JP2595374B2 - Injection method and injection device for injection-type electronic device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Summary] A special timing circuit relates to an injection method of an injection-type electronic device that emits a radio wave or the like during a flight after being emitted from an aircraft or the like and an injection device used for implementing the emission method. The purpose is to perform reasonable injection processing in a short period of time without using a heat source, and to use the thermal battery loaded in the injector as the internal power source ...
A required information signal is transmitted to an internal circuit of the injection-type electronic device. "A method for injecting an injection-type electronic device, which is loaded into an injector and uses a thermal battery as an internal power source, to explode an explosive for injection, thereby injecting the injection-type electronic device. A start signal for activating the thermal battery is provided from an externally provided injection control device to the injection type electronic device, and the electromotive force of the thermal battery activated by the start signal is supplied to the injection powder as an ignition signal. After the firing control is performed, the injection control device sends an activation signal to the internal circuit of the injection-type electronic device before the explosive explosive explodes. Is transmitted.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an injection method for an injection-type electronic device that emits radio waves during flight after being emitted from an aircraft or the like, and an injection device used for implementing the emission method.

Such an injection-type electronic device is used for applications such as transmitting a radio wave for a sign after the emission.

2. Description of the Related Art Conventionally, as such an injection device, there is known an injection device in which an ejected material is loaded into an injector, and the explosive charged in the injector is exploded by an ignition signal from a control device, and is ejected outside the device. Have been.

On the other hand, for example, when an electronic device that emits a radio wave for a sign in a microwave band is used as an emission target, a device having a large electromotive force is required as an internal power supply, and a thermal battery is generally used. In the case of radiating such radio waves, it is necessary to initialize various information such as the speed and altitude of the base unit in the injection-type electronic device when the base station is emitted from the base unit.

As an apparatus for performing injection control while setting various types of information in the injection-type electronic device at the time of injection as described above, for example, the apparatus shown in FIG. 4 can be considered.

In FIG. 4, reference numeral 9 'denotes an injection-type electronic device, which includes a thermal battery 6 serving as an internal power supply, a storage unit 7 for storing information signals, an electronic circuit 8 for transmitting radio waves, and the like. The thermal battery 6 is a thermal battery with an ignition filament, is ignited by receiving a start signal to the ignition filament, and generates electric energy by an internal chemical reaction after the ignition.

Reference numeral 4 denotes an injector, which is loaded with an injection-type electronic device 9 '.
Further, an explosive module 5 with an injection filament for ejecting the injection-type electronic device is mounted. The explosive module 5 is ignited by receiving an ignition signal to the filament and causes an explosion. The electronic device 9 'is emitted outside the device.

An injection control device 1 'includes a control unit 2 and a timing circuit 3. Injector 4 'from control unit 2
, The start signal of the thermal battery 6 and the information signal to be set in the internal circuit are sent to the injection-type electronic device 9 'via separate signal lines. An ignition signal is sent from the timing circuit 3 to the explosive module of the injector 4.

In this injection device, first, a start signal is sent from the injection control device 1 'to the thermal battery 6 of the injection-type electronic device 9', whereby the filament of the thermal battery 6 is ignited and the thermal battery 6 starts operating. I do. After this ignition, the internal circuit of the injection type electronic device 9 'is operated by the electromotive force generated by the thermal battery 6.

Next, the injection control device 1 'sends necessary information signals to the injection-type electronic device 9' at the timing when the thermal battery 6 has sufficiently started up. The injection-type electronic device 9 ′ receives this information signal and stores it in the storage unit 7.

Further, the injection control device 1 'sends an ignition signal to the explosive module 5 of the injector 4' at the timing when the transmitted information signal is received by the injection-type electronic device 9 '. As a result, the explosive module 5 is ignited and explodes, and ejects the injection-type electronic device 9 'out of the device.

The above timing control is performed by the timing circuit 3 of the injection control device 1 '.

[Problems to be Solved by the Invention] The above-described injection device requires a special timing circuit for performing timing control of activation of the thermal battery, information transfer, and ignition of the explosive module, which is uneconomical.

Further, if the timing control is not performed properly, for example, an erroneous firing may occur in which the explosive module explodes before the information transfer is completed and the injection type electronic device is ejected outside the device. Further, in order to prevent such erroneous firing, it is necessary to set the timing of the rise of the thermal battery and the completion of information transfer with some allowance, so that the time required for firing of the injection-type electronic device becomes longer as a whole.

The present invention has been made in view of such circumstances, and an object of the present invention is to enable a reasonable injection process in a short time without using a special timing circuit. Another object of the present invention is to prevent erroneous firing such that an injection-type electronic device is fired before information transfer.

[Means for Solving the Problems] FIG. 1 is an explanatory view of the principle according to the present invention.

The injection method of the injection-type electronic device according to the present invention includes the injection device 20.
An injection method for an injection-type electronic device, in which the injection-type electronic device 22 having a thermal battery 24 as an internal power supply is injected by exploding an injection gunpowder 26, the injection method being performed outside the injection-type electronic device 22. From the injection control device 23 to the injection-type electronic device 22
The start signal for activating the thermal battery 24 is given to the fuel cell 24, and the electromotive force of the thermal battery 24 activated by the start signal is supplied to the injection powder 26 as an ignition signal to ignite, and the injection control device 23 After the start signal is transmitted and before the explosive explosive 26 explodes, an information signal necessary for the operation of the internal circuit 26 after the injection is transmitted to the internal circuit 25 of the injection-type electronic device 22. It was done.

According to another aspect of the present invention, there is provided an injection method for an injection-type electronic device.
23 includes a switch 27 for interrupting an ignition signal given to an explosive for injection 26. After the internal circuit 25 has completed receiving an information signal from the injection control device 23, the switch 27 is turned on to output the ignition signal to the explosive for injection. 26.

In one embodiment, the injection device of the injection type electronic device according to the present invention includes an injection type electronic device 22 that drives an internal circuit 25 using a thermal battery 24 as an internal power supply, and loads the injection type electronic device 22. A start signal for activating the thermal battery 24 is transmitted from the injection control device 23 provided outside the apparatus to the injection-type electronic device 22, and the electromotive force of the thermal battery 24 activated by the start signal is emitted as an ignition signal. The injection type electronic device is ejected from the injector 20 by detonating the explosive 26 for
After the injection control device 23 sends the start signal of the thermal battery 24 and before the injection powder 26 explodes, the injection type electronic device 22
The information signal necessary for the operation of the internal circuit 25 after the injection is transmitted to the internal circuit 25.

According to another aspect of the present invention, there is provided an injection-type electronic device according to the present invention.
22 includes a switch 27 for interrupting the transmission of the ignition signal to the explosive for injection 26, and a reception completion determining unit 28 for determining the completion of reception of the information signal from the injection control device 23,
The transmission of the ignition signal to 26 is prohibited by the switch 27 until the reception completion determination unit 28 determines that the reception of the information signal has been completed.

[Action]

First, from the injection control device 23 to the thermal battery 24 of the injection type electronic device 22
A start signal is sent to the battery, whereby the thermal battery 24 is ignited and the electromotive force rises. The electromotive force of the thermal battery 24 ignites the explosive 26 for firing, causing an explosion, and thereby ejecting the injection-type electronic device 22 from the injector 20. At this time, during the period from the transmission of the activation signal to the explosion of the explosive 26, the injection control device 23
Sends an information signal necessary for the operation of the internal circuit 25 after the injection to the internal circuit 25 of the injection-type electronic device 22, and the injection-type electronic device 22 performs the necessary operation based on the information signal after the injection .

Further, in another embodiment of the present invention, before the reception of the information signal is completed, the switch 27 is opened so that the ignition signal is not sent to the explosive for injection 26, and the completion of the reception of the information signal is determined. After the completion of the reception is determined by the determination unit 28, the switch 27 is closed and an ignition signal is transmitted to ignite and explode the explosive 26. As a result, the injection type electronic device before the information transfer is completed
22 misfires can be reliably prevented.

Embodiment An embodiment of the present invention will be described below with reference to the drawings.

FIG. 2 shows an injection device of an injection-type electronic device as one embodiment according to the present invention. The apparatus of this embodiment is mounted on an aircraft and ejects an injection-type electronic device into the air. The emitted injection-type electronic device emits, for example, radio waves for signs while falling in the air.

In the figure, reference numeral 1 denotes an injection control device, which has a built-in control unit 2 for controlling an information processing sequence of the entire system. Reference numeral 4 denotes an injector that ejects the filled injection-type electronic device 9 by the explosive force of the explosive module 5. Reference numeral 9 denotes an injection-type electronic device, which includes a thermal battery 6 as an internal power supply, a storage unit 7, and an electronic circuit 8.
Built-in.

This embodiment differs from the apparatus in FIG. 4 in that:
The injection control device 1 does not have the timing circuit 3 and is provided with a start signal to be given to the thermal battery 6 and a signal line for sending an information signal to be set in the storage unit 7 to the injection-type electronic device 9. Thus, the signal line for giving the ignition signal to the explosive module 5 of the injector 4 has been removed.

Instead, the electromotive force of the thermal battery 6 is supplied to the filament of the explosive module 5 from the injection-type electronic device 9 as an ignition signal to the explosive module 5 of the injector 4.

 Hereinafter, the operation of this embodiment will be described.

First, the injection control device 1 sends an activation signal to the injection-type electronic device 9 to activate the thermal battery 6. With this start signal, the filament of the thermal battery 6 is heated and ignited, and the generated heat causes a chemical reaction to generate an electromotive force, which is supplied to an internal circuit. This electromotive force takes a certain amount of time to rise, and it takes some time before an electromotive force sufficient to drive a microwave transmitter or the like that requires a large amount of power is generated. Can be obtained from the thermal battery 6 early after ignition.

Next, the injection control device 1 sends an information signal such as a radio wave emission condition to the injection type electronic device 9 immediately after the start signal of the thermal battery is transmitted. These information signals are received by the injection-type electronic device 9 and stored in the storage circuit 7 thereof. Although the storage circuit 7 is supplied with power by the rising thermal battery 6, it operates with weak power as described above, so that there is no problem in operation even when the electromotive force of the thermal battery 6 is small.

The electromotive force of the thermal battery 6 is directly supplied to the explosive module 5 as an ignition signal. Therefore, when the electromotive force of the thermal battery 6 is sufficiently increased, the filament of the explosive module 5 is heated, causing ignition and explosion, and the injection-type electronic device 9 is ejected from the mother machine.

The ignition and explosion of the explosive module 5 takes a relatively long time of 10 to 20 msec. On the other hand, the time required to transfer the information signal is on the order of microseconds. The transfer of the information signal to the device 9 has been sufficiently completed.

According to the above-described injection processing sequence, since the thermal battery 6 of the injection-type electronic device 9 has sufficiently generated electromotive force immediately after injection, the internal electronic circuit 8 is activated immediately after injection. To emit radio waves.

Various modifications are possible in implementing the present invention. FIG. 3 shows an injection device of an injection-type electronic device as such a modification. This modified device differs from the above-described embodiment device in that the information signal from the injection control device 1 is stored in the storage unit 7 via the reception completion determination unit 10 and that the thermal battery A switch 11 capable of cutting off the ignition signal is provided between the signal lines for transmitting the ignition signal to the explosive module 5 of the injector 4, and the switch 11 is turned on / off by the reception completion determination signal from the reception completion determination unit 10.
That is, it can be turned off.

Here, the reception completion determination unit 10 can determine the completion of the reception of the received information signal by using an end indicator included in the information signal. The switch 11 is turned off (open) when the reception is not determined to be completed by the reception completion determination unit, and is turned on (closed) when the reception is determined to be completed.

When configured as in this modified example, after completely receiving the information signal from the injection control device 1, the injection-type electronic device 9 closes the switch 11 and sends the ignition signal from the thermal battery 6 to the explosive module of the injector 4. Therefore, it is possible to reliably prevent erroneous emission such as ejection of the injection-type electronic device 9 before information transfer.

[Effects of the Invention] As described above, according to the present invention, a complicated timing circuit for controlling the timing of activation of a thermal battery, information transfer, ignition of an explosive module, and the like is not required, and the present invention is economical. Yes, and the injection control sequence can be greatly simplified. In addition, since the explosive module is ignited by the electromotive force of the thermal battery, the electromotive force of the thermal battery after injection is sufficiently large. For example, various necessary operations can be performed. Also, since there is no extra waiting time for timing adjustment as compared with the control by the timing circuit, the time required for the injection processing can be shortened. Further, by prohibiting the ignition signal transmission to the explosive module by the switch until the completion of the information reception, it is possible to reliably prevent the injection type electronic device from being erroneously fired before the completion of the information transfer.

[Brief description of the drawings]

FIG. 1 is a view for explaining the principle of the present invention, FIG. 2 is a block diagram showing an injection device of an injection-type electronic device as one embodiment of the present invention, FIG. 3 is a block diagram showing a modification of the present invention, FIG. 4 is a block diagram showing a configuration example of an injection-type electronic device injection device. In the figure, 1 ... Injection control device 2 ... Control unit 3 ... Timing circuit 4 ... Ejector 5 ... Explosive module 6 ... Heat battery 7 ... Storage unit 8 ... Electronic circuit 9 ... Ejection type electronics Device 10 ... Reception completion determination unit 11 ... Switch

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Sakuro Umene 1015 Ueodanaka, Nakahara-ku, Kawasaki City, Kanagawa Prefecture Inside Fujitsu Limited (56) References JP-A-63-122978 (JP, A) -103098 (JP, U)

Claims (4)

(57) [Claims] 1. An injection method for an injection-type electronic device, wherein the injection-type electronic device filled with an injection device and having a thermal battery as an internal power supply is injected by exploding an explosive for injection. An injection control device provided outside the electronic device gives a start signal to start the thermal battery to the injection-type electronic device, and the electromotive force of the thermal battery activated by the start signal is used as an ignition signal for the injection. The firing control device sends the firing signal to the internal circuit of the injection-type electronic device after the operation signal is transmitted and before the firing powder explodes. An injection method for an injection-type electronic device configured to transmit an information signal necessary for operation of the internal circuit. 2. The injection-type electronic device according to claim 1, further comprising a switch for interrupting an ignition signal applied to the explosive for injection, and turning on the switch after the internal circuit has completed receiving the information signal from the injection control device. 2. The injection method for an injection-type electronic device according to claim 1, wherein an ignition signal is sent to said injection gunpowder. 3. An injection type electronic device for driving an internal circuit using a thermal battery as an internal power source is loaded in an injector, and an injection control device provided outside the injection type electronic device controls the injection type electronic device. By transmitting an activation signal for activating the thermal battery and exploding an electromotive force of the thermal battery activated by the activation signal as an ignition signal into an explosive for injection, the injection-type electronic device is transmitted from the injector. The injection control device is configured to perform injection, and after the start-up signal of the thermal battery is transmitted and before the explosive for explosion explodes, the injection-type electronic device is injected into an internal circuit. An injection-type electronic device injection device for transmitting an information signal necessary for the operation of the internal circuit. 4. The injection-type electronic device includes a switch for interrupting the transmission of an ignition signal to the explosive for injection, and a reception completion determination unit for determining completion of reception of an information signal from the injection control device. The transmission of the ignition signal to the explosive for injection is repeated until the reception completion determination unit determines that the reception of the information signal is completed.
4. The injection type electronic device injection device according to claim 3, wherein the injection type electronic device is configured to be inhibited by the switch.