JPH04124599A - Ejection method and device for ejection type electronic device - Google Patents

Abstract

PURPOSE:To eliminate a complicated timing circuit for controlling the starting of a thermal battery, the transmission of information, the ignition of a charge module and the like, by a method wherein a necessary information signal is sent out by an ejection control device to the internal circuit of an ejection type electronic device before a time until the charge of an ejector is exploded after sending a starting signal. CONSTITUTION:An ejection control device 1 sends information signals such as a radio wave ejecting condition and the like to an ejection type electronic device 9 immediately after sending the starting signal of a thermal battery successively. These information signals are received by the ejection type electronic device 9 and are stored in a memory circuit 7. Power is supplied from the thermal battery 6, which is in the condition of rising up, to the memory circuit 7. The electromotive force of the thermal battery 6 is given to a charge module 5 as an igniting signal as it is. Accordingly, when the electromotive force of the thermal battery 6 is risen up sufficiently, the filament of a charge module 5 is heated to cause ignition and explosion whereby the ejection type electronic device 9 is ejected out of a mother machine. Accordingly, the ejection control device 1 unnecessitates the timing circuit 3.

Description

[Detailed Description of the Invention] [Summary] An injection method for an injection-type electronic device that is injected from an aircraft or the like and emits radio waves while in flight after injection, and a special timing circuit for the injection device used to carry out the injection method. An injection-type electronic device whose internal battery is a thermal battery loaded into the injector is used to explode the gunpowder loaded into the injector, with the aim of performing a rational injection process in a short time without using An injection method for an injection type electronic device in which an injection control device gives a starting signal to the injection type electronic device to start its thermal battery, and the electromotive force of the thermal battery activated by the starting signal is used. The gunpowder in the injector is ignited by giving an ignition signal.

[Field of Industrial Application] The present invention relates to an injection method for an injection-type electronic device that is ejected from an aircraft or the like and emits radio waves while in flight after injection, and an injection device used to carry out the injection method.

Such injection-type electronic devices are used, for example, to send out marker radio waves after injection.

[Prior art 1] Conventionally, such an injection device is known to load a projectile into an injector and eject the gunpowder contained in the injector out of the device by exploding it in response to an ignition signal from a control device. It is being

On the other hand, when the injection target is, for example, an electronic device that emits marker radio waves in the microwave band, an internal power source with a large electromotive force is required, and a thermal battery is generally used. Furthermore, when emitting such radio waves, it is necessary to initialize various information such as the speed and altitude of the mother machine in the injection type electronic device when the radio waves are emitted from the mother machine.

An example of a device that performs injection control while setting various information in the injection mold electronic device during injection is as shown in FIG. 4, for example.

In FIG. 4, 9° is an injection type electronic device, which includes a thermal battery 6 serving as an internal power source, a storage section 7 for storing information signals, an electronic circuit 8 for transmitting radio waves, etc. This thermal battery 6 is a thermal battery with an ignition filament, and is ignited by receiving a starting signal on the ignition filament. After ignition, electric energy is generated by an internal chemical reaction.

Reference numeral 4 denotes an injector, in which an injection type electronic device 9° is loaded, and a gunpowder module 5 with an injection filament for injecting this injection type electronic device is also loaded, and this gunpowder module 5 sends an ignition signal to the filament. When exposed to the air, it ignites and causes an explosion, and the explosive force causes the injection-type electronic device 9 to explode.
It is designed to eject ゛ outside the vessel.

lo is an injection control device, which includes a control section 2 and a timing circuit 3. The activation signal for the thermal battery 6 and the information signal to be set in the internal circuit are sent from the control unit 2 to the injection type electronic device 9 through separate signal lines through the injector 4. ing. Further, the timing circuit 3 sends an ignition signal to the explosive module of the injector 4.

In this injection device, first, an activation signal is sent from the injection control device 1 to the thermal battery 6 at 9 degrees of the injection type electronic device, whereby the filament of the thermal battery 6 is ignited and the thermal battery 6 starts operating. do. After this ignition, the internal circuit of the injection type electronic device 9° is activated by the electromotive force generated by the thermal battery 6.

Next, the injection control device 1' sends out a necessary information signal 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 section 7.

Further, the injection control device I° sends an ignition signal to the gunpowder 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 gunpowder module 5 is ignited and explodes, ejecting 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 to control the timing of starting the thermal battery, transmitting information, and igniting the explosive module, which is uneconomical.

Furthermore, if the timing control is not successful, an erroneous firing may occur, such as the explosive module exploding and ejecting the ejection type electronic device outside the device, for example, before the information transfer is completed. In addition, in order to prevent such erroneous firing, it is necessary to set the timing with some allowance for the startup of the thermal battery and the completion of information transfer, so the time required for firing the injection-type electronic device becomes longer overall. .

The present invention has been made in view of the above circumstances, and its purpose is to enable rational injection processing to be performed in a short time without using a special timing circuit. Another object of the present invention is to prevent erroneous firing, such as the injection type electronic device being ejected before information is transferred.

[Means to solve the problem] FIG. 1 is a diagram explaining the principle of the present invention.

The injection method for an injection-type electronic device according to the present invention includes an injection-type electronic device 22 that uses a thermal battery 24 loaded in an injector 20 as an internal power source, and a gunpowder 26 loaded in the injector 20 that explodes. An injection method in which injection is performed by causing
The injection control device 23 gives the injection type electronic device 22 a starting signal to start its thermal battery 24, and the electromotive force of the thermal battery 24 activated by this starting signal is used to ignite the gunpowder 26 of the injector 20. It is designed to fire by giving a signal.

Further, in the injection method for an injection type electronic device according to the present invention, as another form, in the above-mentioned injection method, the injection control device 23
After the activation signal is sent, necessary information signals are sent to the internal circuit 25 of the injection type electronic device 22 until the gunpowder 26 of the injector 20 explodes.

Further, in another embodiment of the injection method for an injection type electronic device according to the present invention, in the above-described injection method, the injection type electronic device 22 is provided with a switch 27 that cuts off the ignition signal applied to the gunpowder 26 of the injector 2o. After the internal circuit completes receiving the information signal from the injection control device 23, the switch 27
is turned on to send an ignition signal to the injector 2o.

Further, in one embodiment of the injection device for the injection type electronic device according to the present invention, the internal circuit 25 uses the thermal battery 24 as an internal power source.
an injection-type electronic device 22 that drives the injection-type electronic device 22;
an injector 20 loaded with the injection type electronic device 22 and injecting the injection type electronic device 22 by exploding the gunpowder 26;
The injection type electronic device 2
2 is configured to send an ignition signal to the injector 20 based on the electromotive force of the thermal battery 24 after the thermal battery 24 is activated by the activation signal.

Moreover, in the injection device of the injection type electronic device of the present invention, in the above-mentioned injection device, the injection control device 23 is
A device configured to send a necessary information signal to the internal circuit 25 of the injection type electronic device 22 after the activation signal of the thermal battery 24 is sent and until the explosive 26 of the injector 20 explodes. It is.

Furthermore, in the injection device of the injection type electronic device according to the present invention, in still another form, in the injection device described above, the injection type electronic device 22 includes a switch 27 that cuts off the transmission of the firing signal to the injector 20, and A reception completion determination unit 28 determines whether the reception of the information signal from the control device 23 is complete, and transmits the ignition signal to the injector 20 until the reception completion determination unit 28 determines that the reception of the information signal is complete. This is configured to be prohibited by a switch 27.

[Effect 1] First, a start signal is sent from the injection control device 23 to the thermal battery 24 of the injection mold electronic device 22, whereby the thermal battery 24 is ignited and an electromotive force is generated. The electromotive force of the thermal battery 24 ignites the gunpowder 26 in the injector 20 to cause an explosion, thereby ejecting the injection type electronic device 22 from the injector 20.

In another embodiment of the present invention, an information signal is sent from the injection control device 23 to the internal circuit 25 of the injection mold electronic device 22 between the sending of the activation signal and the explosion of the gunpowder 26. After injection, the device 22 performs necessary operations based on this information signal.

Furthermore, in another embodiment of the present invention, the switch 27 is opened to prevent the ignition signal from being sent to the gunpowder 26 of the injector 20 before the reception of the information signal is completed. After the reception completion determination section 28 determines that the reception is complete, the switch 27 is closed to send out an ignition signal, and the gunpowder 26 is ignited and exploded. This can prevent erroneous firing of the injection type electronic device 22 before the information transfer is completed.

[Example] Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 2 shows an injection device for an injection type electronic device as an embodiment of the present invention. This embodiment device is mounted on an aircraft and injects an injection type electronic device into the air.
The ejected injection-type electronic device emits, for example, a radio wave for a sign while falling through the air.

In the figure, l is an injection control device, which includes a control section 2 that controls the information processing sequence of the entire system. Reference numeral 4 denotes an injector that injects the loaded injection type electronic device 9 using the explosive force of the gunpowder module 5.

Reference numeral 9 denotes an injection type electronic device, which includes a thermal battery 6 as an internal power source, a storage section 7, and an electronic circuit 8.

The difference between this embodiment device and the device shown in FIG. 4 is that the injection control device 1 does not have a timing circuit 3, and the injection control device 1 does not have a timing circuit 3, and a starting signal is sent to the thermal battery 6 of the injection type electronic device 9. The gunpowder module 5 of the injector 4
The signal line that provides the firing signal has been removed.

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

The operation of this embodiment device will be explained below.

First, the injection control device l sends an activation signal to the injection type electronic device 9 to activate its thermal battery 6. In response to this activation signal, the filament of the thermal battery 6 is heated and ignited, and the heat generated causes a chemical reaction to generate an electromotive force, which is supplied to the internal circuit. This electromotive force takes a certain amount of time to rise, and therefore it takes a certain amount of time to generate enough electromotive force to drive a microwave transmitter etc. that requires a large amount of power. The electromotive force for driving can be obtained from the thermal battery 6 early after ignition.

Immediately after sending out the activation signal for the thermal battery, the injection control device 1 sends information signals such as radio wave emission conditions to the injection type electronic device 9. These information signals are received by the injection mold electronic device 9 and stored in its storage circuit 7. This memory circuit 7 is supplied with power by the thermal battery 6 which is starting up, but as described above, it operates with weak electric power, so even if the electromotive force of the thermal battery 6 is small, there is no problem in operation.

Further, the electromotive force of the thermal battery 6 is directly applied to the explosive module 5 as an ignition signal. Therefore, this thermal battery 6
When the electromotive force increases sufficiently, the filament of the gunpowder module 5 is heated, ignition and explosion occur, and the injection type electronic device 9 is ejected from the base machine.

It takes 10 to 20 m for ignition and explosion of this gunpowder module 5.
It takes a relatively long time of 5 ec, and on the other hand, the time required to transfer the information signal is on the order of microseconds, so the transfer of the information signal to the injection-type electronic device 9 is sufficiently completed before the injection due to the explosion. are doing.

According to the above injection process sequence, the thermal battery 6 of the injection type electronic device 9 generates sufficient electromotive force immediately after injection, so the internal electronic circuit 8 is activated immediately after injection. can emit radio waves.

Various modifications are possible in implementing the invention. FIG. 3 shows an injection device for an injection type electronic device as such a modified example. This modified example device is different from the above-described example 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 the thermal battery 6 From the gunpowder module 5 of the injector 4
A switch 11 that can cut off the firing signal is provided between the signal lines that send out the firing signal, and this switch 11 can be controlled on/off by the reception completion determination signal from the reception completion determination section 10. It is that you are.

Here, the reception completion determining section 10 is capable of determining the completion of reception of the received information signal based on an end indicator included in the information signal. Also switch 11
is in an OFF (open) state when the reception completion determination section II+ is not determined to be reception completion, and is in an ON (closed) state when it is determined that reception is complete.

When configured like this modified example device, the injection type electronic device 9
After completely receiving the information signal from the injection control device 1, the switch 11 is closed and the ignition signal from the thermal battery 6 is given to the explosive module 5 of the injector 4. Misfires such as the device 9 being ejected can be reliably prevented.

[Advantageous Effects of the Invention 1] As explained above, according to the present invention, there is no need for a complicated timing circuit for controlling the timing of starting the thermal battery, information transfer, ignition of the explosive module, etc., resulting in an economical system. In addition, the injection control sequence can be extremely simplified. In addition, since the gunpowder module is ignited by the electromotive force of the thermal battery in a rational sequence, the electromotive force of the thermal battery after injection is large enough, and therefore the injection-type electronic device emits radio waves immediately after injection. You can perform various necessary tasks such as:

Furthermore, compared to control using a timing circuit, there is no extra waiting time for timing adjustment, so the time required for injection processing can be shortened. Furthermore, by prohibiting the sending of an ignition signal to the gunpowder module by the switch until information reception is completed, it is possible to reliably prevent the injection type electronic device from being erroneously fired before the information transfer is completed.

[Brief explanation of the drawing]

FIG. 1 is a diagram illustrating the principle of the present invention; FIG. 2 is a block diagram showing an injection device of an injection type electronic device as an 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 device for an injection type electronic device. In the figure, 1... Injection control device 2... Control section 3... Timing circuit 4... Injector 5... Explosive module 6... Thermal battery 7... Storage section 8... Electronic circuit 9...Injection-type electronic device io-...Reception completion determination unit]1--Invented by switch A. Yes or no? , door f-teron-E3 pa shi3 condolence

Claims (1)

[Claims] 1. An injection type electronic device (22) loaded in the injector (20) and using a thermal battery (24) as an internal power source,
) is an injection method for an injection type electronic device in which the gunpowder (26) loaded in the injection type electronic device (22) is injected by exploding the gunpowder (26) loaded in the injection type electronic device (22). ), and an ignition signal generated by the electromotive force of a thermal battery (24) activated by the activation signal is applied to the gunpowder in the injector (20) to cause ignition. Injection method. 2. After the injection control device (23) sends the activation signal, until the gunpowder (26) in the injector (20) explodes,
2. The injection method for an injection mold electronic device according to claim 1, wherein a necessary information signal is sent to an internal circuit (25) of the injection mold electronic device (22). 3. The injection electronic device (22) includes a switch (27) that cuts off the ignition signal applied to the gunpowder of the injector (20), and the internal circuit (25) receives information signals from the injection control device (23). 3. The method for injecting an injection type electronic device according to claim 2, wherein the switch (27) is turned on to send the ignition signal to the injector (20) after completion of reception of the ignition signal. 4. Internal circuit (25) using thermal battery (24) as internal power source
an injection type electronic device (22) for driving the injection type electronic device (22); , the thermal battery (24) for the injection type electronic device (22)
An injection control device (2) that sends out a start signal to start the
3), the injection type electronic device (22) activates the thermal battery (22) in response to the activation signal.
24) is configured to send an ignition signal to the injector (20) by the electromotive force of the thermal battery (24) after the thermoelectric battery (24) is activated. 5. The injection control device (23) sends the activation signal for the thermal battery (24), and then fires the gunpowder (26) in the injector (20).
5. The injection-type electronic device injection device according to claim 4, wherein the injection-type electronic device injection device is configured to send necessary information signals to the internal circuit (25) of the injection-type electronic device (22) until the injection-type electronic device (22) explodes. 6. The injection type electronic device (22) determines the completion of reception of the information signal from the switch (27) that cuts off the sending of the ignition signal to the injector (20) and the injection control device (23). a reception completion determination section (28), and the injector (20
) until the reception completion determination section (28) determines that the reception of the information signal is complete.
7) The injection-type electronic device injection device according to claim 5, configured to prohibit the injection according to the above.