the power feeding communication device 7 has a receiving circuit 7f electrically connected to the receiving line 6b of the blast bus 6 and a receiving antenna 7h connected to the receiving circuit 7f by a communication line 7g. The receiving antenna 7h has, for example, a coil wound in an annular shape in order to receive a communication signal wirelessly transmitted from the power receiving device 8. The number of turns of the coil is, for example, one or more. When the receiving antenna 7h is exposed to a specific electromagnetic field, a current having a specific frequency, amplitude, and wavelength is generated, and the current can be received as a signal. The receiving antenna 7h is specialized for receiving an electromagnetic field having a frequency different from the electromagnetic wave generated by the feeding coil 7e, for example, an electromagnetic field having a higher frequency than the electromagnetic wave. Thereby, the electromagnetic wave generated by the power feeding coil 7e and the electromagnetic wave received by the receiving antenna 7h are differentiated. The frequency of the electromagnetic wave that the receiving antenna 7h can receive is, for example, 100 MHz or more and 1 GHz or less.

As shown in FIG. 4, an assembling hole 7b into which the power receiver 8 is fitted is provided in the lower portion of the power supply container 7a. The assembling hole 7b has a substantially cylindrical shape and has an opening on the lower side, and the power receiving device 8 is fitted from below. A receiving antenna 7h is arranged above the assembling hole 7b.

As shown in FIG. 4, the power receiving device 8 receives the power supplied wirelessly from the power feeding communication device 7, charges it, and explodes the explosive cylinder 30 in a predetermined time. The electric power receiver 8 has a tubular main body portion 8a and a fitting portion 8b having a smaller diameter than the main body portion 8a. The fitting portion 8b has a tubular shape, is positioned coaxially with the main body portion 8a, and projects from the main body portion 8a toward the power feeding communication device 7. The container of the electric power receiver 8 is filled with a liquid, gel or solid filler to prevent water or seawater from entering.

As shown in FIG. 3, the power receiving device 8 includes a power receiving coil 8f that receives the power supplied wirelessly from the power feeding communication device 7. The power receiving coil 8f has a coil wound in an annular shape. The number of turns of the coil is 1 or more, for example 10 or more. The power receiving coil 8f generates a current by being exposed to an electromagnetic field. The electric current is used as power for initiation and control. When the power receiving coil 8f is exposed to a specific electromagnetic field, a current having a specific frequency, amplitude, or wavelength is generated, and the specific current can be received as a signal. The frequency of the electromagnetic wave is, for example, 100 to 500 KHz. The power receiving coil 8f is positioned inside the power feeding coil 7e in the radial direction and is close to the power feeding coil 7e by inserting the fitting portion 8b of the power receiving device 8 into the assembly hole 7b.

As shown in FIG. 3, the power receiving device 8 has a transmitting antenna 8c for transmitting a signal to the power feeding communication device 7. The transmitting antenna 8c has, for example, a coil wound in an annular shape. The number of turns of the coil is, for example, one or more. The transmission antenna 8c generates an electric field or a magnetic field by transmitting a current having a specific frequency, amplitude, and wavelength in a coil forming the transmission antenna 8c, and transmits a specific electromagnetic wave. The transmitting antenna 8c is specialized for transmitting an electromagnetic field having a frequency different from the electromagnetic wave received by the power receiving coil 8f, for example, a higher frequency than the electromagnetic wave. Thereby, the electromagnetic wave generated by the transmitting antenna 8c and the electromagnetic wave received by the power receiving coil 8f are differentiated. The frequency of the electromagnetic wave transmitted by the transmitting antenna 8c is, for example, 100 MHz or more and 1 GHz or less. The transmitting antenna 8c is arranged concentrically with the receiving antenna 7h and is close to the receiving antenna 7h by inserting the fitting portion 8b of the electric receiver 8 into the assembly hole 7b.

As shown in FIG. 4, the power receiver 8 has a detonation side controller 10. As shown in FIG. 5, the detonation side controller 10 has a power storage unit 11 that stores the electric power received by the power receiving coil 8f wirelessly, and a detection circuit 14 that detects a predetermined signal from the electric wave received by the power receiving coil 8f. Power storage unit 11 has a power storage unit 11a for detonation and a power storage unit 11b for control. Both the power storage unit 11a for detonation and the power storage unit 11b for control include a power storage device (for example, a capacitor or the like) capable of storing power. The detonation power storage unit 11a and the control power storage unit 11b store current and power generated in the power receiving coil 8f.

As shown in FIG. 5, the detection circuit 14 detects a predetermined signal from the radio wave received by the power receiving coil 8f, and transmits the signal to the control circuit 13. The control circuit 13 has a CPU that controls various parts of the detonation side controller 10 based on a signal from the detection circuit 14, and a memory that stores a program for operating the CPU. The memory stores in advance a serial number unique to the power receiving device 8 (charging detonator 2 (see FIG. 4 )). The control circuit 13 operates the resistance value measuring circuit 18 based on the command signal from the blast controller 3.

As shown in FIG. 5, the resistance value measuring circuit 18 is provided between the control circuit 13 and the electric detonator 9 to determine whether or not the electric detonator 9 that detonates the explosive canister 30 is normal. The resistance value measuring circuit 18 receives an instruction from the control circuit 13 and supplies a weak current to the electric detonator 9 to measure the resistance value of the electric detonator 9. The control circuit 13 activates the discharge circuit 12 when it is determined that the resistance value of the electric detonator 9 is abnormal.

As shown in FIG. 5, the discharge circuit 12 discharges the current stored in the power storage unit 11 when the control circuit 13 determines that the electric detonator 9 is abnormal. The discharge circuit 12 is provided between the control circuit 13 and the electric detonator 9. The discharge circuit 12 is electrically connected to the detonation power storage unit 11a based on an instruction from the control circuit 13, and dissipates the electric power stored in the detonation power storage unit 11a.

As shown in FIG. 5, the control circuit 13 transmits whether the electric detonator 9 is normal or abnormal to the power feeding communication device 7 via the transmitting circuit 15 and the transmitting antenna 8c. The transmission circuit 15 receives a signal from the control circuit 13, generates a current having a specific frequency, amplitude, and wavelength, and supplies the current to the transmission antenna 8c.

After preparation for detonation in the charging detonator 2 is completed, the detonation signal is issued from the blast controller 3. The detonation signal is transmitted to the control circuit 13 via the power receiving coil 8f and the detection circuit 14 as shown in FIG. The control circuit 13 operates the switch circuit 16 based on the initiation signal. The switch circuit 16 is interposed between the power storage unit 11 and the electric detonator 9. The switch circuit 16 is switched from the disconnected state to the connected state by the control circuit 13, and electrically connects the detonation power storage unit 11a and the electric detonator 9. As a result, electric power from the power storage unit 11a for detonation is supplied to the electric detonator 9, and the explosive cylinder 30 explodes.

As shown in FIGS. 1 and 3, the explosive cylinder 30 is a cylindrical explosive and is loaded into a loading hole 35 a provided in the seabed 35. The explosive canister 30 has a canister body and an explosive charged in the canister body. The cylinder body should be sealed with explosives to prevent seawater from entering. The charging detonator 2 is attached to one end of the explosive cylinder 30 in the longitudinal direction. The explosive cylinder 30 includes, for example, one explosive or a plurality of explosives connected in series in the longitudinal direction.

The flow of the blasting method of blasting the seabed 35 using the blasting system 1 will be described with reference to FIGS. First, as shown in FIG. 5, the operator operates the blast controller 3 to generate a command signal from the blast controller 3 in preparation for blasting (step S1 in FIG. 6). The command signal is transmitted to the repeater 4 via the control bus 5 (see FIGS. 1 and 2) as a command light signal which is an optical signal. The power-supply-side photoelectric conversion communication circuit 4a of the repeater 4 converts the command light signal into an electric signal (step S2 in FIG. 6). An electric signal is transmitted to the power feeding communication device 7 via the blast bus 6 (see FIGS. 1 and 2). The power supply circuit 7c transmits a power supply current based on the electric signal (step S3 in FIG. 6). The power feeding coil 7e receiving the power feeding current emits an electromagnetic wave (step S4 in FIG. 6).

As shown in FIG. 5, the power receiving coil 8f receives an electromagnetic wave, and the power receiving coil 8f generates a current. (Step S5 of FIG. 6). An electric current flows into the power storage unit 11, and the detonation power storage unit 11a and the control power storage unit 11b are charged (step S6 in FIG. 6). The control circuit 13 transmits a charge completion notification signal when it detects that the power storage unit 11a for detonation and the power storage unit 11b for control are completely charged. The control circuit 13 transmits the serial number stored in advance as a signal together with the charge completion signal (step S7 in FIG. 6). The transmission circuit 15 receives the charging completion notification signal (and the serial number of the charging detonator 2) from the control circuit 13 and converts it into a current (step S8 in FIG. 6). The converted current flows into the transmitting antenna 8c, and the transmitting antenna 8c emits an electromagnetic wave (step S9 in FIG. 6).

As shown in FIG. 5, the receiving antenna 7h receives the electromagnetic wave from the transmitting antenna 8c, and the receiving antenna 7h generates a current (step S10 in FIG. 6). The reception circuit 7f converts the current from the reception antenna 7h into a charging completion notification signal and amplifies it (step S11 in FIG. 6). The charging completion notification signal is transmitted to the repeater 4 via the blast bus 6 (see FIGS. 1 and 2). The receiving side photoelectric conversion communication circuit 4b receives the charging completion notification signal and converts the charging completion notification signal into a notification optical signal (step S12 in FIG. 6). The notification light signal is transmitted to the blast controller 3 via the control bus 5 (see FIGS. 1 and 2). The blast controller 3 receives the notification optical signal (step S13 in FIG. 6). The display unit of the blast controller 3 displays the ready state of each power receiver 8 based on the serial number. The worker can thereby recognize that preparation for detonation of each charging detonator 2 is completed (step S14 in FIG. 6).

After performing step S6 as shown in FIG. 6, step S30 shown in FIG. 7 is also performed in parallel with step S7. As shown in FIG. 5, the detection circuit 14 receives the current from the power receiving coil 8f, detects a signal from the current (step S30 in FIG. 7), and the detection circuit 14 transmits the signal to the control circuit 13. The control circuit 13 sends a signal to the resistance value measuring circuit 18 based on the signal. The resistance value measuring circuit 18 measures the resistance value of the electric detonator 9 by using a part of the electric power stored in the control power storage unit 11b as a weak current (step S31 in FIG. 7). The control circuit 13 confirms from the measured resistance value whether the electric detonator 9 is defective or not (step S32 in FIG. 7). If there is no defect, the control circuit 13 transmits an inspection completion signal to the transmission circuit 15 (step S33 in FIG. 7).

As shown in FIG. 5, the inspection completion signal transmitted from the transmission circuit 15 is sent to the transmission antenna 8c as a current. The transmission antenna 8c transmits the inspection completion signal as an electromagnetic wave (step S34 in FIG. 7). The reception antenna 7h receives the electromagnetic wave and converts it into a current (step S35 in FIG. 7). The reception circuit 7f receives the current from the reception antenna 7h as an inspection completion signal (step S36 in FIG. 7). The reception circuit 7f transmits an inspection completion signal, and the reception side photoelectric conversion communication circuit 4b converts the inspection completion signal into an optical signal and transmits it (step S37 in FIG. 7). The optical signal is transmitted to the blast controller 3 via the control bus 5. The blast controller 3 receives the optical signal indicating that the inspection is completed (step S38 in FIG. 7), and the display unit of the blast controller 3 displays that the inspection is completed (step S39 in FIG. 7).

After step S39 (see FIG. 7) and step S14 (see FIG. 6) are completed, the process of step S15 is performed. That is, the display unit of the blast controller 3 displays that charging of the power storage unit 11 is completed (step S14) and that the inspection of the electric detonator 9 is completed (step S39). The operator confirms these displays and operates the input unit of the blast controller 3. The blasting controller 3 transmits a detonation light signal based on the operation of the input unit (step S15 in FIG. 6). A detonation light signal is transmitted to the repeater 4 via the control bus 5. The power-supply-side photoelectric conversion communication circuit 4a converts the detonation light signal into an electric signal and transmits it to the power-supply circuit 7c (step S16 in FIG. 6). The electric signal is transmitted to the power feeding communication device 7 via the blast bus 6.

As shown in FIG. 5, the power feeding circuit 7c receives the detonation signal, converts it into a current, and transmits it to the power feeding coil 7e (step S17 in FIG. 6). When the current flows, the power feeding coil 7e emits a detonation signal as an electromagnetic wave (step S18 in FIG. 6). The power receiving coil 8f receives the detonation signal as an electromagnetic wave and generates a current (step S19 in FIG. 6). The detection circuit 14 detects the detonation signal based on the current from the power receiving coil 8f (step S20 in FIG. 6). The detonation signal includes the detonation time corresponding to each serial number. The control circuit 13 records the initiation time of the corresponding serial number in the memory. When the timer of the control circuit 13 reaches the detonation time, the control circuit 13 turns on the switch circuit 16 (step S22 in FIG. 6). The detonation time is different for each serial number so that the seabed 35 is efficiently and sequentially detonated.

As shown in FIG. 6, after step S16, step S25 shown in FIG. 8 is also performed in parallel with step S17. That is, in step S16, the power-supply-side photoelectric conversion communication circuit 4a converts the initiation light signal into an electric signal. Based on the electric signal, the repeater 4 records the bus bar disconnection time in the memory of the power supply circuit 4c (step S25 in FIG. 8). When the timer of the repeater 4 reaches the bus bar disconnection time, the power supply circuit 4c supplies power to the bus bar disconnecting detonator 4h of the bus bar disconnecting device 4d. The busbar disconnecting detonator 4h detonates the busbar disconnecting explosive 4g (step S26 in FIG. 8). As a result, the blast bus 6 is disconnected from the repeater 4. The control bus 5 is recovered using the recovery machine mounted on the mother ship 32. The relay 4 is collected toward the mother ship 32 by collecting the control bus 5 (step S27 in FIG. 8). Step S22 is performed after the repeater 4 has moved to a place where the influence of the explosive force of the explosive cylinder 30 is small. That is, the detonation time is later than the bus bar disconnection time, and the relay 4 is moved away from the explosive cylinder 30 by the time difference. The initiation time can be set to, for example, 360 seconds or more and about 600 seconds.

After step S27 (see FIG. 8) and step S21 (see FIG. 6) are finished, the control circuit 13 turns on the switch circuit 16 (step S22 in FIG. 6). The electric detonator 9 receives electric power from the power storage unit 11a for detonation (step S23 in FIG. 6), and the electric detonator 9 detonates the explosive cylinder 30 (step S24 in FIG. 6).

When the control circuit 13 determines in step S32 of FIG. 7 that the electric detonator 9 has a defect, the steps after step S40 are performed to stop the blasting work. That is, as shown in FIG. 5, the control circuit 13 sends a discharge signal to the discharge circuit 12. (Step S40 of FIG. 7). The discharge circuit 12 discharges the power storage unit 11a for detonation based on the discharge signal (step S41 in FIG. 7). When the discharging circuit 12 finishes discharging the power storage unit 11a for detonation, a discharging completion signal is transmitted to the control circuit 13 (step S42 in FIG. 7). The discharge completion signal also includes information on the serial number corresponding to the charge detonator 2.

As shown in FIG. 5, the control circuit 13 transmits a discharge completion signal to the transmission circuit 15 (step S43 in FIG. 7), and the transmission circuit 15 transmits the discharge completion signal as a current to the transmission antenna 8c (step in FIG. 7). S44). The transmission antenna 8c transmits a discharge completion signal (step S45 in FIG. 7), and the reception antenna 7h receives the discharge completion signal. The receiving circuit 7f extracts the discharge completion signal based on the current from the receiving antenna 7h (step S46 in FIG. 7). The reception circuit 7f transmits a discharge completion signal to the reception side photoelectric conversion communication circuit 4b (step S47 in FIG. 7). The photoelectric conversion communication circuit 4b on the receiving side converts the discharge completion signal into an optical signal and transmits it (step S48 in FIG. 7). The blast control device 3 receives the discharge completion signal as an optical signal (step S49 in FIG. 7), and the display unit of the blast control device 3 indicates that the power of the power storage unit 11 has been discharged and that the charging detonator 2 that has discharged is serial. The number is displayed (step S50 in FIG. 7). Thereby, the operator knows that the electric power of the power storage unit 11 has been discharged due to the abnormality of the electric detonator 9 having the specific serial number.

The blasting system 1 is configured as described above. That is, as shown in FIG. 1, the blasting system 1 has an explosive canister 30 loaded on the seabed, a charging detonator 2 joined to the explosive canister 30, and a blasting controller 3 for issuing a command signal. The blast controller 3 and the charging detonator 2 are connected by a bus bar (control bus 5 and blast bus 6). As shown in FIGS. 4 and 5, the charging detonator 2 has a power feeding communication device 7, a power storage device 11, and an electric detonator 9. The power feeding communication device 7 wirelessly supplies power based on a command signal from the blast control device 3. The power storage device 11 charges electric power wirelessly supplied from the power feeding communication device 7. The electric detonator 9 detonates the explosive cylinder 30 based on the electric power charged in the electric storage 11. As shown in FIG. 1, a repeater 4 is provided in the middle of the bus bar. The busbar has a control busbar 5 connecting the blast controller 3 and the relay 4 and a blast busbar 6 connecting the relay 4 and the charging detonator 2.

Therefore, the busbar is divided into a control busbar 5 and a blast busbar 6 by the repeater 4. Therefore, it is possible to prevent the busbar from having a single long-distance structure from the ocean to the water or seabed. For example, the control bus 5 and the blast bus 6 can be made of different materials or different performances. Thereby, the blast controller 3 and the charging detonator 2 can be rationally connected.

As shown in FIG. 4, the charging detonator 2 wirelessly supplies electric power for the electric detonator 9. Therefore, it is possible to suppress the supply of electric power to the electric detonator 9 due to a short circuit or the like. The charging detonator 2 including the power feeding communication device 7 is joined to the explosive canister 30 (see FIG. 3 ), and the power feeding communication device 7 is also close to the explosive canister 30. Therefore, the wireless distance for power feeding is short, and the charging detonator 2 can be downsized.

As shown in FIG. 2, the repeater 4 includes a power supply (power supply circuit 4c), and supplies the power of the power supply to the charging and detonating device 2 through the blast bus 6. Therefore, the electric power is supplied to the charging/detonating device 2 (see FIG. 1) not from the blast control device 3 on the sea but from the relay device 4. Therefore, it is not necessary to supply electric power from the sea to the repeater 4, and a power line for supplying electric power to the control bus 5 connecting these is unnecessary.

As shown in FIG. 2, the control bus 5 has an optical fiber that transmits a command signal from the blast controller 3 (see FIG. 1) as an optical signal. The repeater 4 has a power supply side photoelectric conversion communication circuit 4a that converts an optical signal into an electric signal. Therefore, since the control bus 5 is an optical fiber, it is lighter in weight than the electric wire and has a simple structure. Furthermore, since the optical signal is less likely to be attenuated in the optical fiber, the signal from the blast controller 3 to the charging detonator 2 can be transmitted more accurately.

As shown in FIG. 5, the charging detonator 2 has a transmission circuit 15 that transmits a notification signal. As shown in FIG. 2, the repeater 4 has a receiving side photoelectric conversion communication circuit 4b that converts an electric signal, which is a notification signal received through the blast bus 6, into an optical signal. The control bus 5 has an optical fiber that transmits the notification signal from the repeater 4 to the blast controller 3 as an optical signal. Therefore, as shown in FIG. 1, the blast controller 3 can receive the notification signal as an optical signal. Therefore, since the control bus 5 is an optical fiber, it is lighter in weight than the electric wire and has a simple structure. Furthermore, since the optical signal is less likely to be attenuated in the optical fiber, the signal from the blast controller 3 to the charging detonator 2 can be transmitted more accurately.

As shown in FIG. 1, the blast bus 6 connects a plurality of explosive cylinders 30 in series. Therefore, the total length of the busbar can be shortened as compared with the configuration having a plurality of blasting busbars 6 that connect the relay 4 and the explosive cylinders 30 in parallel.

As shown in FIG. 2, the repeater 4 has a connector 4i that engages with an end of the blast bus bar 6 inserted in the repeater 4. Therefore, the repeater 4 and the blast bus 6 can be connected even underwater, which improves workability. Alternatively, by delaying the time when power can be supplied, the safety of installation work of the blasting system is improved.

As shown in FIG. 2, the repeater 4 has a busbar disconnecting device 4d that disconnects the blasting busbar 6 from the repeater 4 based on a command signal from the blasting controller 3 (see FIG. 1). Therefore, the relay 4 can be prevented from being involved in the explosion of the blasting work, and the relay 4 can be recovered. Thereby, the repeater 4 can be repeatedly used.

As shown in FIG. 2, the busbar disconnecting machine 4d has a busbar disconnecting detonator 4h for cutting the blast busbar 6 and a busbar disconnecting explosive 4g which is detonated by the busbar disconnecting detonator 4h. Therefore, it is possible to separate the blast bus 6 and the relay 4 by a detonation with a relatively simple structure.

As shown in FIG. 1, the blasting system 1 has a charging detonator 2 that detonates an explosive cylinder 30 loaded on the seabed or the waterbed, and a blasting controller 3 that sends a command signal from the sea or water. The charging detonator 2 and the blast controller 3 are connected by a bus bar via a relay device 4. The blasting controller 3 sends a command signal to the charging detonator 2 via the busbar. The repeater 4 stores the disconnection time for disconnecting the bus bar from the repeater based on the command signal. The charging detonator 2 stores the detonation time based on the command signal. During the disconnection time, the repeater 4 disconnects the busbar (blast bus 6) from the repeater 4 by using the busbar disconnector 4d (see FIG. 2) provided in the repeater. The charging detonator 2 detonates the explosive cylinder 30 during the detonation time after the evacuation time for leaving the relay device 4 from the explosion range has elapsed.

Therefore, as shown in FIG. 1, before the explosive cylinder 30 is detonated using the charging detonator 2, the relay 4 can be withdrawn from the explosion affected range of the blasting work to prevent damage and the relay 4 can be recovered. Thereby, the repeater 4 can be repeatedly used.

The blasting system 1 is used to blast the seabed 35 as shown in FIG. Alternatively, the blast system 1 may be used to blast the bottom of a water reservoir such as a pond, lake, or river.

As shown in FIG. 2, the repeater 4 has a power feeding side photoelectric conversion communication circuit 4a and a receiving side photoelectric conversion communication circuit 4b. Instead of this, the power feeding side photoelectric conversion communication circuit 4a and the receiving side photoelectric conversion communication circuit 4b are provided in the power feeding communication device 7 of each charging detonator 2. In this case, the blasting busbar 6 can be an optical communication line such as an optical cable, like the control busbar 5.

As shown in FIG. 2, the repeater 4 has a power feeding side photoelectric conversion communication circuit 4a and a receiving side photoelectric conversion communication circuit 4b. Instead of this, the repeater 4 may have a configuration in which the power feeding side photoelectric conversion communication circuit 4a and the receiving side photoelectric conversion communication circuit 4b are not provided. In this case, the control bus 5 is an energizing wire such as a copper wire in the same manner as the blast bus 6. Since the control bus 5 and the blast bus 6 are relayed by the repeater 4, the current lines of the control bus 5 and the blast bus 6 can be made of different materials or different diameters.

As shown in FIG. 2, the repeater 4 is provided with a power supply (power supply circuit 4c). Instead of this, a power source may be provided in the power feeding communication device 7 of each charging detonator 2. In this case, it is possible to reduce the number of current-carrying wires required for the blast bus 6 that connects the repeater 4 and the charging detonator 2.

As shown in FIG. 2, the busbar disconnecting machine 4d has a busbar disconnecting detonator 4h for cutting the blast busbar 6 and a busbar disconnecting explosive 4g which is detonated by the busbar disconnecting detonator 4h. That is, the blast bus 6 is disconnected from the relay 4 by cutting the blast bus 6 with the explosive force of the bus disconnecting explosive 4 g. Instead, it may have another configuration in which the repeater 4 and the blast bus 6 are automatically separated. For example, an electronic switch that is activated by a signal may be provided in the connector 4i and the blast bus bar 6 may be disconnected from the connector 4i by operating the electronic switch.

As shown in FIG. 2, the control bus 5 has two communication lines (for example, optical fibers) 5a and 5b. Instead of this, the control bus 5 may be configured by a single communication line (for example, an optical fiber), and transmission/reception can be performed by the single line.

As shown in FIG. 1, the blast bus 6 connects a plurality of charging detonators 2 in series. Alternatively, the relay 4 and each charging detonator 2 may be connected by each blast bus 6, that is, the relay 4 and each charging detonator 2 may be connected in parallel.

As shown in FIGS. 4 and 5, the power feeding communication device 7 has a receiving circuit 7f and a receiving antenna 7h. Alternatively, the power feeding communication device 7 may have a configuration that does not include the receiving circuit 7f and the receiving antenna 7h.

As shown in FIG. 5, the electric receiver 8 is provided with a discharge circuit 12 that discharges the power storage unit 11a for detonation. Instead, the electric power receiver 8 may not include the discharge circuit 12. In the case of this structure, only the control power storage unit 11b may be charged at the first charging. After that, the resistance value of the electric detonator 9 may be confirmed by the resistance value measuring circuit 18, and if there is no abnormality, electricity may be stored in the power storage unit 11a for detonation.

As shown in FIG. 5, the power receiver 8 has a resistance value measuring circuit 18 for confirming a malfunction of the electric detonator 9. Alternatively, the power receiver 8 may not have the resistance value measuring circuit 18.

As shown in FIG. 2, the repeater 4 has a bus bar disconnector 4d. Instead of this, the repeater 4 may be configured without the bus bar disconnector 4d. As shown in FIG. 2, the busbar disconnecting device 4d may disconnect the connecting portion between the blasting busbar 6 and the relay device 4, or may disconnect the blasting busbar 6 near the relay device 4.

As shown in FIG. 1, the explosive cylinder 30 is inserted into the loading hole 35 a of the seabed 35. Alternatively, the explosive cylinder 30 may be inserted into a crack existing in the seabed 35 or installed on the seabed 35. As shown in FIG. 1, a part of the charging detonator 2 is located outside the seabed 35. Alternatively, all of the charging detonators 2 may be located inside the seabed 35, or all of them may be located outside the seabed 35.

1 Blasting system 2 Charging detonator 3 Blasting controller 4 Repeater 4a Power supply side photoelectric conversion communication circuit 4b Reception side photoelectric conversion communication circuit 4c Power supply circuit (power supply)
4i connector 5 control bus (bus)
6 Blast Bus (Bus)
9 Electric detonator 11 Electric storage device (electric storage unit)
15 Transmitter circuit 30 Explosive canister 35 Seabed

Claims (9)

A blasting system for drilling a seabed or waterbed,
Explosive barrels loaded on the seabed or waterbed,
A charge detonator joined to the explosive cylinder,
A blast controller that sends a command signal from the sea or water,
A busbar connecting the blast controller and the charging detonator,
The charging detonator includes a power feeding communication device that wirelessly supplies power based on the command signal from the blast controller, a power storage device that charges power wirelessly supplied from the power feeding communication device, and the power storage device. An electric detonator that detonates the explosive cylinder based on the electric power charged to
A repeater is installed in the middle of the bus bar,
A blasting system, wherein the busbar has a control busbar that connects the blast controller and the repeater, and a blast busbar that connects the repeater and the explosive cylinder. The blasting system according to claim 1, wherein
The blasting system, wherein the repeater includes a power source, and supplies the power of the power source to the charging detonator through the blasting bus. The blasting system according to claim 1 or 2, wherein
The control bus has an optical fiber for transmitting the command signal from the blast controller as an optical signal,
The blasting system, wherein the repeater has a power-supply-side photoelectric conversion communication circuit that converts the optical signal into an electric signal. The blasting system according to any one of claims 1 to 3,
The charging detonator has a transmission circuit for transmitting a notification signal,
The repeater has a receiving side photoelectric conversion communication circuit for converting an electric signal, which is the notification signal received through the blast bus, into an optical signal,
The blast system in which the control bus has an optical fiber for transmitting the notification signal from the repeater to the blast controller as an optical signal. The blasting system according to any one of claims 1 to 4,
The blasting system, wherein the repeater has a connector that engages an end of the blasting bus bar inserted in the repeater. The blasting system according to any one of claims 1 to 5,
Having a plurality of the explosive canisters,
The blasting bus is a blasting system that connects a plurality of the explosive cylinders in series. The blasting system according to any one of claims 1 to 6,
A blasting system having a busbar disconnecting device for disconnecting the blasting busbar from the relaying device based on the command signal from the blasting controller. The blasting system according to claim 7,
The busbar disconnecting machine includes a busbar disconnecting detonator for cutting the blasting busbar, and a blasting system for deactivating the busbar disconnecting detonator. A charge detonator for detonating an explosive cylinder loaded on the seabed or the water bottom, a blast controller for issuing a command signal from the sea or water, and the charge detonator and the blast controller are connected via a relay. A blasting method in a blasting system having a bus bar, comprising:
The blasting controller transmits the command signal to the charging detonator via the bus bar, and the relay machine stores a disconnection time for disconnecting the bus bar from the relay machine based on the command signal,
The charging detonator stores the detonation time based on the command signal,
The relay machine disconnects the bus bar from the relay machine using a bus bar disconnector provided in the relay machine at the disconnection time,
A blasting method in which the charging detonator detonates the explosive cylinder during the detonation time after the evacuation time for leaving the relay unit from the explosion range has elapsed.

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