The present invention relates to an airbag device mounted on a flying object.
In recent years, with the development of flight control technology, an industrial use of flying objects equipped with a plurality of rotor blades, for example, called drone, is accelerating. Such flying objects are expected to expand worldwide in the future.
On the other hand, the risk of fall accidents of flying objects as described above is considered to be dangerous and hinders spread of the flying objects. A background where the risk of such a fall accident is considered to be dangerous is considered to be related to the possibility that a lithium ion battery mounted on a flying object may be ignited by falling impact. Importance of battery protection is becoming an international consensus. It is important to protect other devices (such as various sensors, safety devices, and flight control devices) mounted on flying objects.
Thus, in order to reduce falling impact on a flying object, it has been proposed that the flying object is provided with an airbag. For example, Patent Literature 1 describes that an airbag is provided at a lower portion of a multicopter (helicopter) as a flying object.
Patent Literature 1: Japanese Published Unexamined Patent Application-A No. 2016-088111
However, since the airbag provided in the multicopter described in Patent Literature 1 is large enough to reach a region over the entire lower portion of the multicopter when the airbag inflates, the total weight of the airbag is heavy. As a result, the flight performance is significantly reduced. In the technology of Patent Literature 1, it is difficult to individually protect each device mounted on a flying object.
Thus, an object of the present invention is to provide an airbag device for a flying object, which sufficiently has a performance of protecting each device mounted on the flying object.
(1) The present invention is an airbag device for a flying object, which protects at least one of objects to be protected mounted on the flying object, and the airbag device includes an airbag, which is provided adjacent to at least one of the objects to be protected mounted on the flying object, is contracted or folded in an initial state, and is deployable so as to cover a portion or the entirety of a periphery of the object to be protected mounted on the flying object when the airbag is inflated and a gas generator which is connected to the airbag and is capable of supplying gas into the airbag to inflate the airbag when the gas generator is activated.
In general, gas generators can be roughly divided into non-explosive and explosive types. In the non-explosive type gas generator, it is the mainstream to connect a sharp member such as a needle and a compressed spring to a gas cylinder filled with gas such as carbon dioxide or nitrogen, use spring force to fly the sharp member, and make the sharp member collide with a sealing plate sealing the cylinder to release the gas. At this time, a drive source such as a servomotor is usually used to release a compression force of the spring. In the case of the explosive type, either an igniter alone or an igniter and a gas generating agent may be provided. A hybrid-type or stored-type gas generator may be used in which a sealing plate in a small gas cylinder is cleaved by the power of explosives and an internal gas is discharged to the outside. In this case, a pressurized gas in the gas cylinder is selected from at least one or more non-combustible gases such as argon, helium, nitrogen and carbon dioxide. A gas generator may be equipped with an explosive heating element in order to ensure expansion when the pressurized gas is released. Furthermore, the gas generator may be equipped with a filter and an orifice for adjusting a gas flow rate as required.
(2) In the airbag device for a flying object in (1), the object to be protected mounted on the flying object is preferably a power source of the flying object, a safety device used to protect the flying object and a collision object that collides with the flying object from the impact at the time of collision, a laser surveying device capable of performing surveying, an altitude sensor capable of detecting altitude, an infrared sensor or ultrasonic sensor capable of detecting a distance from the collision object, a camera capable of performing imaging, a black box device that records acquired data, or a flight control device that controls flight of the flying object.
According to the configuration in (1) or (2), each device mounted on the flying object can be protected from the impact at the time of collision. In particular, according to the configuration in (2), since each important device mounted on the flying object can be protected from the impact at the time of collision, even after the collision, control of the flying object and operation of each device cannot be disturbed.
(3) In the airbag device for a flying object in (1) or (2), the airbag is preferably a tubular expandable body which expands so as to cover a portion (such as a side surface of a device) or the entirety of a periphery of the object to be protected mounted on the flying object when the gas generator is operated.
(4) As another aspect, in the airbag device for a flying object in (1) or (2), the airbag is preferably an expandable body having a dome-like portion which expands so as to cover a portion or the entirety of a periphery of an object to be protected mounted on the flying object when the gas generator is operated.
According to the configuration in (3) or (4), even if a device to be protected is provided outside an airframe (housing) of the flying object, the object to be protected mounted on the flying object can be protected from the impact at the time of collision.
(5) The airbag device for a flying object in (1) to (4) preferably has a vent hole capable of exhausting gas inside the airbag until the inside of the airbag reaches a predetermined internal pressure or less when the inside of the airbag reaches the predetermined internal pressure or more. When the vent hole is provided, a volume change of the gas inside the airbag at the time of collision becomes large, and there is an effect that the impact can be easily absorbed.
(6) In the airbag device for a flying object in (1) to (5), an internal pressure value of the airbag is preferably −67.4 kPa to 48.6 kPa after the internal pressure of the airbag exhibits a minimum value.
According to the configuration in (5) or (6), since the airbag suitably absorbs the impact at the time of collision, an object to be protected mounted on the flying object can be protected from the impact at the time of collision with higher accuracy.
(7) In the airbag device for a flying object in (1), preferably, one of the objects to be protected mounted on the flying object is a detection device capable of detecting or predicting collision between the flying object and an obstacle existing outside the flying object, and after the detection device detects or predicts the collision between the flying object and the obstacle existing outside the flying object, the detection device transmits an operation signal to the gas generator to operate the gas generator, and controls the airbag to start deployment within 5 ms to 36 s. Since an explosive gas generator is activated in 2 ms after receiving the operation signal, the airbag starts to be deployed in at least 5 ms after the operation signal is transmitted. Although it is possible to activate the airbag device after collision is predicted by a sensor, the longest limit in this case is 36 s.
According to the configuration in (7), the airbag can be deployed in a very short time, and, in addition, the airbag can be deployed at a suitable timing by predicting collision.
(8) In the airbag device for a flying object in (7), preferably, one of the objects to be protected mounted on the flying object is a detection device capable of detecting or predicting collision between the flying object and an obstacle existing outside the flying object, and a detectable distance from the detection device to the obstacle existing outside the flying object is 0 m to 10 m.
According to the configuration of (8), the detectable distance can be accurately detected at 0 μm to 10 μm of the collision by using an acceleration sensor, an ultrasonic sensor, or the like alone or by combining them. If the detectable distance exceeds approximately 10 m, it becomes difficult to judge whether or not the object collides, which will lead to an erroneous determination. In addition, an erroneous determination is led by scattering of ultrasonic waves or the like emitted from the sensor.
(9) In the airbag device for a flying object in (1), when a weight of the flying object is M [kg], a speed at which the airbag can absorb impact is W [m/s], and a numerical value X [kg1/2·m/s] is M1/2×W, X is preferably 50 to 900.
According to the configuration of (9), for example, when an obstacle of 10 kg collides, an impact absorption effect can be exhibited in a speed range of 16.1 to 278.9 km/h; therefore, impact can be absorbed even in collision at a maximum speed (100 km/h) of a current electric multicopter.
(10) In the airbag device for a flying object in (1) to (9), preferably, the gas generator has a pyro-type gas generating agent and is configured such that the gas is generated by combustion of the pyro-type gas generating agent to flow into the airbag.
According to the configuration of (10), a mode (generally referred to as a pyro type) in which gas generated by combustion of a pyro-type gas generating agent is made to flow into the airbag is employed, whereby as compared with a mode (generally referred to as a cylinder type) in which compressed gas filled in a container is made to flow into the airbag, the container for filling the compressed gas is not required, so that the weight of the airbag device can be further reduced.
As the pyro-type gas generating agent, a non-azide gas generating agent is preferably used, and in general, a gas generating agent is formed as a molded body containing a fuel, an oxidant and an additive. As the fuel, for example, a triazole derivative, a tetrazole derivative, a guanidine derivative, an azodicarbonamide derivative, a hydrazine derivative or the like or a combination thereof is used. Specifically, for example, nitroguanidine, guanidine nitrate, cyanoguanidine, 5-aminotetrazole and the like are suitably used. Furthermore, used as an oxidant is, for example, basic nitrate such as basic copper nitrate, perchlorate such as ammonium perchlorate and potassium perchlorate, nitrate including cation selected from alkali metal, alkaline-earth metal, transition metal, and ammonia, and the like. As the nitrate, for example, sodium nitrate, potassium nitrate and the like are suitably used. Examples of additives include a binder, a slag-forming agent, and a combustion-adjusting agent. As a binder, for example, an organic binder such as a metal salt of carboxymethyl cellulose or stearic acid salt, or an inorganic binder such as synthetic hydroxytalcite or acid clay can suitably be used. As the slag-forming agent, silicon nitride, silica, acid clay and the like can be suitably used. As the combustion-adjusting agent, metal oxides, ferrosilicon, activated carbon, graphite and the like can be suitably used. In addition, single base powder, double base powder, or triple base powder based on nitrocellulose may be used.
The shape of the molded body of the pyro-type gas generating agent includes a variety of shapes like a granule, a pellet, a columnar grain, a disk, and the like. In the molded body having a columnar shape, a perforated (for example, a single-hole cylindrical shape or a porous cylindrical shape, etc.) molded body having a through hole inside the molded body is used. In addition to the shape of the gas generating agent, it is preferable to appropriately select the size and the filling amount of the molded body in consideration of the linear burning rate, pressure index and the like of the gas generating agent.
(11) In the airbag device for a flying object in (1) to (9), the gas generator may include a gas-filled container filled with compressed gas and an igniter that has an ignition charge and cleaves the gas-filled container owing to combustion of the ignition charge to make the compressed gas as the gas flow into the airbag. Examples of a gas generator having an igniter include a hybrid-type gas generator and a stored-type gas generator.
According to the configuration of (11), a gas-filled container is cleaved by combustion of an ignition charge to flow compressed gas from the gas-filled container, so that a gas generating agent to be burned by flame due to a squib is not required.
(12) In the airbag device for a flying object in (1) to (11), preferably, at least one of the objects to be protected mounted on the flying object is provided inside an airframe (housing) of the flying object, and the airbag is provided inside the airframe of the flying object to be adjacent to the object to be protected mounted on the flying object provided inside the airframe of the flying object.
According to the configuration of (12), the airbag is provided inside the airframe of the flying object and is expandable inside the housing, whereby the weight can be significantly reduced as compared with conventional airbags that are provided at a lower portion of a flying object in an initial state and reach a region over the entire lower portion of the flying object when inflated. This does not degrade the flight performance of the flying object. Since the airbag in (11) inflates inside the airframe of the flying object provided with various devices, performance of protecting the device provided inside the flying object is satisfactorily secured. According to the above, it is possible to provide an airbag device for a flying object which is reduced in weight while sufficiently having a performance of protecting a device provided inside the flying object.
Hereinafter, an airbag device for a flying object according to an embodiment of the present invention will be described with reference to the drawings.
As shown in
The gas generator 3 is connected to the expandable member 2. In detail, the gas generator 3 is inserted inside the expandable member 2 from a left portion of the expandable member 2 except for a portion of the gas generator 3 (refer to the below-mentioned
The gas generator 3 includes a squib 5, a bottomed cylindrical filter 6 having an open end, and a bottomed cylindrical gas discharge member 7 having an open end and covering an outer shape portion of the filter 6. The squib 5 has an ignition part 5a and a pair of terminal pins 5b. The ignition part 5a includes a resistor (bridge wire) (not shown) connected to the pair of terminal pins 5b, and an ignition charge is filled in the ignition part 5a so as to surround the resistor or be in contact with the resistor. A transfer charge may be charged into the ignition part 5a as necessary. A nichrome wire or the like is generally used as the resistor, and ZPP (zirconium/potassium perchlorate), ZWPP (zirconium tungsten potassium perchlorate), lead tricinate and the like are generally used as an ignition charge. The type and amount of the ignition charge can be adjusted appropriately.
The filter 6 prevents or suppresses that slag and the like are discharged out of the filter 6 during combustion of the ignition charge, and has a function of cooling gas. The filter 6 is disposed in the expandable member 2 in a state where the open end of the filter 6 is connected to an inner portion the expandable member 2. The squib 5 is disposed to close the open end of the filter 6. Although the filter 6 is provided from the viewpoint of slag collection and gas cooling as described above, from the viewpoint of reducing the weight of the airbag device 1 for a flying object and a flying object 10 described later equipped with the airbag device 1, the filter 6 is not an essential component. That is, in the present embodiment, the filter 6 may or may not be provided.
The gas discharge member 7 is disposed in the expandable member 2 in a state where the open end of the gas discharge member 7 is connected to the expandable member 2. The gas discharge member 7 has a plurality of gas outlets 7a formed on the upper side in
In such a configuration, in a state where the airbag device 1 for a flying object is mounted on the flying object, when the flying object is in a preset state such as (1) when the flying object collides, (2) when an acceleration sensor (not shown) detects acceleration not less than a value determined that the flying object is falling, or (3) when an operation signal from a wireless operation device (not shown) is not received for a certain period of time, the current supply section 4 having received a signal from a control device (not shown) (such as a computer that includes a CPU, a ROM, a RAM, and the like and operates according to a predetermined program) supplies a predetermined amount of current to the terminal pin 5b. As a result, current is supplied to the resistor in the ignition part 5a, and Joule heat is generated in the resistor, so that the ignition charge starts to burn in response to this heat. As the ignition charge burns, combustion of the pyro-type gas generating agent starts, and gas is generated in the filter 6. This gas flows into the expandable member 2 from the gas outlet 7a of the gas discharge member 7 through the filter 6. Consequently, the expandable member 2 is expanded.
Next, the configuration of the flying object equipped with the airbag device 1 for a flying object will be described.
The flying object 10 is a flight device that performs flight based on user's remote control operation or a preset flight route. As shown in
Returning to
The rotational speeds of all the propellers 11a, 11b, 11c, and 11d are made the same, and while the propellers 11a and 11c are rotated in one direction, the propellers 11b and 11d are rotated in the opposite direction with respect to the one direction, whereby the flying object 10 can be raised or lowered. In a state where the flying object 10 is flying, if the rotational speed of the propellers 11a and 11b is slower than the rotational speed of the propellers 11c and 11d, the flying object 10 moves in the direction of the propellers 11a and 11b. Conversely, in the state where the flying object 10 is flying, if the rotational speed of the propellers 11c and 11d is slower than the rotational speed of the propellers 11a and 11b, the flying object 10 moves in the direction of the propellers 11c and 11d. In the state where the flying object 10 is flying, if the rotational speed of the propellers 11a and 11c is slower than the rotational speed of the propellers 11b and 11d, the flying object 10 horizontally rotates clockwise or counterclockwise. Thus, the flying object 10 can realize each operation of floating, horizontal movement, rotational movement, stopping, and landing by changing the rotational speed and rotational direction of the propellers 11a, 11b, 11c, and 11d. The number of propellers is a mere example and is not limited to four.
Subsequently, the flying object 10 includes rotor guards 15a, 15b, 15c, and 15d that correspondingly protect the propellers 11a, 11b, 11c, and 11d, and an upper center guard 17 and a lower center guard 18 connected to each other (see
As shown in
Subsequently, the flying object 10 is provided with various components for retaining the structure of the flying object 10. More specifically, as shown in
The legs 25b and 25d are grounded when the flying object 10 lands. Here, in the lower cover member 20, openings 20b and 20d are formed in portions corresponding to the legs 25b and 25d. The leg 25b protrudes outward through the opening 20b, and the leg 25d protrudes outward through the opening 20d. The opening 20b is formed below the propeller 11b, and the opening 20d is formed below the propeller 11d, whereby air permeability below the propellers 11b and 11d is improved, so that the flight performance can be improved.
The frame connecting member 26b is connected to the frame 16, the leg 25b, and the central frame 21, and the frame connecting member 26d is connected to the frame 16, the leg 25d, and the central frame 21. The frame connecting members 26b and 26d are members having elasticity, and are formed of, for example, plastic. Thus, by making the frame connecting members 26b and 26d elastic, it is possible to absorb the impact from the frame 16 and the four legs including the legs 25b and 25d.
The central frame 21 is provided substantially at the center in the height direction inside the flying object 10. The central frame 21 is formed of, for example, a member that is strong and is less likely to be thermally deformed like metals, carbon, or the like. The base 23 described above and a portion of the expandable member 2 of the airbag device 1 are disposed on the central frame 21. The motor holding portions 14b and 14d hold the motors 12b and 12d. The motor holding portions 14b and 14d are supported by the central frame 21.
Here, as shown in
Based on the state of
As described above, according to the airbag device 1 according to the present embodiment, the expandable member 2 is provided inside an airframe (housing (the upper cover member 19 and the lower cover member 20)) of the flying object 10 provided with the battery 24 and is expandable inside the airframe, whereby the weight can be significantly reduced as compared with conventional airbags that is provided at a lower portion of a flying object in an initial state and reaches a region over the entire lower portion of the flying object when inflated. This does not degrade the flight performance of the flying object 10. Since the expandable member 2 expands inside the airframe of the flying object 10 provided with the battery 24, performance of protecting the battery 24 is satisfactorily secured. According to the above, it is possible to provide the airbag device 1 for a flying object which is reduced in weight while sufficiently having a performance of protecting the battery 24.
In the present embodiment, a mode (pyro type) in which gas generated by combustion of the ignition charge is made to flow into the expandable member 2 is employed, whereby as compared with a mode (cylinder type) in which compressed gas filled in a container is made to flow into an expandable member, the container for filling the compressed gas is not required, so that the weight of the airbag device 1 can be further reduced.
In the present embodiment, a portion of the expandable member 2 is disposed in contact with the upper portion of the battery 24 in the initial state, whereby the upper portion of the battery 24 can be satisfactorily protected when the expandable member 2 is expanded.
Thus, the embodiment of the present invention has been described hereinabove with reference to the drawings. However, the specific structure of the present invention shall not be interpreted as to be limited to the above described embodiment. The scope of the present invention is defined not by the above embodiment but by claims set forth below, and shall encompass the equivalents in the meaning of the claims and every modification within the scope of the claims. The following modifications can be applied.
In the above embodiment, the mode (pyro type) in which gas generated by combustion of a powder is made to flow into the expandable member 2 is employed, but the invention is not limited thereto, and, as described below, the cylinder type in which compressed gas filled in a gas-filled container is made to flow into an expandable member 102 may be employed. Here, in the following description, components with the same last two digits as those in the above-described embodiment are the same as those described in the above-described embodiment unless otherwise specified, and therefore the description thereof may be omitted.
As shown in
In the configuration as described above, in a state where an airbag device 101 for a flying object is mounted instead of the airbag device 1 for the flying object 10 of the above embodiment, at the time of collision, a current supply section 104 having received a signal from a control device (not shown) supplies a predetermined amount of current to a terminal pin 105b. As in the above embodiment, current is supplied to the resistor in an ignition part 105a, and Joule heat is generated in the resistor, so that the ignition charge starts to burn in response to this heat.
Then, the ignition charge burns to generate gas in the connection chamber 31. The pressure of the gas causes the vulnerable wall 33 to be cleaved, and as a result, the pressure in the gas-filled container 32 increases, so that the vulnerable portion of the gas-filled container 32 is cleaved. As a result, the compressed gas in the gas-filled container 32 flows into the expandable member 102, and the expandable member 102 is expanded. According to such an embodiment, the gas generating agent burned by flame due to the squib 105 is not required.
In the above embodiment, a portion of the expandable member 2 is disposed in contact with the upper portion of the battery 24 in the initial state, but the invention is not limited thereto, and as long as the battery 24 can be protected after operation, a portion of the expandable member 2 may be disposed separately above the battery 24 without being in direct contact with the upper portion of the battery 24 in the initial state. A portion of the expandable member 2 may be disposed in contact with a side portion of the battery 24 in the initial state, or may be disposed to the side of the battery 24.
Furthermore, in the above embodiment, a portion of the expandable member 2 is disposed in contact with the upper portion of the battery 24 in the initial state, but the invention is not limited thereto, and as shown in
In the above embodiment and modification, although protection of the battery provided inside the airframe of the flying object has been explained, the present invention can be applied not only to the battery but any device provided inside the airframe.
Further, as another modification, there are an airbag device for a flying object according to a modification shown in
A flying object 200 includes an airframe 201, one or more propulsion mechanisms (such as a propeller) 202 that are connected to the airframe 201 and propel the airframe 201, a plurality of legs 203 provided at a lower portion of the airframe 201, a device 204 provided at a lower center of the airframe 201, and an airbag device 205 provided on a side surface of the device 204. Although the airbag device 205 has substantially the same configuration as any of the airbag devices in the above embodiment or the modification, the airbag device 205 is different in that as shown in
The device 204 is, for example, a power source of the flying object 200, a safety device used to protect the flying object 200 and a collision object that collides with the flying object 200 from the impact at the time of collision, a laser surveying device capable of performing surveying, an altitude sensor capable of detecting altitude, an infrared sensor or ultrasonic sensor capable of detecting a distance from the collision object, a camera capable of performing imaging, a controller 220 (see
As shown in
The sensor 211 detects a flight state of the flying object 200 (including collision, collision prediction, crash, and the like). Specifically, the sensor 211 is a sensor including one or more selected from, for example, an acceleration sensor, a gyro sensor, an air pressure sensor, a laser sensor, an ultrasonic sensor, etc. and can acquire data of the flying state of the flying object 200, such as the speed, acceleration, inclination, altitude, and position of the flying object 200.
The controller 220 includes a sensor abnormality detection section 221, a calculation section 222, and a notification section 223 as a functional configuration. The controller 220 executes a predetermined program to functionally realize the sensor abnormality detection section 221, the calculation section 222, and the notification section 223.
The sensor abnormality detection section 221 detects an abnormal state of the sensor 211. That is, the sensor abnormality detection section 221 detects whether the sensor 211 can operate normally.
The calculation section 222 determines whether the flying state of the flying object is abnormal, specifically, whether the flying object 200 has received an impact (or whether the flying object 200 has collided), based on each piece of data acquired by actual measurement by the sensor 211. Alternatively, the calculation section 222 predicts that the flying object 200 collides with an external obstacle (collision prediction). In the collision prediction, a distance between the flying object 200 and an obstacle is measured by an infrared sensor, an ultrasonic sensor, or the like, and a relative speed between the flying object 200 and the obstacle is measured by an acceleration sensor, a camera, or the like. Alternatively, the calculation section 222 calculates the relative speed with respect to the obstacle from a time change of the measured distance and calculates time until collision from the relative speed of the obstacle and the distance from the obstacle at that time. When the calculation result is equal to or more than a predetermined threshold value, a collision is predicted, and it is determined that the flight state is abnormal. When the calculation section 222 determines that the flight state of the flying object is abnormal or predicts that the flying object 200 collides with an external obstacle, the calculation section 222 outputs an abnormality signal (that may include an instruction signal to activate or operate other equipment) to the outside; however, an abnormality signal output section may be provided separately from the calculation section 222 and output the abnormality signal according to an instruction of the calculation section 222.
When the sensor abnormality detection section 221 detects an abnormality in the sensor 211, the notification section 223 notifies an administrator or the like that the abnormality has been detected.
Subsequently, the operation of the abnormality detection device 240 of the present embodiment will be described.
First, the sensor abnormality detection section 221 performs an abnormality inspection of the sensor 211. Specifically, whether an acceleration sensor or the like that measures the acceleration of the flying object normally operates is inspected by the sensor abnormality detection section 221.
When it is not determined that there is no abnormality as a result of the above inspection, the sensor abnormality detection section 221 notifies the administrator or the like of an error and ends the inspection. On the other hand, when it is determined that there is no abnormality as a result of the inspection, the calculation section 222 reads each piece of data actually measured by the sensor 211.
When the data measured and acquired by the sensor 211 is not abnormal (including a case where the collision prediction is determined), the calculation section 222 outputs a signal to be returned to the processing of the abnormality inspection of the sensor 211 by the sensor abnormality detection section 221.
On the other hand, when the acquired data is abnormal (including the case where the collision prediction is determined), the calculation section 222 outputs the abnormal signal to the gas generator 206. When the collision prediction is determined, the abnormality signal is immediately output to the gas generator 206 if a prediction time until collision is shorter than time required to deploy the airbag, and if the prediction time until the collision is longer than the time required to deploy the airbag, a sum of time to reach an optimal internal pressure value of the airbag and the time required to deploy the airbag is compared with the calculated time until the collision. If the calculated time is shorter, the abnormality signal is output to the gas generator 206, and if the calculated time is longer, the process of measuring the distance from the obstacle again and calculating the time until the collision again is repeated. By following this process, malfunction or erroneous detection is prevented to ensure reliability of the operation.
Then, the gas generator 206 having received a deployment device activation signal is activated, deploys the airbag of the airbag device 205 such that the airbag has a shape as shown in
According to the present modification configured as above, since each important device mounted on the flying object 200 can be protected from the impact at the time of collision, even after the collision, control of the flying object 200 and operation of each device cannot be disturbed. In particular, a device provided outside the flying object 200 can be effectively protected from the impact at the time of collision.
Further, as another modification, there are an airbag device 305 for a flying object according to a modification shown in
The present modification is different from the modification shown in
A detectable distance can be accurately detected at 0 m to 10 m of the collision by using an acceleration sensor, an ultrasonic sensor, or the like alone or by combining them. If the detectable distance exceeds approximately 10 m, it becomes difficult to judge whether or not the object collides, which will lead to an erroneous determination. In addition, an erroneous determination is led by scattering of ultrasonic waves or the like emitted from the sensor.
In the present invention, a tank combustion test is a test conducted by the method described below. A gas generator for an airbag is fixed at room temperature in a 60-liter SUS (stainless steel) tank, and a cable sealed from the outside of the tank to the inside of the tank is connected to an igniter of the gas generator to seal the tank. Further, the sealing cable is connected to an outside ignition current generating device. The ignition current generating device is switched on, and the switching-on operation is used as a trigger to start data collection by a pressure sensor installed on an inner wall of the tank. The time when the ignition current generating device is switched on is set to 0, and a pressure increase change in the tank is measured by a data logger for time from 0 ms to 210 ms. A sampling rate is 10 kHz. Data sampled by the data logger is digitally signal processed to obtain a curve that finally serves as a tank pressure-time (kPa/milliseconds) curve and evaluates performance of the gas generator.
The tank combustion test was conducted on the gas generators used in Examples 1 and 2. The results are shown in
Specifications of the airbag used in Examples 1 and 2 are shown in
A device (airbag device) in which a gas generator was assembled to the above-described airbag folded into a small size was used, a pressure sensor (PGM-10KC (Kyowa Electronic Instruments Co., Ltd.)) was attached to the airbag device in an initial state, and the airbag device was operated. The result of measuring a change over time in an internal pressure (pressure) of the airbag is shown in
In
Using the same airbag device having two vent holes as used in Example 1, a resultant acceleration calculation test was conducted by an impactor test in which using the facilities of Japan Automobile Research Institute, a head impactor (comparable product with domestic technical standard and ECE No. 127) was vertically collided with the airbag at 36 km/h. The outline of this test is shown in
A resultant acceleration measurement test according to an impactor test was conducted in the same manner as in (Example 2) using each of the airbag devices of (Example 1). The resultant acceleration was measured at each time (60 ms) at when the maximum resultant acceleration decreased in (Example 2). A peak top value of the measured resultant acceleration is taken as the maximum resultant acceleration, and the result is shown in
Using the airbag device of the present invention, an estimate was made that an obstacle having a weight of M [kg] was made to collide. The trial calculation was performed according to the procedure shown below.
(1) Calculation of Theoretical Energy Absorption Value of Airbag
A theoretical energy absorption value P×V [J] of the airbag is obtained from an airbag internal pressure P [kPa] and an airbag volume V [L] when an obstacle collides.
(2) Calculation of Speed W at which Impact can be Absorbed by Airbag
A relative speed W [km/h] of an obstacle (weight M [kg]) at which impact can be absorbed by the airbag is expressed by the following equations according to the energy conservation law.
(3) Calculation of Numerical Value X
A numerical value X [(kg)1/2·km/h] is defined as the following equation.
x=√{square root over (M)}·W=5.1×√{square root over (PV)}
From
Number | Date | Country | Kind |
---|---|---|---|
2016-247225 | Dec 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2017/045841 | 12/20/2017 | WO | 00 |