CN201666766U - Wireless detonator module and blasting system - Google Patents

Abstract

The utility model discloses a wireless detonator module. The detonator module, which is wirelessly connected with at least one exploder and can transmit at least one instruction signal, comprises primary charge, an instruction signal receiver, an instruction signal processor, a power supply, an energy receiver for receiving wireless signal energy, a converter for converting the energy into electric energy, a dynamic power supply for storing the electric energy coming from the converter and supplying electricity to a detonator and an ignition circuit, and after the instruction signal receiver and the instruction signal processor receive an ignition signal, the ignition circuit can receive the electric energy stored in the dynamic power supply to activate the primary charge to explode. The utility model also provides a blasting system comprising the detonator module. The detonator module can be remotely ignited after being improved without requiring complex on-site wiring. The time of blasting operation is shortened, the engineering implementation process is simplified, and the overall safety is enhanced as well.

Description

A kind of wireless detonator assembly and demolition set

Technical field

The utility model relates to priming system and control technology field thereof, relates in particular to a kind of wireless detonator assembly and demolition set.

Background technology

In mining processes, carry out effective rock fragmentation by the blasting charge, need quite high technology and special knowledge.In most of minings, in stone, calculate good position and place the blasting charge of right quantity.The blasting charge is ignited through detonator predetermined time delay, meets the requirements of the cracked pattern of explosion and stone thus.Usually, signal is sent to detonator by detonate electric wire (LEDC) or detonator of the low energy of non-electric system.The electronics line also can send signal to electric detonator in addition.Recently, electric detonator allows to use 1ms or programmable delay time still less.

Determine the position that the blasting scheme and the blasting charge are laid, often be to use a large amount of labours, highly rely on blast operations personnel's accurate and conscientious degree.The blast operations personnel must place the blasting charge accurately, for example in the boring of stone, determine that detonator contacts well with the blasting charge.Importantly, the blast operations personnel must confirm that the communication of detonator and trigger is good, ignite each detonator and can ignite each blasting charge thereby trigger can send ignition signal.

Can directly carry out telecommunications between trigger and the detonator in the electronics fuzing system, armament, perhaps allow to use the signal of more complexity to send.For example, sort signal sends may comprise ARM to be sent instructions, remove DISARM to be sent instructions, and the instruction of the delay time of detonator being carried out remote programmable.In addition, as security feature, detonator can store the ignition code, has only the ignition code that receives from the trigger Shi Caihui that matches to treat and send out and ignition signal responds.

In order to respond described command signal, the electric detonator system also can comprise the programmable circuit that can receive, store and handle received signal.Yet this programmable circuit may cause safety problem.For example, to cause the detonator primary charge to be misquoted quick-fried for the power supply of the programmable circuit detonation circuit that can influence detonator.

The receiving system of detonator control signal and method have improved to some extent and have misquoted quick-fried possibility with reduction now, thereby improve the security of blasting scheme.The development of wireless detonator and corresponding detonator system has also improved shotfiring safety.The personnel that are familiar with this technology recognize the great potential of wireless detonator system to the raising of explosion site safety.By avoiding the physical connection (as the electronics line, detonator, LEDC, perhaps optical cable) between the detonator, the unsafe factor of on-the-spot other assembly of explosion also decreases.In the wired detonator system of tradition, need very skilled and careful the connecting up of operator, also will carefulness very determine that the line that causes trigger from the blasting charge (with the detonator that is connected) does not open circuit, electric leakage damages etc.The wireless explosion system then is hopeful to address these problems.

Another advantage of wireless detonator relates at explosion on-the-spot easy automatically the install blasting charge and related detonator.This for example may comprise automatic detonator filling in the hole of cutter, makes being dynamically connected certainly of detonator and corresponding each blasting charge.At the explosion scene a series of blasting charge and detonator can be installed automatically, for example can pass through robot system, the security at explosion scene will be significantly improved, because the blast operations personnel can operate explosion from far place.Yet some technical barriers that are difficult to overcome have appearred in such system, wherein much also do not solve.Obstacle that leads to automation be difficulty, particularly detonator that the on-the-spot robot of explosion handled and handled detonator require to connect or with electronics line, shock tube or similarly connect.Wireless detonator and corresponding wireless detonator system can help to address these problems, and make the easier control of enforcement of automatic mining.In addition, the artificial physical connection control of detonator will be used a large amount of labours with being connected, and requires the blast operations personnel to take much time.Opposite, blasting system does not need a large amount of labours automatically, but needs a large amount of program of time design to comprise robot system but not blast operations person's time.

Wireless detonator has had further development, and the wireless explosion system is fit to mining and uses, and comprises that detonator and system can connect automatically at the explosion scene.But still there is very big security concerns in existing wireless explosion system, if wireless system can become feasible possible alternative of traditional wired blasting system, security needs further improve.Can realize the function of complicated wiring system at explosion on-site wireless blasting system, but have the co-related risks that each inter-module of blasting system connects and can not accurately place.And the industry that develops into of wireless telecommunication system presents the significant challenge that makes new advances and new safety problem in the bursting work.

Find that through carefulness investigation wireless detonator and initiation system thereof can cause that detonator misquotes quick-fried misgivings.Do not consider the interference of occurring in nature wireless telecommunication system in fact, between wireless trigger and relevant detonator thereof, carry out communication fast and accurately and can face huge challenge yet.The wherein most important signal that need be handled by the accurate complete reception of wireless detonator is an ignition signal.The failure of communication system detonating primer can cause the danger of site operation personnel's injures and deaths.We can say and prevent that the on-the-spot detonator of explosion from misquoting quick-fried is of paramount importance.

The utility model content

For improving the security of detonator and blasting system, avoid the on-the-spot detonator that takes place of explosion to misquote the quick-fried danger that waits, the utility model provides a kind of detonator assembly, and this detonator assembly and at least one initiator carry out wireless connections and transmit at least one command signal, and this detonator assembly comprises:

Primary charge;

Command signal receives and processor, is used for receiving the above-mentioned wireless command signals of processing;

Power supply is used to described command signal to receive and the processor power supply;

Energy receiver is used to receive the energy of wireless signal;

Converter is used for the above-mentioned power conversion that receives from energy receiver is become electric energy;

Dynamic power supplies is connected with converter, and the electric energy that can store from converter also is the detonator power supply;

Firing circuit is connected with described primary charge, is used to receive the electric energy that stores in the described dynamic power supplies, and ignites;

Described power supply can not provide sufficient electric energy for described firing circuit, and after above-mentioned command signal reception was received firing command with processor, firing circuit can receive the electric energy that stores in the described dynamic power supplies, activates primary charge, thus ignition.

At least one command signal of described transmission is by following medium: radio wave, acoustic energy, electromagnetic energy, or electromagnetic induction; The energy of described energy emitter emission comprises: microwave, electromagnetic wave, acoustic energy or electromagnetic induction.

Described command signal reception comprises an electromagnetic energy receiver with processor and energy receiver, described command signal is by electromagnetic wave first wavelength transmission, described energy from energy emitter is launched by electromagnetic second wavelength transmission, and described detonator assembly also comprises:

Discriminating device, link to each other with described electromagnetic energy receiving system, be used to distinguish the electromagnetic energy of described first wavelength and the electromagnetic energy of described second wavelength, the electromagnetic energy of described first wavelength is received by command signal and processor receives and handles, and the electromagnetic energy of described second wavelength is converted device and converts electric energy to.

Described command signal receives and processor comprises radio wave reception converter, and described at least one command signal comprises radio wave, and energy receiver comprises the electromagnetic energy receiver, and the energy of described emission comprises electromagnetic energy; Perhaps, described command signal receives and processor comprises the electromagnetic energy receiver, and described at least one command signal comprises electromagnetic energy, and described energy receiver comprises radio receiver, and the energy of described emission comprises radio wave.

Described command signal receives and processor comprises the first luminous energy receiver; Described command signal comprises the luminous energy of first wavelength; Described energy receiver comprises the second luminous energy receiver; The energy of described emission comprises the luminous energy of second wavelength.

Described energy receiver comprises an electromagnetic induction energy receiver, and the energy of described emission comprises electric energy, and this electric energy to small part is transferred to described detonator assembly by electromagnetic induction; Described electromagnetic induction energy receiver comprises at least one magnetic coupling device, and each electromagnetic induction is relevant with electric wire from the electric current of described energy emitter; Command signal reception and processor and/or energy receiver comprise an electromagnetic energy receiver.

Described magnetic coupling device is to adopt ferritic toroidal transformer.

Described dynamic power supplies comprises one of the following at least: electric capacity, diode, rechargeable battery, fuel cell, air cell, audiphone battery, miniature nuclear power source, and active cell.

Described detonator assembly further comprises: be arranged on the firing switch between described dynamic power supplies and the described detonation circuit, described firing switch is set up electrical link according to the firing command signal that described command signal receiver receives between described passive power source and described detonation circuit, be discharged into detonation circuit with the electric energy that will be stored in described passive power source, ignite described primary charge thus.

Described command signal reception and processor and/or energy receiver receive luminous energy, comprise a light capture device and the optical cable that is used for the light that the light capture device receives is transferred to converter; Described smooth capture device is placed in the described luminous energy of the above reception in ground, and described optical cable transmission luminous energy is to the converter on ground; The luminous energy that received by each light capture device is from incandescent lamp, laser instrument, laser diode, or LED.

Described each command signal is to comprise from one group: the ARM signal of waiting to signal, remove DISARM to be signaled, and ignition signal FIRE selects in detonator time delay and the cap sensitive code; Described detonator assembly further comprises:

Signal transmission device is used to produce and transmits at least a command signal that is received by described trigger.

Described discriminating device comprises one or more optical filters;

Wherein, the wavelength of the electromagnetic energy of wavelength ratio second wavelength of the electromagnetic energy of described first wavelength will be grown;

The electromagnetic energy of described first wavelength is from least one red laser;

The electromagnetic energy of described second wavelength is from least one blue laser.

The utility model also provides a kind of demolition set, comprising:

At least one trigger can be sent to relevant detonator by first medium radio communication with command signal;

At least one blasting charge;

Detonator assembly, at least one detonator assembly is connected with the described blasting charge, and with described at least one trigger communication;

At least one is transmitted into each detonator assembly by the energy emitter of second medium emitted energy, to give each detonator assembly charging, to receive and to respond the firing command signal from described at least one trigger;

Central control station is used to control at least one above-mentioned trigger.

Send described at least a command signal in the following way: radio signal, electromagnetic energy specifically comprises luminous energy, microwave energy, ultraviolet, acoustic energy or electromagnetic induction;

The energy of emission comprises: radio signal, electromagnetic energy specifically comprises luminous energy, microwave energy, ultraviolet, acoustic energy or electromagnetic induction.

Use the blasting method of wireless detonator assembly provided by the utility model and demolition set, may further comprise the steps:

At a large amount of blasting charge of the on-the-spot arrangement of explosion;

Setting and the detonator assembly that each blasting charge links to each other are ignited each detonator assembly and will be ignited each relevant blasting charge;

Receive the energy of described emission from above-mentioned energy emitter emitted energy at least one above-mentioned detonator assembly to cause each detonator assembly, and the energy of changing above-mentioned emission is that the electric power energy is the ignition charging of each detonator assembly thus;

Send at least one command signal from described at least one trigger and make each detonator assembly emit above-mentioned electric power energy, ignite each primary charge to above-mentioned detonation circuit.

The utility model proposes a kind of detonator assembly, supporting demolition set and the reduced detonator of using this detonator assembly are misquoted quick-fried blasting method.Detonator assembly described in the utility model uses well-known components to realize avoiding detonator to misquote quick-fried method.By avoiding the physical connection line between detonator assembly and the supporting initiator, utility model person successfully develops a kind of intrinsic safety type detonator assembly.At the scene of detonating, the operator can install the blasting charge and detonator assembly and away from after carry out long-range ignition again, and need not to carry out again complicated field wiring.So not only reduce the time of blast operations and simplified project implementing process, also improved whole security.

The technical scheme that adopts the utility model to provide can make that the automation mechanized operation of detonator device is easier.Need not to carry out between detonator assembly and trigger or power supply physical connection (for example electric wire, detonator, LEDC, or optical cable), by automatic fitting tool the detonator device being packed into holes easilier, for example uses robot system.Like this, the explosive at the scene of explosion around that blast operations person can cost less makes the staff away from harm thus.

Description of drawings

Fig. 1 is wireless detonator assembly and corresponding demolition set described in the utility model one preferred embodiment;

Fig. 2 is described wireless detonator assembly of the utility model one preferred embodiment and corresponding demolition set configuration diagram;

Fig. 3 is described wireless detonator assembly of the utility model one preferred embodiment and corresponding demolition set configuration diagram;

Fig. 4 is described wireless detonator assembly of the utility model one optional embodiment and corresponding demolition set configuration diagram;

The method flow diagram that Fig. 5 carries out explosion for the described wireless detonator assembly of a preferred embodiment in the utility model and corresponding demolition set.

The specific embodiment

The utility model relates to the energy that uses a kind of form and comes and the detonator communication, comes to detonator assembly " charging " or " power supply " with another multi-form energy, thereby makes its reliable ignition.The energy of these two kinds of forms is different from other form, and it can be detected by detonator of the present utility model.By form of energy disclosed in the utility model as seen, it is quick-fried that the energy that uses when communication of detonator assembly described in the utility model is not easy to cause misquoting of detonator basis explosive.For reliable ignition, two kinds of diverse form of energy must be detected by detonator assembly simultaneously, and not so the detonator device will be in

" safe mode ".

The form of energy may adopt the form of any suitable wireless telecommunications and wireless charging or power supply, for example can be by different medium transmission.For example, the form of these energy may be including, but not limited to electromagnetic energy (comprising light), ultraviolet, radio wave, and microwave, perhaps can receive other form as electromagnetic induction or acoustic energy.The utility model suggestion is first-selected selects same form from above-mentioned example form of energy, both be used for also being used to detonator assembly " charging " or " power supply " by command signal (for example from trigger) and detonator assembly communication.Yet under this environment, extraneous existing energy source must be made a distinction by detonator assembly described in the utility model, thereby guarantees command signal and the energy that charges to detonator assembly can be not disturbed.In the example, if detonator assembly described in the utility model uses microwave to come communication and charging, detonator assembly just can be distinguished according to wavelength or frequency so.Obviously if detonator assembly described in the utility model uses different ability forms to carry out communication and charging, that needs the situation of the different energy of wavelength basis or frequency separation just to reduce.For example, detonator assembly described in the utility model can then pass through radio wave with the communication of trigger by absorbing luminous energy for its charging.This is actually special embodiment of the present utility model.Under this environment, optional light and radio receiving equipment can accurately be distinguished charging and communication signal on the detonator assembly.

In order to receive for example ARM, DISARM, with the FIRE signal and come detonator time delay being set and igniting relevant code of auto correlation trigger, the utility model plan is used and is comprised that an energy provides the Miniature Power Unit of sufficient power supply as the telecommunication circuit in the detonator assembly.Yet this power supply does not often have enough energy to activate primary charge by firing circuit.As what discuss, the utility model uses a different system of separating fully to give detonator assembly " charging " or " power supply ", can reliably ignite primary charge according to one or more command signals thus.For example, use reception electromagnetic energy (as luminous energy or microwave) to provide energy among the utility model embodiment for the firing circuit that activates primary charge.Like this, each detonator assembly can be programmed from trigger reception command signal by the radio-frequency communication mode.Yet, unless each detonator assembly has all received the electromagnetic energy of power supply and for firing circuit converts electric power energy to, not so can not make a response to the firing command signal.Wireless telecommunications between trigger and detonator assembly, communication ARM for example, DISARM, or ignition signal also have time delay and ignite code, all can not cause misquoting of primary charge quick-fried fully, and detonator assembly is in the intrinsic safety state thus.According to the utility model, have only detonator assembly can ignite after charging fully by an energy source that is different from the command signal communication system of (for example different wavelength or frequency) trigger fully.Just be to use different form of energy for detonator assembly provides the energy input, just can making the FIRE signal of its response trigger and the reliable firing circuit that activates ignite primary charge.

The expert will appreciate that the signal of trigger communication and energy source are different with powering for detonator assembly in itself.For example, the any wireless transmission signal and the instrument of energy can be used by detonator assembly described in the utility model, finishing the wireless telecommunications with trigger (for example transmission of command signal), and trigger is the energy of detonator assembly " power supply " or " charging " or the transmission of energy.Detonator assembly described in the utility model can be divided into wireless telecommunications that general communication is a purpose and with the wireless telecommunications of power supply.In addition, also can use single form of energy (for example luminous energy) also has been control detonator transfer instruction signal as the detonator assembly charging both, uses different wave length when power supply and transfer instruction signal, so that detonator assembly can be distinguished effectively.For example, in specific embodiments,, and be that light energy is transmitted in the detonator assembly power supply with the optical signal of shorter wavelength higher-energy with the optical signal transmission command signal of longer wavelength less energy.The form of this luminous energy for example can adopt the form of red and blue laser.In addition, other wireless mode also can be used for comprising for example ultraviolet, radio wave and microwave, the perhaps electromagnetic energy of other form, electromagnetic induction and acoustic energy with the detonator assembly communication or for detonator assembly power supply transmission energy.

In other embodiments, detonator assembly described in the utility model can receive energy and the charging of transmitting by receiver by an electromagnetic induction.Such receiver comprises that the energy received energy is as any equipment by the electromagnetic induction electric energy transmitting.For example, magnetic coupling device that has the magnetic metal material.In first-selected device, magnetic coupling device has the open extension wire that is configured to receive, and above-mentioned magnetic coupling device can produce output signal based on the electric current that passes through on the lead.For example, extension wire can optionally transmit the electric current that is adapted at causing in the magnetic coupling device magnetic flux, and promptly magnetic flux can utilize current transfer to the coiling on every side of magnetic coupling equipment.Magnetic coupling device comprises ring-type element in first-selected device, as illustrated in fig. 4.The line and the magnetic coupling device that do not have a loaded current of physical connection between the use of magnetic coupling device comprises.Therefore, in the utility model, magnetic induction constitutes a kind of wireless (or wireless to small part) energy transmission form.

First-selected embodiment of the present utility model as shown in Figure 1.10 expression detonator assemblies.It is a luminous energy receiver 11 that detonator assembly comprises in the energy receiver present embodiment, and being used for receiving from what adopt in this enforcement is the laser 12 of the energy emitter 13 of laser form.And the luminous energy receiver also can be selected electromagnetic energy receiver (not sign) or other any type of energy receiver that receives any form electromagnetic energy.In another first-selected embodiment, energy receiver is the microwave energy receiver, receives microwave energy.Detonator device 10 comprises that a command signal receiver 14 receives arbitrarily the radio wave command signal 15 from trigger 16 in addition.The command signal that receives is through signal processor 17.

Detonator assembly 10 comprises that primary charge 18 is connected to the miscellaneous part of detonator by firing circuit 19, as shown in Figure 1.In addition, detonator 10 comprises that the transform light energy that converter 20 is used for luminous energy receiving tool 11 is received is an electric energy.Afterwards, electric energy temporarily is stored in passive power source 21, and first-selected form is an electric capacity.Passive power source is connected to firing circuit 19 by firing switch 22.Firing switch 22 keeps off-state, prevents the electric power transfer between passive power source 21 and the firing circuit 19.Command signal processor 17 (also and instruction signal processor 14 is integrated but in selecting embodiment) can receive and handle several dissimilar command signals (not sign).Yet, only receiving a firing command signal from trigger 16, the command signal processor just can cause firing switch 22 closures.

Therefore, at detonator device 10 illustrated in fig. 1, have only satisfied following both situations just can ignite:

At first, luminous energy receiver 11 receives sufficient luminous energy 12 with the electric power energy that produces and storage is sufficient from LASER Light Source 13, activates firing circuit 19 and ignites primary charge 18 by converter 20 and passive power source 21;

Secondly command signal receiver 14 receives ignition signal so that firing switch 22 is closed by the radio signal 15 that receives from trigger 16, thus passive power source 21 and firing circuit 19 are carried out the electric weight transmission, be discharged into firing circuit 19 to ignite primary charge 18 with the electric energy that allows to be stored in passive power source 21.

Comprise also among the embodiment in Fig. 1 that an active electrical source 25 receives for command signal and processor provides the energy.Like this, command signal reception and processor can receive the command signal from trigger all the time.

The input that needs two physically different two different energy sources from two different mediums in embodiment illustrated in fig. 1 is to ignite primary charge.The utility model also comprises more than the described more complex embodiments of Fig. 1.For example, from the command signal of trigger may further comprise may be handled and store by the detonator device time delay sign indicating number and the security feature sign indicating number as igniting code.This ignites code and can compare with the ignition code of setting in advance to determine that command signal is reliably but not misquotes quick-fried result unintentionally.For example, consistent with known security system, if the ignition code that has received is complementary with the ignition code of finishing in advance, ignition signal is then only handled and receive to the command signal processor.For safety, embodiment of the present utility model all is used in combination with existing mature technology in the industry.

Though in Fig. 1, do not mark, be easy to know that the parts of detonator assembly may not be installed in the capsule.For example, the luminous energy receiver may adopt the form of external antenna to extend out to far position from capsule.An embodiment comprises this principle, and as shown in Figure 2, the same among all parts of detonator and Fig. 1 is except luminous energy receiver 11.Further describe, the form that the luminous energy receiver adopts is a light capture device 30, is connected light capture device 30 and converter 20 with optical cable 31.Like this, the light capture device may be installed in the position of the luminous energy that sends from laser 13 such as on the ground suitable reception or interception.And other parts of detonator device may be installed in subsurface, or in the holing of stone.Though there is not diagram, the utility model can also further be embodied as: be installed in the light capture device from the far place of other parts of detonator assembly, other possible parts of crossover tool and detonator are installed in the position of close or adjacent light capture device.In this embodiment, luminous energy converts electric energy on ground or stone, be sent to ground next by being electrically connected the ignition primary charge.

Laser 13 can be that direct laser or laser light group provide luminous energy for a series of detonator assemblies.Can determine demolition set like this, as each detonator device, perhaps at least one light-receiving instrument of each detonator device is in the scope of light energy source such as laser.Optionally, the source of luminous energy can be from the part of trigger, also can be from parts cluster fully independently.According to the utility model, each optical receiver that should mark each detonator device may be the target in one or more luminous energy sources (for example laser).This helps to guarantee that the detonator device in the time charging that requires, also helps to make charging not influenced by the dirt of optical receiver.

In a preferred embodiment, the wireless telecommunications first-selection of trigger comprises that the two-way communication receives the signal that transmits from relevant detonator device to allow trigger, and for example, the state of detonator device, is ignited code etc. at time delay.

In another embodiment, the utility model proposes the explosion instrument and comprise a central command station that is used for the controlled blasting operation away from the explosion scene, also have one or more can receive from the command signal of central command station with pass on the trigger of signal effectively to numerous relevant detonators.

Though in Fig. 1 or Fig. 2, do not do sign, be easy to expect and be transmitted as the energy of detonator assembly charging and transmit the command signal that is used to control detonator assembly with the energy such as the luminous energy of single type.If use luminous energy, then can come the transfer instruction signal with different wavelength and charge to detonator assembly.In embodiment illustrated in fig. 3, two laser instruments that different wave length luminous energy is provided are arranged, one is used for the transfer instruction signal, and another is used to ignites the primary charge energy supply.Trigger 16 utilizes an additional laser instrument 32 that transmits light energy bundle 33 to light capture device 30.Energy beam 33 is longer than luminous energy 12 wavelength of laser instrument 13 generations, and energy is lower.The long luminous energy 33 of wavelength replaces radio signal 15 among Fig. 1 or Fig. 2 and is used for the transfer instruction signal to detonator.Trigger 16 and additional laser instrument 32 known method communication, but preferred use wireless method or direct electric communication.Can select, laser instrument 32 also can be the part of trigger.

In a preferred embodiment, the blue laser of shortwave is because of higher charging that energy transmission efficiency is useful on, and the long red laser of wavelength is used for the transfer instruction signal.Detonator assembly 10 is the same with previous device but increased optical filter 34 and recognize the wavelength that receives luminous energy.Be directed to command signal receiver 14 after having short wavelength luminous energy to be filtered like this.Receive in case be converted device and command signal receiver, signal is incited somebody to action processing as stated above.

Optical filter 34 can replace (not identifying among Fig. 3) with the luminous energy receiver.In this device, the luminous energy that is used to transmit first wavelength of energy can be directly to the first luminous energy receiver that is used to be transferred to power conversion instrument 20.The luminous energy that is used for second wavelength of transfer instruction signal can be directly to the second luminous energy receiver that is used to be transferred to command signal reception and processor 14.The luminous energy that receives every kind of wavelength need there is no need to distinguish with an optical filter light of different wave length with a luminous energy receiver.Wavelength more than two types if desired, then available a plurality of luminous energy receiving tools are perhaps used an optical filter.If desired can be with a plurality of luminous energy receiving tools with one or more optical filters.The light that can expect first and second wavelength can transfer instruction signal or transmission energy.

With similar embodiment shown in Figure 3 in, can use the twin-laser device, luminous energy receiver 11 is built-in as shown in Figure 1, and the luminous energy receiver mode of employing exterior light capture device 30 as shown in Figure 2.Further can expect to use any known luminous energy emission source to launch the light of suitable wavelength.In addition, also can use and to launch two independences and the different single light energy source that can be received wavelength by detonator.

The optional embodiment of the utility model as shown in Figure 4.This embodiment comprise a lot of with at Fig. 1,2, or the similar or identical parts that show in 3.But for detonator device charging be by way of electromagnetic induction rather than by some other wireless tool.In Fig. 4, identified the line of selecting to transport from the electric current of power supply (not sign) 40 has been arranged.Power supply (not sign) can also can be a separate component from the part of trigger or central command station.Under any circumstance, line 40 all will twine by an annular magnetic coupling device 41, does like this when electric current process electric wire and can produce magnetic flux in magnetic coupling device.Be converted to electric power energy effectively at 42 li magnetic fluxs of seal wire, this seal wire twines part annular magnetic coupling device 41 and links to each other with another parts of detonator device 10.In order to convert a kind of electric power energy form that is suitably for passive power source 21 power supplies to, seal wire 42 links to each other with crossover tool 20.In optional embodiment, also can directly link to each other seal wire 42 and change from the energy of power supply to line 40 with passive power source.In this case, in some optional embodiment, then can no longer need converter at least.

Though strictly speaking embodiment illustrated in fig. 4 is not " wireless " completely, it is in spirit and scope of the present utility model.Electromagnetic induction can be used as a kind of selection that form of energy is provided as a kind of method for the detonator power supply, is different from general command signal communication 15 from trigger 16.Because this reason, detonator device 10 can be distinguished command signal and charging signals effectively, and and if only if when satisfying following condition, and primary charge just can be detonated:

(1) passive power source 21 is by line 40 electromagnetic induction, and magnetic coupling device 41 and seal wire 42 are recharged or are recharged fully;

(2) trigger 16 transmission fuze signals 15 (for example by radio wave or electromagnetic energy), receive and handle by command signal receiver 14 (handling) with processor 17, make firing switch 22 closures thus and the electric power energy of storage is discharged into firing circuit 19, cause igniting primary charge 18.

Though the use in the conversion of the annular shown in Fig. 4 is in the field of business known, it is communication or other the general communication that is used for detonator/detonator assembly command signal that tradition is used.This is opposite with the utility model, and the utility model has used electromagnetic induction for the command signal communication and in order to ignite to detonator assembly charging.For the use of charging, the seal wire 42 that is wrapped on the annular magnetic coupling device may needn't be too accurate with respect to the device that is used for the equivalence of transfer instruction signal.After all, the purpose of using the circular device in this device is charging, the failure of circular device can cause lacking charging or charge insufficient, thereby detonator assembly can not be ignited, this causes great risk may not can for the blast operations personnel.It is no coming the failure of transfer instruction signal with circular device, may cause that the state of detonator device is uncertain to have an inevitable safety problem.With respect to the annular transmitter that is used for the transfer instruction signal, the annular transmitter that is used to charge not too accurately also is an acceptable.For example, this equipment also is to use the poor slightly seal wire of accuracy 42 to be wrapped on the magnetic coupling device 41.

In another embodiment of the present utility model, propose a kind of demolition set, comprising:

At least one trigger can be sent to relevant detonator to command signal by first medium radio communication;

At least one blasting charge;

At least one detonator assembly, related with the binding of each blasting charge, and with at least one described initiator communication;

At least one energy emitter by second medium emitted energy, being transmitted into that each detonator assembly comes is each detonator assembly charging, makes it can respond firing command signal from above-mentioned at least one trigger;

A selectable central control station is controlled at least one above-mentioned trigger.

Detonator assembly described in the utility model and demolition set mainly use independently communication apparatus be used for the transfer instruction signal and independently power supply be used to transmit energy and charge as detonator assembly.Yet detonator assembly described in the utility model as can be known can receive the command signal from one or more sources, for example, and a plurality of triggers.In addition, detonator device described in the utility model as can be known can wireless receiving from one or more energy sources that are used to charge.For example, a plurality of laser instruments are target with a detonator assembly, and this detonator assembly can receive the energy from a plurality of laser instruments.Think that in theory a plurality of energy sources are target with a detonator device, the possibility that can not correctly charge can reduce.For example, because the obstacle of neglecting on the optical channel from the laser instrument to the detonator assembly all may not receive the own energy of selecting laser instrument at the on-the-spot any detonator of explosion.Is target from different angles with the detonator device by a plurality of laser instruments, and the possibility of this situation can reduce.

Detonator assembly further described in the utility model as can be known can be installed as an explosion array.In addition, during the one or more detonator assemblies in the array can use automatic installation apparatus or system to be installed to hole, for example can use robot system at the explosion scene.In addition, an automatic installation apparatus can make detonator assembly described in the utility model become the part of explosion array.When using automatics to carry out explosion, revise and use detonator assembly of the present utility model, demolition set and method are also in scope of the present utility model.

In another embodiment, the blasting method of the detonator assembly that the utility model provides as shown in Figure 5, comprises the steps:

Step S501 is provided with the demolition set that a utility model provides;

Step S502, a large amount of blastings charge is placed in the explosion scene, and its placement location can influence the explosion pattern of expectation;

Step S503, detonator assembly described in the utility model links to each other with each blasting charge, and its primary charge that can ignite each detonator is ignited;

Step S504, the energy receiver of detonator assembly receives from the energy of energy source and gives each detonator assembly charging or power supply, treats blasting state so that each detonator device is in;

Each energy receiver of each detonator assembly is transferred to each detonator assembly from each energy source with the energy of expecting form, so that can received energy be come to make each detonator device be in a kind of appropriate format of ignition thus to each detonator assembly charging or power supply;

Step S505, trigger transmission initiation command signal is to each detonator assembly, so that detonator assembly is discharged into each firing circuit with the electric power energy of storing, to ignite primary charge;

Each trigger transmits at least one command signal, comprises for example firing command signal, to each detonator assembly, so that each detonator assembly is discharged into each firing circuit to the electric power energy of storage, ignites each primary charge thus;

Perhaps, step S504 and S505 can carry out with any order.Command signal further comprises the time delay of each detonator device and ignites code in a preferred embodiment, helps the explosion form result who obtains expecting like this.

In a preferred embodiment, can carry out detection validation, comprise the steps: detonator assembly and the demolition set that the utility model provides

Step S506, whether S507 has sufficient stored energy can activate firing circuit when discharging to detect passive power source.There is not sufficient charging then to get back to step S504.Sufficient energy is arranged, proceed to step S505, promptly primary charge is ignited according to the ignition signal that receives.

The utility model proposes a kind of detonator assembly, supporting demolition set.Detonator assembly described in the utility model uses well-known components to realize avoiding detonator to misquote quick-fried method.By avoiding the physical connection line between detonator assembly and the supporting initiator, utility model person successfully develops a kind of intrinsic safety type detonator assembly.At the scene of detonating, the operator can install the blasting charge and detonator assembly and away from after carry out long-range ignition again, and need not to carry out again complicated field wiring.So not only reduce the time and the cost of blast operations, also improved whole security.

In the utility model biggest advantage is to make the automation mechanized operation of detonator device easier.Need not to carry out between detonator assembly and trigger or power supply physical connection (for example electric wire, detonator, LEDC, or optical cable), by automatic fitting tool the detonator device being packed into holes easilier, for example uses robot system.Like this, the explosive at the scene of explosion around that blast operations person can cost less makes the staff away from harm thus.

Among the utility model embodiment detonator assembly has been described simultaneously, demolition set and blasting method of the present utility model, other the detonator assembly expected thus of person skilled in the art in the industry, though demolition set and blasting method are unspecified also within the scope of utility model.Comprise all embodiments in appended claim scope.In addition, in the embodiment of this diagram and description, the electromagnetic energy that relates to, luminous energy, microwave energy, radio signal, acoustic energy, the wireless energy conversion of electromagnetic induction energy and other form is all mentioned by way of example.Be used to instruct signal and communication or give any kind of detonator assembly " power supply " or " charging " or the energy of form can be by the replacement of other type or form, in the hope of operation and the raising security that realizes expecting.

Claims (14)

1. detonator assembly, this detonator assembly and at least one initiator carry out wireless connections and transmit at least one command signal, it is characterized in that, and this detonator assembly comprises:

Primary charge;

Command signal receives and processor, is used for receiving the above-mentioned wireless command signals of processing;

Power supply is used to described command signal to receive and the processor power supply;

Energy receiver is used to receive the energy of wireless signal;

Converter is used for the above-mentioned power conversion that receives from energy receiver is become electric energy;

Dynamic power supplies is connected with converter, and the electric energy that can store from converter also is the detonator power supply;

Firing circuit is connected with described primary charge, is used to receive the electric energy that stores in the described dynamic power supplies, and ignites;

After above-mentioned command signal reception was received firing command with processor, firing circuit can receive the electric energy that stores in the described dynamic power supplies, activates primary charge, thus ignition.

2. according to the detonator assembly described in the claim 1, it is characterized in that at least one command signal of described transmission is by following medium: radio wave, acoustic energy, electromagnetic energy, or electromagnetic induction; The energy of described energy emitter emission comprises: microwave, electromagnetic wave, acoustic energy or electromagnetic induction.

3. according to the detonator assembly described in the claim 1, it is characterized in that, described command signal reception comprises an electromagnetic energy receiver with processor and energy receiver, described command signal is by electromagnetic wave first wavelength transmission, described energy from energy emitter is launched by electromagnetic second wavelength transmission, and described detonator assembly also comprises:

Discriminating device, link to each other with described electromagnetic energy receiving system, be used to distinguish the electromagnetic energy of described first wavelength and the electromagnetic energy of described second wavelength, the electromagnetic energy of described first wavelength is received by command signal and processor receives and handles, and the electromagnetic energy of described second wavelength is converted device and converts electric energy to.

4. according to the detonator assembly described in the claim 1, it is characterized in that described command signal receives and processor comprises radio wave reception converter, described at least one command signal comprises radio wave, energy receiver comprises the electromagnetic energy receiver, and the energy of described emission comprises electromagnetic energy; Perhaps, described command signal receives and processor comprises the electromagnetic energy receiver, and described at least one command signal comprises electromagnetic energy, and described energy receiver comprises radio receiver, and the energy of described emission comprises radio wave.

5. according to the detonator assembly described in the claim 1, it is characterized in that described command signal receives and processor comprises the first luminous energy receiver; Described command signal comprises the luminous energy of first wavelength; Described energy receiver comprises the second luminous energy receiver; The energy of described emission comprises the luminous energy of second wavelength.

6. according to the detonator assembly described in the claim 1, it is characterized in that described energy receiver comprises an electromagnetic induction energy receiver, the energy of described emission comprises electric energy, and this electric energy to small part is transferred to described detonator assembly by electromagnetic induction; Described electromagnetic induction energy receiver comprises at least one magnetic coupling device, and each electromagnetic induction is relevant with electric wire from the electric current of described energy emitter; Command signal reception and processor and/or energy receiver comprise an electromagnetic energy receiver.

7. according to the detonator assembly described in the claim 6, it is characterized in that described magnetic coupling device is to adopt ferritic toroidal transformer.

8. according to the detonator assembly described in the claim 1, it is characterized in that described dynamic power supplies comprises one of the following at least: electric capacity, diode, rechargeable battery, fuel cell, air cell, audiphone battery, miniature nuclear power source, and active cell.

9. according to the detonator assembly described in the claim 1, it is characterized in that, further comprise: be arranged on the firing switch between described dynamic power supplies and the described detonation circuit, described firing switch is set up electrical link according to the firing command signal that described command signal receiver receives between described passive power source and described detonation circuit, be discharged into detonation circuit with the electric energy that will be stored in described passive power source, ignite described primary charge thus.

10. according to the detonator assembly described in the claim 1, it is characterized in that described command signal reception and processor and/or energy receiver receive luminous energy, comprise a light capture device and the optical cable that is used for the light that the light capture device receives is transferred to converter; Described smooth capture device is placed in the described luminous energy of the above reception in ground, and described optical cable transmission luminous energy is to the converter on ground; The luminous energy that received by each light capture device is from incandescent lamp, laser instrument, laser diode, or LED.

11. the detonator assembly according to described in the claim 1 is characterized in that, described each command signal is to comprise from one group: the ARM signal of waiting to signal, releasing DISARM to be signaled, ignition signal FIRE selects in detonator time delay and the cap sensitive code; Described detonator assembly further comprises:

Signal transmission device is used to produce and transmits at least a command signal that is received by described trigger.

12. the detonator assembly according to described in the claim 3 is characterized in that,

Described discriminating device comprises one or more optical filters;

Wherein, the wavelength of the electromagnetic energy of wavelength ratio second wavelength of the electromagnetic energy of described first wavelength will be grown;

The electromagnetic energy of described first wavelength is from least one red laser;

The electromagnetic energy of described second wavelength is from least one blue laser.

13. a demolition set is characterized in that, comprising:

At least one trigger can be sent to relevant detonator by first medium radio communication with command signal;

At least one blasting charge;

As any described detonator assembly in the claim 1 to 11, at least one detonator assembly is connected with the described blasting charge, and with described at least one trigger communication;

At least one is transmitted into each detonator assembly by the energy emitter of second medium emitted energy, to give each detonator assembly charging, to receive and to respond the firing command signal from described at least one trigger;

Central control station is used to control at least one above-mentioned trigger.

14. the demolition set according to described in the claim 13 is characterized in that,

Send described at least a command signal in the following way: radio signal, electromagnetic energy specifically comprises luminous energy, microwave energy, ultraviolet, acoustic energy or electromagnetic induction;

The energy of emission comprises: radio signal, electromagnetic energy specifically comprises luminous energy, microwave energy, ultraviolet, acoustic energy or electromagnetic induction.

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