EP3371544B1 - Method of firing an electronic detonator and electronic detonator - Google Patents

Description

The present invention relates to a method of firing an electronic detonator, as well as an electronic detonator implementing the firing method.

In general, a set of electronic detonators is connected to the same control system, the control system being configured to manage the operation of the electronic detonators, as well as to supply them.

Each electronic detonator is connected to the control system by means of electrically conductive wires (corresponding to the wires of the detonator, the bus line and the firing line), and comprises in particular an explosive or detonating charge, a primer or ignition module with electronic control, and means for memorizing a firing delay time, this delay time corresponding to the time to be counted between the reception by the electronic detonator of a firing command or order and the firing well said.

Thus, an electronic detonator furthermore comprises electronic circuits configured to reproduce the firing delay time, for example by carrying out a countdown corresponding to the delay time as from the reception of the order or the firing order. fire.

In some cases (for example when the electrical conductors have been cut by one of the previous detonations), once the control system issues a firing command, the electronic detonators are no longer supplied by the control system, the 'power supply to each electronic detonator being provided by energy storage means on board each detonator.

The energy storage means on board an electronic detonator allow, in addition to supplying the various electronic circuits in the detonator such as circuits reproducing the delay time, storing the energy necessary for igniting the electronic detonator.

If the energy stored in the energy storage means decreases so that the means of the electronic circuits are not supplied, the ignition delay time is not reproduced, the ignition of the electronic detonator does not being not implemented.

Similarly, the electronic detonator is not ignited if the energy stored in the energy storage means decreases so that the energy required to ignite is not sufficient in the storage means energy, especially after the delay time has elapsed.

Failure to ignite an electronic detonator presents a significant security risk.

The present invention aims to provide a method of firing an electronic detonator, as well as an electronic detonator in which security is improved.

In this regard, the present invention relates in a first aspect to a method of igniting an electronic detonator comprising energy storage means, the method comprising a reception by the electronic detonator of a firing order.

• mesure d'une énergie stockée dans les moyens de stockage d'énergie,
• lorsque l'énergie stockée mesurée est inférieure ou égale à une énergie prédéterminée, détermination de l'écart de temps existant entre une période de temps écoulée à compter de la réception de l'ordre de mise à feu et le temps de retard associé au détonateur électronique, et
• mise à feu du détonateur électronique lorsque l'écart de temps est inférieur à une valeur de temps prédéterminée.

According to the invention, the method according to independent claim 1 comprises the following steps implemented as long as a delay time associated with the electronic detonator has not elapsed from said reception of the firing order:

• measurement of energy stored in the energy storage means,
• when the measured stored energy is less than or equal to a predetermined energy, determination of the time difference existing between a period of time elapsed from receipt of the firing order and the delay time associated with the detonator electronic, and
• firing of the electronic detonator when the time difference is less than a predetermined time value.

Thus, as soon as the electronic detonator receives a firing order and as long as the delay time associated with the electronic detonator has not elapsed, the energy stored in the energy storage means is monitored so as to ignite the electronic detonator if the measured stored energy is less than or equal to a predetermined energy and if the time difference existing between a period of time elapsed from receipt of the firing order and the delay time associated with the electronic detonator is less than a predetermined time value.

When it has been observed that the measured stored energy is less than or equal to the predetermined energy, it is checked whether the time difference between the associated delay time and the time elapsed since the reception of the placing order fire is less than a predetermined time value, the firing step being only implemented, if the time difference is less than or equal to the predetermined time difference value.

On the contrary, if the time difference is greater than the predetermined time value, the countdown of the delay time associated with the electronic detonator continues.

Consequently, the method makes it possible to fire an electronic detonator although the delay time associated therewith has not elapsed since the reception of the firing command.

This represents a means of controlling the firing of the electronic detonator other than by counting the delay time and thus improving the security relating to the electronic detonator.

For example, the predetermined energy corresponds to a minimum energy necessary to power and ignite the electronic detonator.

Consequently, when the energy stored in the energy storage means reaches a minimum value no longer allowing the supply and / or firing of the electronic detonator, the firing of the electronic detonator is implemented without waiting the delay time has elapsed.

Indeed, when the stored energy is greater than the predetermined energy, the energy storage means contain the energy necessary to supply the electronic detonator and for the actual firing.

On the contrary, when the stored energy reaches the predetermined energy or is lower than the predetermined energy, there is a risk of non-firing of the electronic detonator.

Thus, the electronic detonator is ignited as soon as the energy stored in the energy storage means reaches the predetermined energy in order to prevent the electronic detonator from ever being ignited.

It will be noted that if the stored energy is less than the predetermined energy, either the countdown of the delay time can not be implemented and therefore the electronic detonator will never be ignited although there is energy necessary for ignition, either the counting of the delay time can be implemented but the energy remaining in the storage means is not sufficient for ignition, or there is no energy left or for the power supply or for igniting the electronic detonator.

According to one characteristic, the firing method further comprises a step of comparing the stored energy measured with the predetermined energy.

According to one characteristic, the step of measuring the stored energy comprises a step of measuring a voltage across the terminals of the energy storage means, and the comparison step comprises a step of comparing the measured voltage with a predetermined voltage representative of the predetermined energy.

Thus, when the voltage measured at the terminals of the energy storage means is less than or equal to the predetermined voltage, the firing step of the electronic detonator is implemented before the delay time has elapsed.

Indeed, if the voltage measured at the terminals of the energy storage means is less than or equal to the predetermined voltage, the electronic detonator is ignited before the energy stored by the energy storage means is no longer sufficient so that the electronic detonator is fired.

Thus, the electronic detonator is ignited while enough energy remains to power it and to initiate the detonating charge of the electronic detonator.

It follows that as long as the voltage measured at the terminals of the energy storage means is not less than the predetermined voltage, the countdown of the delay time continues and the firing step of the electronic detonator is started after the delay time associated with the electronic detonator has elapsed.

In one embodiment, the step of measuring the stored energy comprises a first step of measuring the energy stored in first energy storage means and a second step of measuring the energy stored in second energy storage means, the firing of the electronic detonator being implemented if the stored energy measured in the first measurement step is less than or equal to a first predetermined energy or if the stored energy measured in the second step measurement is less than or equal to a second predetermined energy.

In this embodiment, the first predetermined energy corresponds to a minimum energy necessary to power the electronic detonator and the second predetermined energy corresponds to a minimum energy necessary to ignite the electronic detonator.

Furthermore, the comparison step comprises a first step of comparing the stored energy measured in the first measurement step with the first predetermined energy and a second step of comparing the stored energy measured in the second measurement step with the second predetermined energy.

In this embodiment, the energy storage means of the electronic detonator thus comprise two different energy storage means, the firing of the electronic detonator being implemented when the stored energy measured in the first measurement step is less than or equal to the first predetermined energy and / or the stored energy measured in the second measurement step is less than or equal to the second predetermined energy.

It is thus possible to separately monitor the minimum energy required to ignite the electronic detonator and the minimum energy required to power the electronic detonator.

When one of the energies reaches a minimum value, the electronic detonator is fired in advance.

The present invention relates in a second aspect to an electronic detonator according to independent claim 5 comprising energy storage means and means for receiving a firing order.

• des moyens de mesure d'une énergie stockée dans les moyens de stockage d'énergie,
• des moyens de détermination de l'écart de temps existant entre une période de temps écoulée à compter de la réception de l'ordre de mise à feu et le temps de retard associé au détonateur électronique, l'écart de temps étant déterminé lorsque l'énergie stockée mesurée par les moyens de mesure est inférieure ou égale à une énergie prédéterminée, et
• des moyens de mise à feu configurés pour mettre en œuvre la mise à feu du détonateur électronique avant qu'un temps de retard associé au détonateur électronique ne s'écoule pas, lorsque l'écart de temps déterminé par les moyens de détermination est inférieur à une valeur de temps prédéterminée.

According to the invention, the electronic detonator further comprises:

• means for measuring an energy stored in the energy storage means,
• means for determining the time difference between a period of time elapsed from receipt of the firing order and the delay time associated with the electronic detonator, the time difference being determined when the stored energy measured by the measuring means is less than or equal to a predetermined energy, and
• firing means configured to initiate firing of the electronic detonator before a delay time associated with the electronic detonator does not elapse, when the time difference determined by the determining means is less than a predetermined time value.

According to one characteristic, the electronic detonator comprises means for comparing the stored energy measured by the measuring means with said predetermined energy.

According to one characteristic, the means for measuring the energy stored in the energy storage means comprise means for measuring the voltage at the terminals of said energy storage means, and the comparison means comprise means for comparing d a voltage measured by the measuring means at a predetermined voltage representative of the predetermined energy.

In one embodiment, the energy storage means comprise first energy storage means configured to store the energy necessary for supplying the electronic detonator and second energy storage means configured to store the energy necessary for firing the electronic detonator.

Thanks to the different energy storage means for storing the energy necessary for supplying the electronic detonator and for storing the energy necessary for igniting the electronic detonator, it is possible to measure the voltage at terminals of each of said energy storage means and igniting the detonator when one of the voltages is less than or equal to a predetermined voltage.

According to one characteristic, the energy storage means comprise a capacitor.

The present invention aims, according to a third aspect, to a detonation system comprising a set of electronic detonators according to the invention and implementing the firing method according to the invention. The electronic detonator and the detonation system have advantages similar to those described above with reference to the firing method according to the invention.

Other features and advantages of the invention will appear in the description below.

• la figure 1 représente schématiquement un système de détonation conforme à un mode de réalisation comportant plusieurs détonateurs électroniques ;
• la figure 2 représente un détonateur électronique selon un mode de réalisation de l'invention ;
• la figure 3 illustre un organigramme représentant le procédé de mise à feu d'un détonateur électronique selon un mode de réalisation de l'invention ; et
• les figures 4a, 4b et 4c représentent des exemples d'évolution dans le temps de la tension aux bornes des moyens de stockage d'énergie.

In the appended drawings, given by way of nonlimiting examples:

• the figure 1 schematically represents a detonation system according to an embodiment comprising several electronic detonators;
• the figure 2 represents an electronic detonator according to an embodiment of the invention;
• the figure 3 illustrates a flowchart representing the method of firing an electronic detonator according to an embodiment of the invention; and
• the Figures 4a, 4b and 4c represent examples of evolution over time of the voltage across the energy storage means.

The figure 1 represents a detonation system comprising several electronic detonators 1, 2, ..., N.

The electronic detonators 1, 2, ..., N are connected to a firing unit or control system 20 through electrically conductive wires 30. The electrical conductor wires 30 include wires from the detonator, a bus line and a firing line.

The control system 20 is responsible in particular for supplying the electronic detonators 1, 2, ..., N, for verifying that they operate correctly and for managing their operation, for example for controlling their firing.

To do this, the control system 20 includes electronic circuits necessary to manage the operation of all the electronic detonators and to communicate with them.

Thus, the firing unit or control system 20 generates supply signals as well as control signals, for example test signals or firing signals. These signals are sent via the electric conductor wires 30 to the electronic detonators 1, 2, ..., N.

Each electronic detonator 1, 2, ..., N has a delay time associated with it, for example by reception through the electric conducting wires 30, the delay time coming from the firing unit 20, or by reception by other wired or non-wired means from another unit, such as a console or programming unit (not shown in the figure).

The figure 2 shows an electronic detonator 1 in accordance with an embodiment of the invention.

The essential means for implementing the invention are shown on the figure 2 .

The electronic detonator 1 includes a heating resistor R intended to ignite a detonating charge (not shown in the figure) when the electronic detonator 1 is ignited.

The electronic detonator 1 further comprises energy storage means 100 necessary in particular for supplying the electronic detonator 1 in the event that it is not supplied by the firing unit 20, as well as for firing proper of the electronic detonator 1.

It will be noted that before a firing order is issued by the firing unit 20, the electronic detonator 1 is supplied through the conducting wires electrical 30. In particular, a supply signal from the firing unit 20 is rectified by a rectifier bridge 300 connected to the input of the electronic detonator 1, the supply signal charging the energy storage means 100 with energy. .

In the embodiment shown in the figure 2 , the energy storage means 100 comprise first energy storage means 101 configured to store the energy necessary for supplying the electronic detonator 1, and second energy storage means 102 configured to store the energy required to ignite the electronic detonator 1.

According to other embodiments, the first and second energy storage means 101, 102 can be replaced by unique energy storage means storing the energy necessary for supplying the electronic detonator 1 and for its Firing.

In the embodiment represented by the figure 2 , the first and second energy storage means 101, 102 respectively comprise a capacitor.

The capacitor of the first storage means 101 is called the supply capacitor 101 and the capacitor of the second storage means 102 is called the shot capacitor 102.

Thus, the supply capacitor 101 includes the energy necessary to maintain the supply voltage of the electronic detonator 1 and, in particular, of the electronic circuits necessary for the operation of the electronic detonator 1, for a period of time.

The firing capacitor 102 stores the energy necessary to maintain a voltage necessary for firing the electronic detonator 1.

The electronic detonator 1 also comprises a control module 200 comprising electronic circuits necessary to manage the operation of the electronic detonator 1.

For example, the control module 200 controls the opening and closing of the switches T1, T2 making it possible respectively to charge the shot capacitor 102 and connect the shot capacitor 102 to the heating resistor R when the electronic detonator 1 is ignited.

For example, the control module 200 includes a microcontroller 201 configured to manage the operation of the electronic detonator 1.

In particular, the microcontroller 201 includes means for receiving a firing order. This firing order is received from the firing unit 20. It further comprises means for counting the delay time associated with the electronic detonator 1, that is to say the time elapsed since the electronic detonator 1 receives the firing order from the firing unit or control system 20 and to initiate firing once the time countdown reaches the delay time associated with the electronic detonator 1.

The electronic detonator 1, and in particular the control module 200, further comprises means for measuring the stored energy 202 in the energy storage means 100 and means for comparing the stored energy measured with an energy predetermined.

In one embodiment, the means for measuring the energy stored in the energy storage means 100 comprise means for measuring the voltage at the terminals of the energy storage means 100 and the means for comparing the stored energy measured at a predetermined energy include means for comparing a voltage with a predetermined voltage.

Thus, in the embodiment shown in the figure 2 , the measuring means comprise means for measuring the voltage across the supply capacitor 101 and across the firing capacitor 102.

Measuring the voltage across the supply capacitor 101 makes it possible to know whether it contains the energy necessary for supplying the electronic detonator 1, in particular for supplying the electronic circuits managing its operation 200.

The measurement of the voltage across the terminals of the firing capacitor 102 makes it possible to know whether it contains sufficient energy for the actual firing of the electronic detonator 1.

In one embodiment, the means for measuring the stored energy 202 comprise an analog digital converter 202 (ADC or ADC in Anglo-Saxon nomenclature for " Analog Digital Converter "). Thus, the voltage across the supply capacitor 101 and the shot capacitor 102 is measured by means of the analog-to-digital converter 202.

In this embodiment, the electronic detonator 1 comprises a single analog-to-digital converter 202 for sampling the voltages across the terminals of the supply capacitor 101 and the shot capacitor 102. Thus, in this embodiment, the control module 200 comprises a multiplexer 203 having two inputs 203a, 203b and an output 203c.

Of course, the electronic detonator could include two analog digital converters instead of a multiplexer.

In other embodiments not shown, the energy measurement and comparison means may include other means, for example analog voltage measurement and comparison means.

In the embodiment shown, the first input 203a of the multiplexer 203 is connected to the supply capacitor 101 and the second input 203b is connected to the shot capacitor 202. The output 203c of the multiplexer 203 is connected to the input 202a of the converter analog digital 202.

The voltage across the supply capacitor 101 and the voltage across the shot capacitor 102 is sampled by the analog to digital converter 202, each in turn.

In particular, the microcontroller 201 provides for carrying out the voltage measurements at the terminals of the supply capacitor 101 and the firing capacitor 102 periodically and of course only one at a time. Conventionally, the voltages at inputs 203a, 203b are transmitted to its output 203c each in turn.

Thus, when the microcontroller 201 controls the measurement of the voltage across the supply capacitor 101, the first input 203a of the multiplexer 203 is selected and the voltage at this first input 203a is transmitted to the output 203c of the multiplexer 203, that is to say to the input 202a of the analog-digital converter 202.

In the embodiment described, the voltage measured at the terminals of the power supply 101 and firing 102 capacitors can be compared respectively with a predetermined voltage representative of a predetermined energy.

Of course, the predetermined voltages for the supply capacitor 101 and for the firing capacitor 102 may have different values.

The measurement and comparison of the voltages will be described later with reference to the figure 3 .

The output of the analog digital converter 202b is sent to the microcontroller 201 where the comparison means will compare the voltage received from the analog digital converter 202 with a predetermined voltage representative of a predetermined energy.

In one embodiment, the predetermined energy corresponds to the minimum energy necessary to power the electronic detonator 1 and to ignite it.

It will be noted that the predetermined energy takes account of a margin corresponding to the time elapsed between the moment when it is observed that the electronic detonator 1 must be fired in advance and the moment of the firing itself.

In another embodiment not shown in the figures, the energy storage means comprise a single capacitor in which the energy required makes it possible to maintain an adequate voltage for supplying the electronic detonator and for firing it.

In this embodiment, the analog-to-digital converter directly samples the voltage across said capacitor, without the need for a multiplexer.

The figure 3 shows a flowchart representing the method of firing an electronic detonator according to an embodiment of the invention. The electronic detonator is such as that shown in the figure 2 . Of course, the firing method according to the invention can be implemented in electronic detonators according to other embodiments.

In a detonation system as shown in the figure 1 , the electronic detonators 1, 2, ..., N are supplied or energized E0 by the firing unit 20 by means of the electric conducting wires 30.

When the electronic detonators 1, 2, ..., N are energized, they listen to detect the reception of a firing order.

The electronic detonators 1, 2, ..., N are thus placed in this listening step E1 of a firing order.

Of course, the electronic detonators 1, 2, ..., N can implement other tasks while remaining attentive to a fired order.

The detection of the reception of a firing order is implemented during a verification step E2 of the reception of a firing order.

When the reception of a firing order is detected during the verification step E2, the firing method comprises a step of measuring an energy stored in the energy storage means 100.

In the embodiment described, the step of measuring the stored energy includes a step of measuring the voltage E3 across the terminals of the energy storage means 100.

This step of measuring the voltage E3 at the terminals of the energy storage means 100 is implemented as long as a delay time associated with the electronic detonator 1 does not elapse as from the reception of the order to put fire (or the detection of the reception of the firing order in the verification step E2).

In the embodiment described, corresponding to an electronic detonator such as that shown in the figure 2 , the measurement of the voltage E3 at the terminals of the energy storage means 100 comprises a first measurement across the supply capacitor 101 and a second measurement across the shot capacitor 102.

Of course, when only one energy storage means is present in the electronic detonator 1, 2, ..., N, only one voltage measurement is implemented.

In addition, the ignition method according to the invention includes a step of comparing the stored energy measured with the predetermined energy.

In the embodiment described, the ignition method comprises a step E4 of comparing the measured voltage to a predetermined voltage which is representative of a predetermined energy.

The predetermined energy corresponds to a minimum energy necessary to power and ignite the electronic detonator 1, 2, ..., N.

In an electronic detonator such as that shown in the figure 2 , the comparison step E4 includes a first step of comparing the voltage measured across the supply capacitor 101 with a first predetermined voltage V _A ( Figures 4a, 4b and 4c ) and a second step of comparing the voltage measured across the terminals of the shot capacitor 102 with a second predetermined voltage V _T ( Figures 4a, 4b and 4c ).

Of course, the values of the first predetermined voltage V _A and of the second predetermined voltage V _T may be different or equal to each other.

The first predetermined voltage V _A corresponds to the minimum energy required to supply the electronic detonator. The second predetermined voltage V _T corresponds to a second minimum energy necessary for igniting the electronic detonator.

Of course, in the case of an electronic detonator comprising unique energy storage means, a single voltage is measured across the terminals of the energy storage means, this voltage being compared to a single predetermined voltage corresponding to a minimum energy necessary to power and ignite the electronic detonator 1, 2, ..., N.

If in the comparison step E4 of the stored energy measured with the predetermined energy, the measured energy is less than or equal to the predetermined energy, a firing step E7 is implemented (early firing ).

In an electronic detonator such as that shown in the figure 2 , if when in the voltage comparison step E4, the voltage measured across the supply capacitor 101 is less than the first predetermined voltage V _A , and / or the voltage measured across the firing capacitor 102 is less than or equal to the second predetermined voltage V _T , the ignition step E7 is implemented.

Thus, when one of the voltages measured at the terminals of the supply capacitor 101 and of the shot capacitor 102 is less than or equal to the corresponding predetermined voltage V _A , V _T , the firing step E7 of the electronic detonator 1 is executed without waiting for the delay time associated with the electronic detonator to have elapsed.

In the embodiment shown in the figure 3 , when it is determined in the comparison step E4 that at least one of the measured voltages is less than or equal to the corresponding predetermined voltage, the ignition method further comprises a step of determining E8 of the time difference between a period of time elapsed from the receipt of the firing order, and the delay time associated with the electronic detonator 1, 2, ..., N.

When the determined time difference is less than a predetermined time value during this determination step E8, the firing E7 of the electronic detonator 1, 2, ..., N is implemented.

On the contrary, when the deviation determined in the determination step E8 is greater than a predetermined time value, the firing process continues with the step of counting the delay time E5.

Thus, in this embodiment, when a voltage across the terminals of the energy storage means 100 is less than or equal to a predetermined voltage and the difference in time existing between a period of time elapsed from the reception of the firing order and delay time associated with the electronic detonator 1, 2, ..., N is less than a predetermined time value, the firing step E7 is implemented although the delay time associated with the electronic detonator 1 has not elapsed at count from receipt of the firing order.

If in the comparison step E4, the voltages V ₁₀₁ , V ₁₀₂ ( Figures 4a, 4b and 4c ) measured at the terminals of the supply capacitor 101 and of the firing capacitor 102 are respectively greater than the first predetermined voltage V _A , and the second predetermined voltage V _T , the countdown of the delay time E5 associated with the electronic detonator 1, 2 , ..., N continues.

During a verification step E6, it is verified whether the delay time associated with the electronic detonator 12, ... N has elapsed from the reception of the firing order. In the positive case, the electronic detonator 1, 2, ..., N is fired during the firing step E7.

It will be noted that the firing of the electronic detonator 1, 2, ..., N once the delay time associated therewith has elapsed, represents a firing case implemented normally.

As long as at the verification step E6 of the delay time associated with the electronic detonator 1, 2, ..., N, it is not observed that the delay time has elapsed, the measurement step E3 of the voltage across the terminals of the energy storage means 100 (supply capacitor 101 and shot capacitor 102 in the embodiment described) as well as the step of comparison E4 of the voltage measured with the predetermined voltage (first voltage predetermined V _A , and second predetermined voltage V _T ) respectively is implemented.

The Figures 4a, 4b, 4c illustrate curves representative of the voltage values measured at the terminals of the supply capacitor 101 and at the terminals of the firing capacitor 102 as a function of time.

The Figures 4a, 4b and 4c represent a level of a first predetermined voltage V _A representing the minimum energy necessary for supplying the electronic detonator 1, 2, ..., N, and a level of a second predetermined voltage V _T representing the minimum energy necessary for the actual firing of the electronic detonator 1, 2, ..., N.

The curve V ₁₀₁ represents the voltage across the supply capacitor 101, and the curve referenced V ₁₀₂ represents the voltage across the firing capacitor 102.

The time instant t ₁ represents an instant at which a firing order is received by the electronic detonator 1, 2, ..., N (detection of the reception of a firing order during the step E2).

It is thus, at this instant of time t ₁ , that the countdown of the delay time associated with the electronic detonator 1, 2, ..., N begins.

The second time instant t ₂ represented in the figures represents the moment at which the electronic detonator 1, 2, ..., N is no longer supplied or is partially supplied by the firing unit 20.

The third instant of time t ₃ represents the instant at which the countdown of the delay time associated with the electronic detonator 1, 2, ..., N has elapsed, instant at which the electronic detonator 1, 2, ..., N must be ignited.

In the figure 4a , the voltage across the supply capacitor V ₁₀₁ and that across the firing capacitor V ₁₀₂ decrease from the second instant of time t ₂ and always remains greater than the predetermined voltages V _T , V _A for the supply capacitor 101 and for the shot capacitor 102 until the delay time has elapsed.

Thus, in this case, the electronic detonator 1, 2, ..., N is fired in the firing step E7, once the delay time associated therewith has elapsed .

In the case shown in the figure 4b , the voltage across the terminals of the shot capacitor 102 decreases very rapidly so that at an instant t _3A , this voltage reaches the second predetermined voltage V _T corresponding to the shot capacitor 102.

It is then at this instant t _3A that the electronic detonator 1, 2, ..., N is fired in advance, that is to say before the delay time has elapsed (instant t ₃ ).

In the case shown in figure 4c , the voltage at one terminal of the supply capacitor 101 decreases very quickly so that it reaches the first predetermined voltage V _A before the delay time associated with the electronic detonator has elapsed (instant t ₃ ).

The electronic detonator 1, 2, ..., N is thus ignited at this instant t _3A in advance, that is to say before the associated delay time has elapsed (instant t ₃ ).

Claims (9)

1. Method for firing an electronic detonator (1, 2,..., N) comprising energy storage means (100), the method comprising reception (E2) by the electronic detonator of a firing order, said method being characterized in that it comprises the following steps that are implemented as long as a delay time associated with the electronic detonator (1, 2,..., N) has not elapsed since said reception (E2) of the firing order:

   - measuring (E3) a stored energy in said energy storage means (100),

   - when the measured stored energy is less than or equal to a predetermined energy, determining (E8) the time difference existing between a period of time that has elapsed since reception of the firing order and said delay time associated with said electronic detonator (1, 2,..., N), and

   - firing (E7) said electronic detonator (1, 2,..., N) when said time difference is less than a predetermined time value.
2. Firing method according to claim 1, characterized in that said predetermined energy corresponds to a minimum energy necessary for supplying and for firing said electronic detonator (1, 2,..., N).
3. Firing method according to one of claims 1 or 2, characterized in that it further comprises a step of comparing the measured stored energy to said predetermined energy.
4. Firing method according to claim 3, characterized in that said step of measuring the stored energy comprises a step (E3) of measuring a voltage at the terminals of the energy storage means, and said comparison step comprises a step (E4) of comparing said measured voltage with a predetermined voltage (V_A, V_T) representative of said predetermined energy.
5. Electronic detonator comprising energy storage means (100) and means for receiving a firing order (200, 201), said electronic detonator (1, 2,..., N) being characterized in that it further comprises:

   - means for measuring (200, 202, 203) a stored energy in said energy storage means (100),

   - means for determining the time difference existing between a period of time that has elapsed since reception of the firing order and said delay time associated with said electronic detonator (1, 2,..., N), said time difference being determined when the stored energy measured by the measuring means is less than or equal to a predetermined energy, and

   - means for firing (200, 201) configured for implementing the firing of said electronic detonator (1, 2,..., N) before a delay time associated with said electronic detonator (1, 2,..., N) has elapsed, when said time difference determined by the determining means is less than a predetermined time value.
6. Electronic detonator according to claim 5, characterized in that it comprises means for comparing (200, 201) the stored energy measured by the measuring means (200, 202, 203) with said predetermined energy.
7. Electronic detonator according to claim 6, characterized in that said means for measuring (200, 202, 203) the energy stored in said energy storage means (100) comprises means for measuring the voltage (200, 202, 203) at the terminals of said energy storage means (100), and said comparison means (200, 201) comprises means (200, 201) for comparing a voltage measured by said measuring means with a predetermined voltage (V_A, V_T) representative of the predetermined energy.
8. Electronic detonator according to one of claims 5 to 7, characterized in that said energy storage means (100) comprises a capacitor (101, 102).
9. Detonation system comprising a set of electronic detonators (1, 2, ..., N) according to one of claims 5 to 8 and implementing the firing method according to one of claims 1 to 4.

Images