DE3942842A1 - ELECTRONIC REAL-TIME DELAY IGNITION - Google Patents

Abstract

An electronic real-time time fuse with high-precision timing, a broad spectrum of time stages and of a size comparable with that of conventional non-electric fuses, has a delay mechanism comprising a time-comparison element (6, 18, 19) in which the target time specific to the fuse can be set by means of a programmable semiconductor memory (19). In a preferred embodiment, the fuse is manufactured by low-voltage MOS technology with a PROM or an EEPROM as the semiconductor memory (19), and the fuse can also be programmed on site.

Description

The invention is directed to an electronic blasting time igniter with a signal input stage, a control section, one Delay device, a charging capacitor and an ignition pill, as well as the use of the detonator in one Ignition system in which the detonators are connected in series or in parallel with one Control unit can be connected.

When it comes to civilian blasting technology, it is crucial that that individual loads in a certain, tightly timed set order to be ignited. researches show clearly that for optimal blasting results both in terms of the shocks as well as the crushing of the rock a very precise time delay of the individual ignitions is required.

The required high precision is achieved by an electronic Control with central triggering from a control unit and detonator-specific delays achieved. The electrical Energy for the electronics and the ignitions must come from the igniter be removable, because the electrical connection of the Igniter on the control unit could occur during the time sequence Detonations are interrupted, causing the detonators to then go off Lack of energy would fail.

Batteries in detonators are, among other things, for safety reasons undesirable. The energy store is usually one Zünders a capacitor from the central control unit in front the ignition needs to be charged. As long as the capacitor is not charged, there is no energy level through which one Ignition could be triggered.

It is disadvantageous that during the time delay of the emergency agile electricity for the electronics taken from the capacitor  must become. The capacitor must be used for long delay times have a high storage capacity so that after the Delay time enough energy left for ignition remains.

A delay detonator circuit is in the US 44 45 435. With five microswitches one can Delay time can be selected. Although only a few Time specifications are possible is the diameter of such Delay detonator more than twice the size of conventional detonators.

With a programmable electronic detonator According to EP 01 42 509 B1, the values of the delays time entered on a control panel. The facility is designed for one floor only. An installation of one Control panel in an igniter with a diameter under one Centimeters is not possible.

EP 01 83 933 A2 encodes the time stages about the bonding of a chip which is on the control part integrated with the delay device. Such a detonator can be relatively slim in one Housing can be accommodated. The disadvantage is that the coding cannot be changed after mounting the chip is.

The object of the invention is an electronic real-time delay detonating detonator, one with the greatest possible variety of times has the smallest possible dimension so that it fits into a conventional Igniter sleeve (outside diameter less than 10 mm) fits; either relative, d. H. with regard to the adjustability of the ignition times among themselves, as well as absolutely, the time accuracy should be very be high.  

The task is solved by a delay detonator, the is characterized in that the delay device Has time comparator and the target time by means of a Semiconductor memory can be predefined in a fuse-specific manner.

A programmable semiconductor memory is preferred (PROM) and the design of the circuits including the Memory in MOS technology and a tuning fork quartz as frequency normal in the timer.

The MOS technology is for electronic circuits of detonators known. In DE PS 21 04 422 metal oxide silicon field effect transistors as threshold switches for ignition elements used. The execution of the Ignition element according to the invention in low-voltage MOS technology, where the electronics already with operating voltages around or below 2 Volt works. The electronic circuit has a very low energy consumption.

The invention also relates to the use of the igniter in an ignition system in which the detonators are connected in series or in parallel a control unit can be connected, from which all interconnected igniter can be started by a signal sequence are and each detonator is then autonomous, d. H. just through Energy consumption from the igniter-specific charging capacitor after a igniter-specific delay time, the Discharge of the charging capacitor ignites the squib.

The delay detonator according to the invention combines in ideally properties with a size that so far never in a conventional igniter housing, i.e. H. one Cylinder of about 7 mm outer diameter, was to be realized. There can be detonators with delay times in the Form order of magnitude from 1 ms to 8000 ms, with the grad can be in the range of 250 µs and the largest possible errors are in the range of 20 ppm. Delay explosion  igniter with this variety of times and with this accuracy are so far unknown. The delay detonators can be operate with supply voltages around or below 2 volts. they can be with all known security and Combine control devices in the detonator.

Semiconductor memories are from computer technology in many Variants known; for the detonator according to the invention is a programmable semiconductor memory (PROM) prefers. A PROM based is very particularly preferred of field effect transistors because such a memory is composed can easily be integrated on a chip using MOS logic.

The memory contains a single address. With a data word lengths of 18 bits can be 262 144 different delay times can be set. The area that such a memory is on of the chip area is not taken into account Weight. This eliminates all switches and bonds.

To reduce the number of programming connections to the Keeping detonators as small as possible is a serial program Storage preferred, i. H. the desired date is read in via a shift register, in the memory program lubricated and then read out again to ensure safe closing go that the programmed value is contained in the memory.

In most cases, the delay time setting in the manufacture of the detonator and not in the Electronics manufacturer. However, it is conceivable and at that detonator according to the invention possible that the choice of special Delay times in the detonator defined by the user on site becomes. All you have to do is connect the cables to the detonator Programming device be brought out so that on site the target time in a suitable programming device Semiconductor memory can be entered.  

In known electronic delay detonators that is Time standard defined by RC elements. According to one before partial timed training shows the timing element as a frequency normally a tuning fork quartz. He is very small and can go with him low voltage work and is inexpensive.

The advantages of a detonator according to the invention become special in cooperation with several detonators when blasting clearly, with the temporal precision and security the key criteria are.

The invention is illustrated by way of example in the drawing and further explained below. Show it:

Figure 1 is a block diagram of an electronic real time delay detonator with analog and digital part.

Fig. 2 data log when reading and programming the memory;

Fig. 3 is an operating diagram.

Fig. 1 shows an embodiment of an igniter in the block diagram. The circuit consists of two main groups, an analog part 1 and a digital part 2nd A limiter 3 in the analog part 1 is used for safety; it is intended to reduce overvoltages at signal input 4 so that the function of the subsequent circuit is not impaired. A signal decoupling 5 filters out the pulses for a central control unit 6 (CPU) from the input signal and adjusts the level to a low-voltage MOS logic. A rectifier 7 feeds a voltage regulator 8 and this in turn supplies a capacitor 9 . The voltage regulator 8 is designed as a two-stage voltage regulator so that a no-fire energy level and an all-fire energy level can be set on the capacitor 9 . To set the all-fire energy level, the controller 8 needs an unlocking signal 10 from the central control unit 6 , which is only set if a corresponding unlocking code is received via the input 4 and the signal output 5 on the central control unit 6 and is recognized as correct . Otherwise, the no-fire energy level at capacitor 9 is always set. In addition, the voltage regulator supplies a RESET signal 11, which establishes a basic state in the logic during commissioning.

By operating a circuit breaker 12 , the charge flows out of the capacitor 9 through a squib 13 as soon as an ignition signal 14 is set. Ignition can only take place if the all-fire energy level on the capacitor 9 is set. A voltage regulator 15 regulates the fixed voltage for the low-voltage MOS logic.

In the digital part 2 , a crystal 16 together with a driver and divider 17 supplies a clock sequence to the central control unit 6 . An up counter 18 can be started by the central control unit 6 and set to zero. In the programmable semiconductor memory 19 , the counter reading is stored, in which an ignition signal 14 is set by the central control unit 6 if the counter reading from the counter 18 coincides therewith.

Data is exchanged with the programmable semiconductor memory 19 via a data interface 20 . Depending on the data protocol, the programmable semiconductor memory 19 can be read or programmed.

FIG. 2 shows an example of a data protocol "read" (above) and "programming" (below) which is coordinated with the system according to FIG. 1. In connection with a line 21 (clock), all data is clocked in via a serial data line 22 . The serial data line 22 works bidirectionally, ie it can both receive and send (tri-state). In Fig. 2a and 2b, the signal sequence in reading and programming is in each case shown with the reference numerals 21 and 22 indicate which line of FIG. 1 run the pulses.

At the beginning of each communication, a start condition 23 must be fulfilled, specifically this means that a low level must be supplied in line 22 and an edge from high to low in line 21 . After this start signal, an identifier 24 must be clocked in; In the example shown, the identifier is 10101 as a bit sequence. One bit is clocked in with each high state of the clock line 21 . The seventh bit decides whether the memory 19 should be programmed or read. If bit 25 is high, this means reading, if bit is low, it means writing. After the successful transmission of the identifier 24 and the read and write bit 25 , the memory 19 responds with an acknowledgment bit 26 , state low (QUIT). A counted amount of data bits 27 can then be clocked in.

If the counted amount of data bits 27 is reached, the memory 19 reacts with a quit; With the following stop condition 28 (line 22 low and 21 change from low to high) the communication is completed.

It is possible at any time to read and check the contents of the memory 19 as long as the corresponding connections are accessible. Of course, the memory can also be designed as an electronically readable memory (EEPROM). In this case, the stored content of the PROM could be changed at any time via lines 21 and 22 , as long as the lines are accessible. Examples of the organization of such EEPROMs are given in the data sheets from XICOR or Eurosil.

Curve 30 in FIG. 3 shows the typical voltage curve at input 4 of an igniter according to the invention. A DC voltage is initially present (section 31 ), the polarity being arbitrary. Curve 32 shows the course of the voltage at energy store 9 . The dashed line 33 represents a no-fire level of the ignition means. In principle, the voltage of the capacitor 9 is set to a voltage below the no-fire level by the voltage regulator 8 during commissioning (section 31 ). Only after successful Ent fuse in section 34 , the capacitor 9 is charged to the full voltage 35 .

An unlocking signal consists of four signals with a defined time sequence. The signal decoupling 5 is designed such that a change in current or voltage when the polarity (sign 34 ) changes sign is evaluated as a pulse. The circuit is constructed in such a way that unlocking is successful when the first and second voltage changes take place within a certain time t ₁ and the time between the second and fourth changes is also just as long. The time t ₁ is evaluated via counter readings 36 of the counter 18 . The energy storage 9 is charged in the time segment 38 .

The charging process of the capacitor 9 is triggered after successful unlocking with the logic signal 10 on the voltage regulator 8 . The ignition command is given in section 39 . It consists of four voltage changes in a regular time sequence. After the fourth change 40 , the counter 18 is started. It counts up until the preprogrammed count 41 of the PROM 19 is reached. At this time 42 , the capacitor 9 , triggered by a signal 14 , is short-circuited via the ignition pill 13 . The voltage 32 at the energy store 9 drops to zero.

Two further voltage changes 43 are shown in the voltage curve 30 at the input 4 after the four voltage changes of the ignition command 39 . They serve as security in the event that the signal transmission is disturbed in a voltage change. The logic is designed such that all detonators start their counters 18 together with the receipt of the ignition command. The time-delayed ignition then takes place individually according to the preprogrammed meter reading in the PROM 19 .

Claims (9)

1. Electronic detonator with a signal input stage ( 3 , 5 ), a control part ( 6 ), a delay device, a charging capacitor ( 9 ) and a squib ( 13 ), characterized in that the delay device has a time comparator and the target time by means of a semiconductor memory ( 19 ) igniter can be specified specifically. 2. detonator according to claim 1, characterized in that the circuits including the memories in MOS Technology. 3. detonator according to claim 2, characterized in that the circuits including the memories in low- Voltage MOS technology are implemented. 4. detonator according to one of claims 1 to 3, characterized in that the semiconductor memory is designed as a one-time programmable memory (PROM) ( 19 ). 5. detonator according to claim 4, characterized in that the one-time programmable memory ( 19 ) via a data ( 22 ) and a clock line ( 21 ) is programmable. 6. detonator according to one of claims 1 to 5, characterized in that the memory ( 19 ) is integrated in a chip which contains the other control functions. 7. detonator according to one of claims 1 to 6, characterized in that a signal input is present on the igniter housing, via which the semiconductor memory ( 19 ) is programmable on site. 8. detonator according to one of claims 1 to 7, characterized in that the timing element has a tuning fork quartz ( 16 ) as the frequency standard. 9. Use of detonators according to one or more of the Claims 1 to 8 in an ignition system in which the igniter Can be connected in series or parallel to a control unit are from which all interconnected igniters through a signal sequence can be started and then each detonator automon, d. H. only through energy consumption from the igniter's own charging capacitor after a ignition-specific delay time the discharge of the Charging capacitor ignites the squib.