KR100417005B1 - Rocket Onboard Safety Device for 2nd or 3rd Stage Ignition - Google Patents

Abstract

The present invention relates to a two-stage or three-stage propulsion engine ignition safety device that is a propulsion engine that is ignited after stage separation of a rocket and a satellite projectile. After the first stage of combustion, the first stage is disconnected and the first stage is separated and after a few seconds of time delay, the second stage ignition is completed. If the two-stage or three-stage propulsion engine is not disconnected due to external causes (electromagnetic waves, etc.) or the failure of the internal flight sequence controller, it may ignite and block behind the nozzle of the rocket. Even if you don't explode, you can't predict the direction of your flight, and you're concerned about a type of safety device that prevents you from seriously affecting your safety. Will.

According to the present invention, the stage separation connector 3 is connected to each other using two pins at the stage separation surface 4, and the stage separation connector 3 is connected to the stage separation connector 3 when the stage separation is performed. Connector disconnecting line 5 which pulls out plug 1, Fixing line 6 of connector disconnecting line which fixes said connector disconnecting line 5 to a rocket end, and plug of connector 3 for disconnecting end Ignition command of the inertial navigation device inputted to the ground (8) connected to (1), the ignition device (9) connected to the socket (2) of the connector (3) for disconnecting the stage, and the input terminal of the ignition device (9). 10 and a sequence controller 11 for controlling the ignition command 10 of the inertial navigation apparatus.

The present invention does not ignite the second or third stage even when the ignition signal is input in the state that the separation is not separated, so before the rocket launch, assembling the rocket at the launch site and performing various tests, SAD (Safety and Safety) Arm Device) can be used as a redundancy device and can be used as a ignition safety device for two- and three-stage propulsion engines during rocket flight.

Description

Rocket Onboard Safety Device for 2nd or 3rd Stage Ignition}

The present invention relates to a two-stage or three-stage propulsion engine ignition safety device, which is a propulsion engine that is ignited after stage separation of rockets and satellite projectiles. After the first stage combustion ends, separate the first stage and have a time delay for a few seconds.After the second stage ignition by the ignition command by the control of the onboard sequence controller, after the second stage combustion ends, separate the second stage.3 However, the propulsion engine is ignited and the payload is put on the desired track.

At this time, the 2nd or 3rd stage ignition should be started after the 2nd or 3rd stage is separated. If the 2nd or 3rd stage is ignited without the stage separation, the nozzle part of the propulsion engine is clogged. The high pressure and high temperature flames may explode or cause the thrust to be distorted and fly in the wrong direction, which may seriously affect safety.

Normally, two-stage or three-stage separation and ignition are programmed to program the time in advance on the mounting computer so that the event can be performed unconditionally, and a specific sensor is installed on the stage separation surface to check whether the stage is disconnected. Can be classified in such a way as to allow ignition when performed.

The latter method has a disadvantage of having a separate stage separation sensor and a processing device capable of processing this signal, but the firing stability is much higher than that of the ignition unconditionally at a given time. .

It is estimated that a number of technologies have been accumulated and adopted in a highly reliable manner in the space-developed countries with many launch tests and failure experiences, but the rocket-related technologies are extremely unknown because they restrict the transfer of technology to other countries.

However, it is assumed that a separate sensor such as a displacement sensor is attached to the stage separation surface to check whether the stage is separated based on the output value of the sensor, and to ignite two or three stages. .

In this case, a space for attaching a separate sensor to a single separation surface, a bias power required for the sensor, hardware and software for processing the signal, and the like must be added, so that problems due to device failure are considered.

The present invention is connected to the ground of the rocket power on one side by using two pins in the existing pull-out connector that is a push pull type connector in which the connector is separated while the stage is separated. If not, devise an ignition safety device that will not ignite the second or third stage even if an ignition command is received, thus implementing a two- or three-stage ignition safety device that does not require a separate sensor and its associated hardware and software.

The present invention is very simple in configuration so that two pins are allocated from the existing end separation connector and are connected as shown in FIG. 1, and the plug of the end separation connector is connected to the ground and the socket of the end separation connector is connected. This is accomplished by connecting to a two stage ignition or three stage ignition (IG Box) input.

1 is a mounting view of the connector for disconnection of the present invention

2 is a circuit diagram of an ignition safety device of the present invention.

[Explanation of symbols on the main parts of the drawings]

1: Connector plug for disconnection 2: Connector socket for disconnection

3: end separation connector 4: end separation surface of rocket

5: Connector disconnection line 6: Connector disconnection line

7: cable 8: grounding

9: ignition device 10: ignition command

11: sequence controller 12: resistance

The present invention provides a conventional pull-out connector that is a push-pull connector in which the connector is separated while being disconnected.

Disconnecting connector (3) connected using two pins,

A connector disconnecting wire 5 connected to the connector for disconnecting the connector 3 to disconnect the plug 1 of the connector when the terminal is disconnected;

A fixing line 6 of a connector separating line for fixing the connector separating line 5 to the rocket end,

A ground 8 connected to the plug 1 of the connector 3 for disconnecting ends;

An ignition device 9 connected to the socket 2 of the connector for disconnecting stage 3,

An ignition command 10 of the inertial navigation device inputted to an input terminal of the ignition device 9,

The sequence controller 11 controls the ignition command 10 of the inertial navigation apparatus.

As shown in FIG. 1, a stage separation connector 3 is mounted with a plug 1 and a socket 2 of the stage separation connector 3 connected to each other using two pins on the rocket stage separation surface 4. If the stage separation of the rocket is made by the connector separation line (Lanyard) 5 attached to the stage separation connector (3), the plug (1) of the stage separation connector is pulled out.

In addition, as shown in FIG. 2, when the stage separation is smoothly performed, the plug of the stage separation connector 3 is pulled out and is separated from the ground 8 connected to the input terminal of the ignition device 9, thereby controlling the inertial navigation by the control of the sequence controller 11. If the two-stage or three-stage propulsion engine is enabled to receive the ignition command (10) of the device, but the stage is not separated by various factors such as external causes (electromagnetic waves, etc.) or failure of the internal flight sequence controller, The plug (1) of the stage disconnect connector (3) does not come out, and the ground (8) is always connected to the input terminal of the ignition device (9), so that even if the ignition command (10) comes from the inertial navigation system, the ignition device (9) receives this command. You can see that it does not accept.

This function can be used as the redundancy of SAD, which is a two- and three-stage ignition safety device after the total assembly of the rockets, which greatly helps to increase safety when preparing for launch.

According to the present invention, a separate end disconnecting sensor and a separate hardware and software are not required, and the functional side is much safer in terms of functionality (the device is unlikely to break down because there is no need for a separate device). The present invention relates to a two- and three-stage ignition stabilizer used, and is expected to be usefully applied to various ground equipments requiring similar functions.

Claims (2)

In the existing stage separation connector, which is a push-pull connector in which the stage is separated and the connector is separated, Disconnecting connector (3) connected using two pins, A connector disconnecting wire 5 connected to the connector for disconnecting the connector 3 to disconnect the plug 1 of the connector when the terminal is disconnected; A fixing line 6 of a connector separating line for fixing the connector separating line 5 to the rocket end, A ground 8 connected to the plug 1 of the connector 3 for disconnecting ends; An ignition device 9 connected to the socket 2 of the connector for disconnecting stage 3, An ignition command 10 of the inertial navigation device inputted to an input terminal of the ignition device 9, The rocket mounting propulsion engine ignition safety device, characterized in that consisting of a sequence controller for controlling the ignition command (10) of the inertial navigation device. The terminal separating connector (3) is characterized in that the plug (1) and the socket (2) of the separating connector (3) are connected to each other by using two pins on the separating surface (4). Rocket mounted propulsion engine ignition safety device.