Patent Application
20230194228
The invention relates to a wireless electronic initiation device, an initiation arrangement and method for initiation a wireless electronic initiation device.
One known method for activating detonators for blasting is to use shock tubes coupled with the detonators and transporting an initiating signal to the detonators e.g. in a borehole in a rock from an initiation device. The shock tubes are then bound and bundled together and fed along a blasting site to the initiation device.
There are however some disadvantages relating to the known methods, such as binding and bundling lots of shock tubes together. The binding and bundling is very time consuming, as well as very dangerous especially when it is done in a tunnel, where there is a risk of falling rocks, for example. In addition there is also a risk for an accidental initiation of the detonators when the shock tubes are connected. Moreover, an automatic installation of the detonators and the shock tubes and overall system is impossible or at least extreme difficult because of the long shock tubes, which easily meddles with each other or with the environment and obstacles in the blasting site. Still, in addition when the initiation signals are provided to the detonators via long shock tubes, there is a risk that charges when blasting will cause damages to other shock tubes, whereupon some of the detonators will not receive initiation signal.
An object of the invention is to alleviate and eliminate the problems relating to the known prior art. Especially the object of the invention is to provide a wireless electronic initiation device, an initiation arrangement and method for initiation a wireless electronic initiation device so that the binding and bundling of the shock tubes or other long wires can be avoided and thereby fastening the process and thereby also minimise the risk to be in dangerous conditions. An object is also to provide a wireless electronic initiation device, an initiation arrangement and method for initiation a wireless electronic initiation device so that the binding and bundling of the shock tubes or other long wires with the wireless electronic initiation device can be avoided. An additional object of the invention is to enable automatic installation of the detonators and the overall initiation system. An object is also to eliminate the risk of an accidental initiation of the detonators when installation the detonators and initiation system. In addition an object is to provide a method and system for transmitting initiation signals in a reliable way and minimizing environmental disturbing effects and features.
The object of the invention can be achieved by the features of independent claims.
The invention relates to a wireless electronic initiation device for a detonator via a detonator initiator according to claim 1. In addition the invention relates to an initiation arrangement according to claim 11, a method for initiation a wireless electronic initiation device according to claim 17 and a use of the wireless initiation device according to claim 18.
According to an embodiment of the invention a wireless electronic initiation device for a detonator via a detonator initiator, such a shock tube or an electric fusehead, is provided. The detonator can be any detonator known from prior art, such as a pyrotechnic or electrical fusehead detonator. The initiation device comprises an initiation member for initiation or activating the detonator initiator and thereby transmitting the initiation signal to the detonator. The initiation device may comprise an output or connector for connecting the initiation device to the shock tube, such as electrodes implemented by teeth or pins, which can be pressed through the shock tube, for example, so that when ignite a spark is induced between the electrodes thereby activating the shock tube. Naturally also other types of connection methods can be utilized, such as an electric fuse or an initiation fuse head. As an example the initiation member can be inserted into or on the center hole of the shock tube, or the initiation member penetrated through the side wall of the shock tube. In addition the initiation device may comprise a connector for connecting the initiation device to the shock tube, such as a short length of the shock tube integrated into the initiation device or other tube via which the actual shock tube can be coupled with the initiation device.
According to an embodiment the initiation device may comprise a bunch connector for connecting the initiation device to number of shock tubes at the one connection maneuver. The bunch connector advantageously comprises number of outputs for connecting number of the shock tubes, which is advantageously prepared first, and then at least one input for connecting the initiation device. As an example, there may be, for example, ten shock tubes connected to the outputs of the bunch connector, after which the initiation device is connected to the input of the bunch connector.
According to an advantageous embodiment the initiation device is configured to receive energy in a wireless manner outside from the initiation device and additionally to charge a energy storage by the received energy. In addition the initiation device is configured also to receive an initiation command in a wireless way outside from the initiation device.
The initiation device may comprise a first wireless communication device with a receiver for receiving said initiation command and said energy. Alternatively, or in addition to, the initiation device may also comprise a second wireless communication device for receiving said energy, whereupon the first wireless communication device can be used only for receiving said initiation command or both the initiation command and energy.
According to an embodiment the initiation device comprises the first wireless communication device with a receiver for receiving an initiation command in a wireless way outside from the initiation device. The first wireless communication device is advantageously a radio communication device, but can also be implemented by an acoustic receiver or optical or inductive receiver, which is configured for receiving an initiation command in a wireless way outside from the initiation device.
The initiation device also comprises the energy storage for providing initiation energy to the initiation member after charged. The energy storage may be e.g. a capacitor, a supercapacitor or a battery. It is advantageous to use a chargeable energy storage that can be charged in a wireless manner outside the initiation device. The wireless charging offers clear safety advantage namely the energy storage can be kept left or at least at so low level that it is unable to provide enough energy for the shock tube for initiation. Thus the initiation device and the detonators can be installed safely. It is to be noted that the initiation device may comprise a separate energy storage, such as a battery or capacitor or the like for providing energy for wireless communication.
The initiation device comprises advantageously also a controller, which advantageously controls e.g. an operation of an initiation circuit as well as determines the received initiation command and its authenticity. Based on the received initiation command the controller advantageously activates the initiation member to ignite the detonator initiator, such as the shock tube, by the energy fed from the energy storage, if the received initiation command was correct and for the initiation device in question. The initiation circuit can be used for example for feeding initiation energy from the energy storage to the initiation member under control of the controller.
The initiation device may also comprise a second wireless communication device, which is configured to receive energy in a wireless manner outside from the initiation device and charge the energy storage, such as the capacitor, by the received energy using e.g. a regulator and other suitable additional equipment. The second wireless communication device is according to an embodiment radio receiver, but can also be implemented by another technique such as by an induction receiver, acoustic receiver or optic receiver. The form of the energy delivered depends naturally on the used technique. For example, according to an embodiment, said energy may be electromagnetic radiation, especially high or ultrahigh frequency radio waves, and in particularly microwave radiation having frequency in the range of 2-4 GHz, most advantageously around 2.45 GHz. The transmit power may be for example 500 W.
The initiation device advantageously controls the charging process of the energy storage. In particularly the controller allows the activation of the initiation member only when the energy storage is charged enough to provide initiation energy suitable to execute initiation command sequence and then finally ignite the detonator initiator, like the shock tube.
When the energy storage is charged enough to provide energy suitable to execute initiation command sequence, the initiation device establishes a communication test with at least two different frequencies with the first wireless communication device to an initiation arrangement. The initiation arrangement comprises at least one first transceiver for communicating with said first wireless communication device of the initiation device. According to an embodiment the initiation device may transmit the communication test using one or more frequencies and the initiation arrangement may respond using one or more frequencies. After this the initiation device selects, via the communication test with the initiation arrangement, the frequency with highest signal strength to be used for receiving said initiation command, or when the signal having strength over a predetermined threshold value is established, said frequency is selected, even if it was the first frequency. According to an embodiment of the invention, when all initiation devices in the blasting site have established the communication test with the initiation arrangement, the initiation arrangement provides the initiation commands in to the wireless electronic initiation devices by transmitting the initiation command in a wireless way to the initiation devices.
It is to be noted that the steps can also be performed in other order so that the communication test is performed first and when it is accepted and the frequency for communication is selected, and after that the energy is received and the energy storage loaded.
Most advantageously the initiation arrangement transmits the initiation command by sweeping the transmission frequency in a predetermined transmission frequency range covering at least the frequencies used by the initiation devices in order to assure that the communication is not disturbed by a multipath fading for the plurality of the initiation devices.
According to an embodiment the first and second wireless communication devices can be implemented by one device, as described elsewhere in this document. The first and second wireless communication devices of the initiation device may also be different and separate devices functioning with different frequencies, whereupon one can be sure that they are not disturbing each other. However according to an embodiment both devices can also function with the same frequency range, whereupon the initiation command advantageously comprises a code identifying the initiation command so that the initiation device can be determine whether the initiation command is as an acceptable initiation command and thereby either ignore or running said initiation command in order to activate the initiation member to ignite the detonator initiator by the energy fed from the energy providing member. The initiation command may also comprise a delay or timing information so that the initiation device can control the timing of running the initiation command.
As discussed elsewhere in this document the initiation arrangement comprises at least one first transmitter for transmitting the initiation command in a wireless way to the initiation device. In addition to that the initiation arrangement advantageously comprises also a second transmitter for transmitting energy in a wireless manner to the initiation device in order to charge the energy storage by said transmitted energy. The second transmitter is advantageously a radio transmitter for transmitting said energy via radio waves, but can also be implemented in other ways depending on the techniques used, such as being an induction transmitter for transmitting said energy via induction, or an acoustic transmitter for transmitting said energy via acoustic waves or optical transmitter for transmitting said energy optically.
Alternatively or in addition to the first transmitter may also be used to transmit also energy in a wireless manner to the initiation device in order to charge said energy storage said transmitted energy.
The initiation device is advantageously implemented as a mobile module, which can be connected to the detonator via the detonator initiator, such as the shock tube. The shock tube used is advantageously only a short tube, the other end of which is coupled with the detonator and the other end of which is coupled to the initiation device. The initiation device as such is advantageously configured to be mounted on or into a borehole to which said detonator is to be installed. Most advantageously the initiation device is configured to be located outside the bore hole thereby allowing better transmission and propagation of the radio waves used for example for initiation commands and for charging the energy storage.
The present invention offers advantages over the known prior art, such as described in this document. Especially the wireless charging offers clear safety advantage namely the energy storage of the initiation device can be kept empty or at least at so low level that it is unable to provide enough energy for the shock tube for initiation. Thus the initiation device and the detonators can be installed safely without risk for blasting too early or in unwanted situation. In addition the initiation commands are transmitted by sweeping the predetermined transmission frequency range covering at least the frequencies used by the initiation devices in order to assure that the communication is not disturbed by a multipath fading for the plurality of the initiation devices. Moreover the initiation devices are configured to make communication tests before the initiation commands are transmitted and to select the frequency having power with strength over a predetermined threshold value, or if over one frequencies are used, to select the frequency from at least two different frequencies which has stronger transmit power.
The exemplary embodiments presented in this text are not to be interpreted to pose limitations to the applicability of the appended claims. The verb “to comprise” is used in this text as an open limitation that does not exclude the existence of also unrecited features. The features recited in depending claims are mutually freely combinable unless otherwise explicitly stated.
The novel features which are considered as characteristic of the invention are set forth in particular in the appended claims. The invention itself, however, both as to its construction and its method of operation, together with additional objects and advantages thereof, will be best understood from the following description of specific example embodiments when read in connection with the accompanying drawings.
Next the invention will be described in greater detail with reference to exemplary embodiments in accordance with the accompanying drawings, in which:
The initiation device comprises also an energy storage 105, such as a battery or a loadable capacitor. In addition the initiation device 100 comprises also a controller 102 for controlling e.g. an operation of an initiation circuit 103 (optional) as well as for determining the received initiation command and its authenticity and other task described elsewhere in this document.
The initiation device comprise also advantageously a second wireless communication device 104 for receiving energy in a wireless manner outside from the initiation device and charge the energy storage 105. The second wireless communication device 104 is according to an embodiment radio receiver using either own antenna (not shown) or a common antenna 107 with the first wireless communication device 101, but can also be implemented by another technique such as by an induction receiver, acoustic receiver or optic receiver.
It is to be noted that even if the first and second wireless communication devices 101, 104 are illustrated as separate devices, they can also be implemented, according to an embodiment of the invention, by integrating to one IC circuit, or they can be implemented by one device 101, as described elsewhere in this document.
According to an embodiment the initiation device 100 may also comprise a connector 108A for connecting the initiation device to the detonator initiator, such as the shock tube 108 in Figures. However, this is an optional feature.
According to an embodiment the first transceiver can also transmit energy in a wireless manner 206 to the initiation devices 100 in order to charge the energy storages 105 in the initiation devices. The first transceiver can operate in this embodiment e.g. with different frequencies for transmitting energy and the initiation commands.
According to an embodiment the initiation arrangement 200 comprises also a second transceiver or transmitter 202 for transmitting said energy in a wireless manner 206 to the initiation devices in order to charge the energy storages 105 of the initiation devices. The second transceiver or transmitter 202 can be implemented by a radio transceiver or transmitter for transmitting said energy via radio waves. Alternatively the second transceiver or transmitter can be implemented by other techniques known by the skilled person as is discussed in this document elsewhere.
In operation the initiation arrangement 200 transmits 206 at first the energy used for charging and at the same time or next is configured to receive communication signals 110 from the initiation devices 100. However the steps can be performed also in other order so to establish the communication first and after this transferring said energy. Each of the initiation devices 100 controls the charging process of its energy storage 105. When the energy storage 105 is charged enough to provide energy suitable to execute initiation command sequence, the initiation device in question establishes a communication test 110 with at least two different frequencies with the first wireless communication device 101 to an initiation arrangement 200. The initiation arrangement can receive these communications with different frequencies by the first transceiver 201 and send back 206 communication signals by these different frequencies. The initiation device is configured to receive these communication signals 206 and selecting the frequency with the highest signal strength to be used after for receiving the initiation command send by the initiation arrangement.
When all initiation devices 100 in the blasting site have established the communication test with the initiation arrangement 200 or other parameters are fulfilled (like at least a certain percent of the initiation devices are ready and a certain predetermined time has lapsed), the initiation arrangement 200 provides the initiation commands to the wireless electronic initiation devices 100 by transmitting the initiation command in a wireless way 206 to the initiation devices 100 by sweeping the transmission frequency in a predetermined transmission frequency range covering at least the frequencies used by the initiation devices in order to assure that the communication is not disturbed by a multipath fading for the plurality of the initiation devices.
The initiation arrangement 200 comprises also advantageously own energy storage 203 and/or energy receiving means for receiving energy outside, such as from an electricity network (not shown), as well as a controller 204 for controlling the energy transmission and sending from the energy storage 203 via said first and/or second transceiver and an antenna 205 to the initiation devices 100. The controller 205 is also configured to manage said radio communication, so receiving the communication tests 110 with at least one or more different frequencies and managing the back communication with at least one or more different frequencies.
According to an embodiment the wireless electronic initiation devices 100 can also send the communication test 110 only by one frequency listened by the initiation arrangement 200, whereafter the initiation arrangement 200 sends back 206 the communication signals by at least one or more different frequencies from which the initiation devices 100 select suitable frequency to be used for receiving the initiation commands.
The invention has been explained above with reference to the aforementioned embodiments, and several advantages of the invention have been demonstrated. It is clear that the invention is not only restricted to these embodiments, but comprises all possible embodiments within the spirit and scope of the inventive thought and the following patent claims. In particularly it is to be noted that even if the shock tube is illustrated in Figures and in many embodiments, it is only an example and that the detonator initiator can also implemented by an electric fusehead.
In addition it is to be noted that even if two separate wireless communication devices are illustrated in Figures and in many embodiments, the device may either comprise a first wireless communication device for receiving said initiation command and said energy, or a first wireless communication device for receiving said initiation command, and in addition a second wireless communication device for receiving said energy.
The features recited in dependent claims are mutually freely combinable unless otherwise explicitly stated.
| Number | Date | Country | Kind |
|---|---|---|---|
| 20175388 | May 2017 | FI | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/FI2018/050324 | 5/3/2018 | WO |
