JP5633365B2 - Device operating system - Google Patents

Description

    The present invention relates to a device operation system, and particularly relates to operation of a device using a gas generating agent.

    Conventionally, various output devices such as an air conditioner, a power window, and an air bag are mounted on a vehicle. There is known an operating system provided with a plurality of electronic control devices (hereinafter referred to as an ECU (electric control unit)) in order to control operations of these various output devices (see Patent Document 1).

    Here, in the operating system (a) as shown in FIG. 6, two signal lines (d, d) extend from one ECU (b) and are connected to the cutting device (c, c). Each cutting device (c) is configured such that the explosive explodes based on the electrical signal sent from the ECU (b), the blade (e) advances, and the energization member (f) is cut. ing.

JP 2008-113554 A

    However, in the operation system (a) as shown in FIG. 6, a signal line (d) corresponding to each cutting device (c, c) which is an output device from the ECU (b) is provided. For this reason, since ECU (b) directly outputs an electrical signal to each cutting device (c, c), there is a problem that power consumption increases.

    The present invention has been made in view of such a point, and an object thereof is to operate a plurality of output devices while suppressing an electric signal output from an ECU.

The first invention comprises two devices (21, 35) each having a gas generating part (23, 37) for generating a high-pressure gas by reaction of a gas generating agent, and gas generation of both devices (21, 35) Device operating system for operating the part (23, 37), an electronic device for outputting an electrical signal for operating the gas generating part (23) of one of the two devices (21, 35) (21) A control unit (11) and an operating unit (29) for operating the gas generating part (37) of another device (35) by the pressure of the high-pressure gas generated by the reaction of the gas generating agent are provided. The operating unit (29) includes a hammer member (31) that is operated by the pressure of the high-pressure gas generated by the reaction of the gas generating agent, and the gas generation of the other device (35) by the operation of the hammer member (31). The part (37) is configured to operate.

In the first invention, each of the two devices (21, 35) includes a gas generation section (23, 37) that generates a high-pressure gas by the reaction of the gas generating agent. The one device (21) is connected to the electronic control unit (11). The operation unit (29) includes a hammer member (31).

When the electronic control unit (11) issues an operation signal to the one device (21), the gas generating part (23) of the one device (21) is activated, and high-pressure gas is generated by the reaction of the gas generating agent. . The operating unit (29) operates the gas generating part (37) of the other device (35) by the pressure of the high-pressure gas generated by the reaction of the gas generating agent. When the high pressure gas is generated by the reaction of the gas generating agent, the hammer member (31) is operated by the pressure of the high pressure gas. The operation unit (29) operates the gas generation part (37) of the other device (35) by the operation of the hammer member (31).

The second invention comprises two devices (21, 35) each having a gas generating part (23, 37) for generating a high-pressure gas by reaction of a gas generating agent, and gas generation of both devices (21, 35) Device operating system for operating the part (23, 37), an electronic device for outputting an electrical signal for operating the gas generating part (23) of one of the two devices (21, 35) (21) A control unit (11) and an operating unit (29) for operating the gas generating part (37) of another device (35) by the pressure of the high-pressure gas generated by the reaction of the gas generating agent are provided. The second invention includes a piezoelectric sensor (45) for detecting pressure, and is configured to operate the gas generating part (37) of the other device (35) by a device operation signal generated based on the detection. Yes.

In the second aspect of the invention, each of the two devices (21, 35) includes a gas generator (23, 37) that generates a high-pressure gas by the reaction of the gas generating agent. The one device (21) is connected to the electronic control unit (11). The operating unit (29) includes a piezoelectric sensor (45). The piezoelectric sensor (45) detects pressure.

When the electronic control unit (11) issues an operation signal to the one device (21), the gas generating part (23) of the one device (21) is activated, and high-pressure gas is generated by the reaction of the gas generating agent. . The operating unit (29) operates the gas generating part (37) of the other device (35) by the pressure of the high-pressure gas generated by the reaction of the gas generating agent. Based on the pressure detection , the operation unit (29) generates a device operation signal for operating the other device (35), and sends the device operation signal to the other device (35). The gas generating part (37) of the other device (35) is activated by the sent device activation signal.

According to a third aspect of the present invention, in the second aspect of the invention, the advancement member (26) is provided to advance in a predetermined advance direction by the high-pressure gas generated by the reaction of the gas generating agent, and the piezoelectric sensor (45) (26) It is comprised so that the pressure of the collision may be detected.

In the said 3rd invention, the advancing member (26) advanced in a predetermined direction with the high pressure gas generated by reaction of the gas generating agent is provided. When the advance member (26) is advanced by the high pressure gas generated by the reaction of the gas generating agent, the advance member (26) collides with the piezoelectric sensor (45). Thereby, a piezoelectric sensor (45) detects the pressure of the collision of an advancing member (26). The operation unit (29) generates a device operation signal for operating the other device (35) based on the pressure detection, and sends the device operation signal to the other device (35). The gas generating part (37) of the other device (35) is activated by the sent device activation signal.

In a fourth aspect based on the second aspect , the piezoelectric sensor (45) is configured to detect the pressure of the high-pressure gas generated by the reaction of the gas generating agent.

In the fourth aspect of the invention, when high pressure gas is generated by the reaction of the gas generating agent, the piezoelectric sensor (45) detects the pressure of the high pressure gas. The operation unit (29) generates a device operation signal for operating the other device (35) based on the pressure detection, and sends the device operation signal to the other device (35). The gas generating part (37) of the other device (35) is activated by the sent device activation signal.

According to a fifth invention, in any one of the second to fourth inventions, between the piezoelectric sensor (45) and the other device (35), the other device (35) is provided. A delay device for shifting the operation timing is provided.

In the fifth aspect , when high pressure gas is generated by the reaction of the gas generating agent, the piezoelectric sensor (45) detects the pressure of the high pressure gas. The operation unit (29) generates a device operation signal for operating the other device (35) based on the pressure detection. Then, the delay device sends the generated device operation signal to another device (35) with a time difference. The gas generating part (37) of the other device (35) is activated by the sent device activation signal.

According to a sixth invention, in any one of the first to fifth inventions, the other device (35) includes at least a device (60) having a gas generating part (62) and an operation unit (68). The operating unit (68) is connected in series with the gas of the device (60) by the pressure of the high pressure gas generated by the reaction of the gas generating agent of the gas generating part (37) of the other device (35). The generator (62) is configured to operate.

In the said 6th invention, the device (60) which has at least a gas generation part (62) is connected to the other device (35) in series via the action | operation unit (68).

    When the gas generating part (37) of the other device (35) is activated and high-pressure gas is generated by the reaction of the gas generating agent, the operating unit (68) is connected to the gas generating part (37) of the other device (35). The gas generating part (62) of the device (60) is operated by the pressure of the high-pressure gas.

According to a seventh invention, in the sixth invention, the operating unit (68) includes a piezoelectric sensor (69) for detecting pressure, and the device (60) of the device (60) is generated by a device operating signal generated based on the detection. A gas generator (62) is configured to operate, and a delay device for shifting the operation timing of the device (60) is provided between the piezoelectric sensor (69) and the device (60).

In the seventh invention, the operating unit (68) includes the piezoelectric sensor (69). The piezoelectric sensor (69) detects pressure. The operation unit (68) generates a device operation signal for operating the device (60) based on the pressure detection. Then, the delay device sends the generated device operation signal to the device (60) with a predetermined time difference. The gas generating part (62) of the device (60) is activated by the transmitted device activation signal.

The eighth invention comprises a plurality of devices (21, 35) each having a gas generating part (23, 37) for generating a high-pressure gas by reaction of a gas generating agent, and the plurality of devices (21, 35) A device operating system for operating the gas generating section (23, 37) of the gas based on the electrical signal from the electronic control device (11), the gas operating based on the electrical signal from the electronic control device (11) A device operating signal for operating the gas generating unit (23, 37) of each device (21, 35) by the pressure of the high pressure gas generated in the gas generating unit (53). And a signal distribution device (50) for distributing the device operation signal to the devices (21, 35).

In the eighth aspect of the invention, when an operation signal is issued from the electronic control device (11), the gas generating section (53) of the signal distribution device (50) is operated, and high pressure gas is generated by the reaction of the gas generating agent. Based on the pressure of the high-pressure gas, the signal distribution device (50) generates a plurality of device operation signals for operating the gas generation units (23, 37) of the plurality of devices (21, 35). Then, the signal distribution device (50) sends the generated device operation signal to each of the plurality of devices (21, 35). In each device (21, 35), each gas generator (23, 37) is activated by a device activation signal.

In a ninth aspect based on the eighth aspect , the signal distribution device (50) includes a piezoelectric sensor (56) that detects pressure, and generates the device operation signal based on the detection. Yes.

In the ninth aspect , the signal distribution device (50) includes the piezoelectric sensor (56). The piezoelectric sensor (56) detects pressure. Based on the pressure detection, the signal distribution device (50) generates a plurality of device operation signals for operating the gas generators (23, 37) of the plurality of devices (21, 35), and generates the device operation signals. Send to each device (21,35). In each device (21, 35), each gas generator (23, 37) is operated by a device activation signal sent thereto.

According to a tenth aspect of the present invention, in the eighth or ninth aspect, the operation timing of the plurality of devices (21, 35) is between the signal distribution device (50) and each device (21, 35). A delay device for shifting the position is provided.

In the tenth aspect of the invention, when an operation signal is issued from the electronic control device (11), the gas generating section (53) of the signal distribution device (50) is operated, and high pressure gas is generated by the reaction of the gas generating agent. Based on the pressure of the high-pressure gas, the signal distribution device (50) generates a plurality of device operation signals for operating the gas generation units (23, 37) of the plurality of devices (21, 35). Then, the delay device sends the generated device operation signal to each device (21, 35) with a time difference. In the plurality of devices (21, 35), the respective gas generators (23, 37) operate based on the device operation signal.

    According to the first aspect, since the operation unit (29) is provided, the gas generation part (37) of the other device (35) can be operated by the high pressure gas generated by the reaction of the gas generating agent. That is, in the conventional operation system (a) shown in FIG. 6, the plurality of devices (c, c) are each sent an electrical signal from the electronic control unit (b). However, in the present invention, only one device (21) operates based on the electric signal of the electronic control unit (11), and the other device (35) controls the pressure of the high-pressure gas generated by the reaction of the gas generating agent. It can be operated using. Thereby, the two devices (21, 35) can be operated while suppressing the electrical signal output from the electronic control unit (11).

And the operation unit (29) provided with the hammer member (31) which operate | moves with the pressure of a high pressure gas was provided. For this reason, a hammer member (31) can be operated by reaction of a gas generating agent. Thereby, the gas generation part (37) of the other device (35) can be operated without operating the other device (35) by the electronic control unit (11). As a result, the two devices (21, 35) can be operated while suppressing the electrical signal output from the electronic control unit (11).

In the said 2nd invention, since the operation | movement unit (29) was provided, the gas generation part (37) of another device (35) can be operated with the high pressure gas generated by reaction of the gas generating agent. That is, in the conventional operation system (a) shown in FIG. 6, the plurality of devices (c, c) are each sent an electrical signal from the electronic control unit (b). However, in the present invention, only one device (21) operates based on the electric signal of the electronic control unit (11), and the other device (35) controls the pressure of the high-pressure gas generated by the reaction of the gas generating agent. It can be operated using. Thereby, the two devices (21, 35) can be operated while suppressing the electrical signal output from the electronic control unit (11).

And the action | operation unit (29) provided with the piezoelectric sensor (45) which detects a pressure was provided. For this reason, a device operation signal can be generated based on detection of pressure. Thereby, the gas generation part (37) of another device (35) can be operated without operating the other device (35) by the electronic control unit (11). As a result, the two devices (21, 35) can be operated while suppressing the electrical signal output from the electronic control unit (11).

According to the third aspect , since the advancing member (26) is caused to collide with the piezoelectric sensor (45), the device operation signal can be generated by detecting the collision pressure of the advancing member (26). it can. Thereby, the gas generation part (37) of another device (35) can be operated without operating the other device (35) by the electronic control unit (11). As a result, the two devices (21, 35) can be operated while suppressing the electrical signal output from the electronic control unit (11).

According to the fourth aspect of the invention, the operating unit (29) including the piezoelectric sensor (45) for detecting the pressure of the high-pressure gas is provided. For this reason, a device operation signal can be generated based on the detection of the pressure of the high-pressure gas generated by the reaction of the gas generating agent. Thereby, the gas generation part (37) of another device (35) can be operated without operating the other device (35) by the electronic control unit (11). As a result, the two devices (21, 35) can be operated while suppressing the electrical signal output from the electronic control unit (11).

According to the fifth aspect , since the delay device is provided, the other device (35) can be operated with a time difference. Thereby, another device (35) can be operated at an optimal operation timing.

According to the sixth invention, since the operation unit (68) is provided, the device connected in series to the other device (35) by the pressure of the high pressure gas of the gas generating part (37) of the other device (35). The gas generating part (62) of (60) can be operated. That is, when the other device (35) is operated, the device (60) can be operated by using the pressure of the high-pressure gas generated from the gas generation unit (37) of the other device (35). Thereby, a several device (35,60) can be operated continuously.

According to the seventh aspect , since the delay device is provided, the device (60) connected in series to the other device (35) can be operated with a time difference. Thereby, the device (60) can be operated at an optimal operation timing.

According to the eighth aspect of the invention, since the signal distribution device (50) including the gas generation unit (53) is provided, a plurality of device operation signals are generated by the pressure of the high pressure gas in the gas generation unit (53). Can do. For this reason, each gas generation part (23,37) of this some device (21,35) can be operated, without operating a some device (21,35) by an electronic control apparatus (11). . As a result, the plurality of devices (21, 35) can be operated while suppressing the electrical signal output from the electronic control unit (11).

In the ninth aspect of the invention, the piezoelectric sensor (56) for detecting the pressure is provided. Therefore, a plurality of device operation signals can be generated based on the pressure detection. Thereby, each gas generation part (23,37) of a some device (21,35) can be operated, without operating a plurality of device (21,35) by the electronic control apparatus (11). As a result, the plurality of devices (21, 35) can be operated while suppressing the electrical signal output from the electronic control unit (11).

According to the tenth aspect of the invention, since the delay device is provided, the plurality of devices (21, 35) can be operated with a time difference. Thereby, each device can be operated at an optimal operation timing.

It is a figure which shows the state before operation | movement of the action | operation system which concerns on this Embodiment 1. FIG. It is a figure which shows the state after operation | movement of the action | operation system which concerns on this Embodiment 1. FIG. It is a figure which shows the state after operation | movement of the action | operation system which concerns on this Embodiment 2. FIG. It is a figure which shows the state after operation | movement of the action | operation system which concerns on this Embodiment 3. FIG. It is a figure which shows the state after operation | movement of the action | operation system which concerns on this Embodiment 4. It is a figure which shows the action | operation system which concerns on a prior art example.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Embodiment 1>
Embodiment 1 is an operation system according to the present invention. As shown in FIG. 1, the operating system (10) of the first embodiment includes one ECU (electric control unit) and a cutting unit (20). The operating system (10) constitutes a device operating system according to the present invention. In the first embodiment, the lower direction in FIG. 1 is referred to as “front”, and the upper direction is referred to as “rear”.

    The ECU (11) controls the operation of the first cutting device (21) and constitutes an electronic control device according to the present invention. Specifically, the ECU (11) is connected to the first cutting device (21) through the ECU signal line (12), and sends an electrical signal to the first cutting device (21) through the ECU signal line (12). The first cutting device (21) is operated. This electrical signal constitutes an electrical signal according to the present invention.

    The cutting unit (20) is a unit configured by connecting two cutting devices (21, 35). The cutting unit (20) includes a first cutting device (21) and a second cutting device (35) arranged in the front-rear direction.

    The first cutting device (21) is a cutting device that operates based on a cutting signal from the ECU (11), and constitutes one device according to the present invention. The 1st cutting device (21) is provided with the 1st casing (22), the 1st gas generating part (23), the 1st braid (26), and the operation unit (29).

    The first casing (22) is formed in a vertically long, substantially rectangular parallelepiped box member. The first casing (22) has a first installation hole (22a) extending in the width direction at substantially the center in the front-rear direction. The first installation hole (22a) has a first harness (13 ) Is inserted and installed. The first harness (13) is a current-carrying member to be cut by the first cutting device (21) according to the first embodiment. The first harness (13) is formed in a long plate shape. Inside the first casing (22), the first gas generating part (23), the first blade (26) and the hammer (31) are accommodated in order from the rear, and the first blade (26) and the hammer (31) A first harness (13) is installed between the two.

    The first gas generator (23) generates a high-pressure gas for advancing the first blade (26) to cut the first harness (13), and the gas generator according to the present invention. (23). The first gas generating section (23) includes an explosive as a gas generating agent, a first ignition section (24) for detonating the explosive, and a first gas generating chamber (25). The first ignition part (24) is constituted by a detonator, and a front end part having an explosive is exposed in the first gas generation chamber (25). With this configuration, when the explosive in the first gas generation chamber (25) explodes by the first ignition unit (24), high pressure gas is generated in the first gas generation chamber (25), and the high pressure gas is The first blade (26) is advanced by increasing the pressure in the one gas generation chamber (25).

    The first blade (26) is for receiving a high-pressure gas and moving forward in the first casing (22) to cut the first harness (13). The first blade (26) includes a first cutting part (27) whose front end is formed of a metal material (for example, steel), and a first pusher (28) to which the first cutting part (27) is attached. Yes.

    The operation unit (29) will be described later.

    The second cutting device (35) is a cutting device that operates based on the operating unit (29), and constitutes another device according to the present invention. The second cutting device (35) includes a second casing (36), a second gas generator (37), and a second blade (40).

    The second casing (36) is formed in a vertically long, substantially rectangular parallelepiped box member. The second casing (36) has a second installation hole (36a) extending in the width direction substantially at the center in the front-rear direction, and the second installation hole (36a) has a second harness (14 ) Is inserted and installed. The second harness (14) is an energization member to be cut by the second cutting device (35) according to the first embodiment. The second harness (14) is formed in a long plate shape. Inside the second casing (36), a second gas generating part (37) and a second blade (40) are accommodated in order from the rear.

    The second gas generating part (37) generates a high-pressure gas for advancing the second blade (40) to cut the second harness (14). The gas generating part according to the present invention (37). The second gas generating section (37) includes an explosive as a gas generating agent, a second ignition section (38) for detonating the explosive, and a second gas generating chamber (39). The second ignition part (38) is constituted by a detonator, and a front end part having an explosive is exposed in the second gas generation chamber (39). With this configuration, when the explosive in the second gas generation chamber (39) explodes by the second ignition unit (38), high pressure gas is generated in the second gas generation chamber (39), and the high pressure gas is The second blade (40) is advanced by increasing the pressure in the two gas generation chamber (39).

    The second blade (40) is for receiving the high pressure gas and moving forward in the second casing (36) to cut the second harness (14). The second blade (40) includes a second cutting part (41) whose front end is formed of a metal material (for example, steel), and a second pusher (42) to which the second cutting part (41) is attached. Yes.

    The said operation unit (29) operates a 2nd cutting device (35) with the pressure of the high pressure gas which generate | occur | produces in a 1st gas generation part (23). The operation unit (29) includes a hammer (31) accommodated in the first casing (22), and is provided between the first cutting device (21) and the second cutting device (35).

    The hammer (31) operates the second cutting device (35) in response to the pressure of the collision of the first blade (26) that advances, and constitutes a hammer member according to the present invention. Specifically, the hammer (31) includes a hammer pressure receiving portion (32) and a rod portion (33), and is configured to advance when the advanced first blade (26) collides with the hammer pressure receiving portion (32). Has been.

    The hammer pressure receiving part (32) is a receiving member for causing the first blade (26) to advance to collide. In the first casing (22), the hammer pressure receiving part (32) is located on the front side of the first harness (13) (the opposite side across the first blade (26) and the first harness (13)). ). For this reason, after cutting the first harness (13), the tip of the first blade (26) collides with the hammer pressure receiving part (32).

    The rod portion (33) has one end connected to the hammer pressure receiving portion (32) and the other end extending to the outside of the first casing (22). The other end of the rod part (33) is inserted into the second casing (36) and extends to the front of the second ignition part (38) of the second gas generation part (37). For this reason, when the hammer (31) moves forward, the tip of the rod portion (33) can hit the initiator of the second ignition portion (38). Thereby, the explosive in the second gas generation chamber (39) explodes, and high pressure gas is generated in the second gas generation chamber (39). When the pressure in the second gas generation chamber (39) rises due to the high pressure gas, the second blade (40) moves forward under the pressure of the high pressure gas and the second harness (14) is cut.

-Driving action-
The operation system (10) according to the first embodiment will be described. First, the cutting unit (20) according to the first embodiment is first installed such that, for example, the first harness (13) of the in-vehicle electric device penetrates the first casing (22) in the width direction. Installed by being inserted through the hole (22a), and inserted through the second installation hole (36a) so that the second harness (14) penetrates the second casing (36) in the width direction. Is done.

    The 1st cutting device (21) is installed in the state where the 1st ignition part (24) was connected to ECU (11). Then, for example, when a vehicle fire or a collision occurs, the ECU (11) sends a cutting signal which is an electric signal to the first cutting device (21). The first ignition unit (24) explodes the explosive in the first gas generation chamber (25) by inputting the cutting signal.

    As shown in FIG. 2, when the explosive explodes, high-pressure gas is generated along with the explosion, thereby increasing the pressure in the first gas generation chamber (25) and imparting forward thrust to the first blade (26). It is done. Thereby, the 1st blade (26) advances and the blade part of the 1st cutting part (27) cuts the 1st harness (13) instantly.

    When the first blade (26) further advances, the tip of the first blade (26) collides with the hammer pressure receiving portion (32) of the hammer (31), and the hammer (31) is pushed forward. When the tip of the rod part (33) hits the initiator of the second ignition part (38) by the advance of the hammer (31), the explosive in the second gas generation chamber (39) explodes. When the explosive explodes, high pressure gas is generated along with the explosion, whereby the pressure in the second gas generation chamber (39) rises, and forward thrust is given to the second blade (40). Thereby, a 2nd braid | blade (40) advances and the blade part of a 2nd cutting part (41) cut | disconnects a 2nd harness (14) instantaneously.

-Effect of Embodiment 1-
According to the first embodiment, since the operation unit (29) is provided, the second gas of the second cutting device (35) is generated by the pressure of the high-pressure gas of the first gas generating part (23) of the first cutting device (21). The generator (37) can be actuated. That is, in the conventional operation system (a) shown in FIG. 6, the electrical signals are sent from the ECU (b) to the plurality of cutting devices (c, c), respectively. However, in the present invention, only the first cutting device (21) operates based on the electrical signal of the ECU (11), and the second cutting device (35) generates the first gas from the first cutting device (21). It can be operated using the pressure of the high-pressure gas generated from the section (23). Thereby, the 1st cutting device (21) and the 2nd cutting device (35) can be operated, suppressing the electric signal outputted from ECU (11).

    Moreover, in this Embodiment 1, the operation unit (29) provided with the hammer (31) which operate | moves with the pressure of the high pressure gas of the 1st gas generation part (23) of a 1st cutting device (21) was provided. For this reason, a hammer (31) can be operated by operating the 1st gas generation part (23) of a 1st cutting device (21). Thereby, the 2nd gas generation part (37) of a 2nd cutting device (35) can be operated irrespective of ECU (11). As a result, the first cutting device (21) and the second cutting device (35) can be operated while suppressing the electrical signal output from the ECU (11).

<Embodiment 2 of the invention>
Next, Embodiment 2 of the present invention will be described. As shown in FIG. 3, the operation system (10) according to the second embodiment is different from the operation system (10) according to the first embodiment in the configuration of the operation unit (29).

    Specifically, the first cutting device (21) according to the second embodiment includes an operation unit (29) having a piezoelectric sensor (45) and a sensor signal line (47).

    When the advanced first blade (26) collides with the piezoelectric sensor (45), the operating unit (29) operates the second cutting device (35) based on the detection of the collision pressure by the piezoelectric sensor (45). It is configured to send an activation signal. The operation signal constitutes a device operation signal according to the present invention. Further, the first blade (26) constitutes an advancing member according to the present invention.

    The piezoelectric sensor (45) detects the pressure at the time of collision of the first blade (26) that advances. In the first casing (22), the piezoelectric sensor (45) is disposed on the front side of the first harness (13) (the opposite side across the first blade (26) and the first harness (13)). ). For this reason, after cutting the first harness (13), the tip of the first blade (26) collides with the piezoelectric sensor (45). And in a piezoelectric sensor (45), the pressure of a collision is converted into the operation signal which is an electrical signal.

    One end of the sensor signal line (47) is connected to the piezoelectric sensor (45), and the other end extends to the outside of the first casing (22), and the second gas generating section ( 37) is connected.

-Driving action-
Next, the operation of the operating system (10) according to the second embodiment will be described. In the operation system (10) according to the second embodiment, the first cutting device (21) is installed in a state where the first ignition unit (24) is connected to the ECU (11). Then, for example, when a vehicle fire or a collision occurs, the ECU (11) sends a cutting signal which is an electric signal to the first cutting device (21). The first ignition unit (24) explodes the explosive in the first gas generation chamber (25) by inputting the cutting signal.

    When the explosive explodes, high-pressure gas is generated along with the explosion, whereby the pressure in the first gas generation chamber (25) rises and forward thrust is given to the first blade (26). Thereby, the 1st blade (26) advances and the blade part of the 1st cutting part (27) cuts the 1st harness (13) instantly.

    Further, when the first blade (26) advances, the tip of the first blade (26) collides with the piezoelectric sensor (45). In the piezoelectric sensor (45), the pressure due to the collision is converted into an operation signal which is an electric signal. The operation unit (29) sends an operation signal to the second gas generation unit (37) of the second cutting device (35) through the sensor signal line (47). The second ignition part (38) explodes the explosive in the second gas generation chamber (39) by the input of the operation signal.

    When the explosive explodes, high pressure gas is generated along with the explosion, whereby the pressure in the second gas generation chamber (39) rises, and forward thrust is given to the second blade (40). Thereby, a 2nd braid | blade (40) advances and the blade part of a 2nd cutting part (41) cut | disconnects a 2nd harness (14) instantaneously.

-Effect of Embodiment 2-
In the second embodiment, an operation unit (29) including a piezoelectric sensor (45) for detecting pressure is provided. For this reason, an operation signal can be generated based on detection of pressure. Thereby, the 2nd gas generation part (37) of a 2nd cutting device (35) can be operated irrespective of ECU (11). As a result, the first cutting device (21) and the second cutting device (35) can be operated while suppressing the electrical signal output from the ECU (11).

    Further, since the first blade (26) is caused to collide with the piezoelectric sensor (45), the pressure of the collision of the first blade (26) can be detected. For this reason, an operation signal can be generated based on detection of a collision pressure. Thereby, the 2nd gas generation part (37) of a 2nd cutting device (35) can be operated irrespective of ECU (11). As a result, the first cutting device (21) and the second cutting device (35) can be operated while suppressing the electrical signal output from the ECU (11). Other configurations, operations and effects are the same as those of the first embodiment.

Embodiment 3 of the Invention
Next, a third embodiment of the present invention will be described. As shown in FIG. 4, the operating system (10) according to the third embodiment includes a signal distribution device (50) instead of the operating system (10) according to the first embodiment.

    Specifically, the operation system (10) according to the third embodiment includes an ECU (11), a signal distribution device (50), a first cutting device (21), and a second cutting device (35). Each of the first cutting device (21) and the second cutting device (35) constitutes one of a plurality of devices according to the present invention. And since the structure of a 1st and 2nd cutting device (21,35) is the same as that of the said Embodiment 1, description is abbreviate | omitted.

    The ECU (11) controls the operation of the signal distribution device (50) and constitutes an electronic control device according to the present invention. Specifically, the ECU (11) is connected to the signal distribution device (50) through the ECU signal line (12), and sends an electric signal to the signal distribution device (50) through the ECU signal line (12). Activate the dispensing device (50). This electrical signal constitutes an electrical signal according to the present invention.

    The signal distribution device (50) is a device that operates based on an electrical signal from the ECU (11). Further, the signal distribution device (50) operates both the first and second cutting devices (21, 35) based on pressure detection by the piezoelectric sensor (56). Specifically, the signal distribution device (50) is provided between the ECU (11) and the first and second cutting devices (21, 35). When the piston (52) collides with the piezoelectric sensor (56), the signal distribution device (50) detects the collision pressure by the piezoelectric sensor (56), and the first and second cutting devices (21, 35). Is configured to send an activation signal to activate the. The operation signal constitutes a device operation signal according to the present invention. The signal distributor (50) includes a casing (51), a piston (52), a gas generator (53), a piezoelectric sensor (56), a first signal line (57), and a second signal line (58). .

    The casing (51) is formed in a substantially rectangular parallelepiped box member. Inside the casing (51), a gas generating part (53), a piston (52), and a piezoelectric sensor (56) are accommodated in order from the rear.

    The gas generator (53) generates high-pressure gas for advancing the piston (52). The gas generating part (53) includes an explosive as a gas generating agent, an ignition part (54) for detonating the explosive, and a gas generating chamber (55). The ignition part (54) is constituted by a detonator, and a front end portion having an explosive is exposed in the gas generation chamber (55). The rear end portion of the ignition portion (54) is connected to the ECU signal line (12). With this configuration, when the explosive in the gas generation chamber (55) explodes by the ignition part (54), high pressure gas is generated in the gas generation chamber (55), and the high pressure gas is generated in the gas generation chamber (55). The piston (52) is moved forward by increasing the pressure of.

    The piston (52) is for receiving high pressure gas and moving forward in the casing (51) to apply pressure to the piezoelectric sensor (56).

    The piezoelectric sensor (56) detects the pressure at the time of collision of the advancing piston (52). The piezoelectric sensor (56) is installed in front of the piston (52) in the casing (51). When the advanced piston (52) collides, the piezoelectric sensor (56) detects the pressure of the collision and converts it into an operation signal which is an electric signal. The operating signal constitutes a device operating signal according to the present invention.

    The first signal line (57) has one end connected to the signal distribution device (50) and the other end connected to the first cutting device (21). The second signal line (58) has one end connected to the signal distribution device (50) and the other end connected to the second cutting device (35).

-Driving action-
Next, the operation of the actuation system (10) according to the third embodiment will be described. First, in the first cutting device (21) according to the third embodiment, for example, the first harness (13) of an in-vehicle electric device is passed through the first casing (22) in the width direction thereof. It is installed by being inserted through one installation hole (22a). In the second cutting device (35), the second harness (14) is inserted through the second installation hole (36a) so as to penetrate the second casing (36) in the width direction. .

    The signal distribution device (50) is installed in a state where the ignition unit (54) is connected to the ECU (11). Then, for example, when a vehicle fire or a collision occurs, the ECU (11) sends an electrical signal to the signal distribution device (50). The ignition part (54) explodes the explosive in the gas generation chamber (55) by the input of the electric signal.

    When the explosive explodes, high-pressure gas is generated along with the explosion, whereby the pressure in the gas generation chamber (55) rises, and forward thrust is given to the piston (52). The piezoelectric sensor (56) converts the pressure caused by the collision into an actuation signal that is an electrical signal. The signal distribution device (50) sends the operation signal to the first and second gas generating parts (23, 37) of the first and second cutting devices (21, 35) by the first and second signal lines (57, 58). Send to. The first and second ignition parts (24, 38) explode the explosives in the first and second gas generation chambers (25, 39) by the input of the operation signal.

    In the first cutting device (21), when the explosive explodes, high-pressure gas is generated along with the explosion, whereby the pressure in the first gas generation chamber (25) rises and the first blade (26) thrusts forward. Is given. Thereby, the 1st blade (26) advances and the blade part of the 1st cutting part (27) cuts the 1st harness (13) instantly.

    Similarly, in the second cutting device (35), when the explosive explodes, high pressure gas is generated along with the explosion, whereby the pressure in the second gas generation chamber (39) rises and moves forward to the second blade (40). Thrust is given. Thereby, a 2nd braid | blade (40) advances and the blade part of a 2nd cutting part (41) cut | disconnects a 2nd harness (14) instantaneously.

-Effect of Embodiment 3-
According to the third embodiment, since the signal distribution device (50) including the gas generation unit (53) is provided, a plurality of operation signals can be generated by the pressure of the high pressure gas in the gas generation unit (53). . For this reason, each gas generation part (23,37) of this some cutting device (21,35) can be operated irrespective of ECU (11). As a result, the plurality of cutting devices (21, 35) can be operated while suppressing the electrical signal output from the ECU (11).

    In the third embodiment, the piezoelectric sensor (56) for detecting the pressure of the collision of the piston (52) is provided. Therefore, a plurality of actuation signals can be generated based on the collision pressure. Thereby, each gas generation part (23,37) of a some cutting device (21,35) can be operated, without operating a some cutting device (21,35) by ECU (11). As a result, the plurality of cutting devices (21, 35) can be operated while suppressing the electrical signal output from the ECU (11). Other configurations, operations, and effects are the same as those in the first or second embodiment.

<Embodiment 4 of the Invention>
Next, a fourth embodiment of the present invention will be described.

    As shown in FIG. 5, the operating system (10) according to the fourth embodiment is different from the operating system (10) according to the second embodiment in the configuration of the cutting unit (20).

    Specifically, as shown in FIG. 5, the cutting unit (20) according to the fourth embodiment includes first to third cutting devices (21, 35, 60) connected in series. In addition, since the structure of a 1st cutting device (21) is the same as that of Embodiment 1 and Embodiment 2, description is abbreviate | omitted. Moreover, the 2nd cutting device (35) which concerns on this Embodiment 4 comprises the other device which concerns on this invention.

    The third cutting device (60) is a cutting device that operates based on the operation unit (68), and constitutes a device according to the present invention. The third cutting device (60) is connected in series to the second cutting device (35) via the operating unit (68). The third cutting device (60) includes a third casing (61), a third gas generator (62), and a third blade (65).

    The third casing (61) is formed in a vertically long, substantially rectangular parallelepiped box member. The third casing (61) is formed with a third installation hole (61a) extending in the width direction at a substantially center in the front-rear direction. The third installation hole (61a) has a third harness (15 ) Is inserted and installed. The third harness (15) is an energization member to be cut by the third cutting device (60) according to the fourth embodiment. The third harness (15) is formed in a long plate shape. Inside the third casing (61), a third gas generator (62) and a third blade (65) are accommodated in order from the rear.

    The third gas generator (62) generates a high-pressure gas for advancing the third blade (65) to cut the third harness (15). The gas generator according to the present invention (62). The third gas generating section (62) includes an explosive as a gas generating agent, a third ignition section (63) and a third gas generating chamber (64) for detonating the explosive. The third ignition part (63) is constituted by a detonator, and a front end part having an explosive is exposed in the third gas generation chamber (64). With such a configuration, when the explosive in the third gas generation chamber (64) explodes by the third ignition section (63), high pressure gas is generated in the third gas generation chamber (64), and the high pressure gas is The third blade (65) is advanced by increasing the pressure in the three gas generation chamber (64).

    The third blade (65) is for receiving the high pressure gas and moving forward in the third casing (61) to cut the third harness (15). The third blade (65) includes a third cutting portion (66) whose front end is formed of a metal material (for example, steel), and a third pusher (67) to which the third cutting portion (66) is attached. Yes.

    The second cutting device (35) according to the fourth embodiment has an operation unit (68) instead of the second cutting device (35) according to the first embodiment. Specifically, the second cutting device (35) according to the fourth embodiment includes an operating unit (68) having a piezoelectric sensor (69) and a sensor signal line (70).

    When the advanced second blade (40) collides with the piezoelectric sensor (69), the operating unit (68) operates the third cutting device (60) based on the detection of the collision pressure by the piezoelectric sensor (69). It is configured to send an activation signal.

    The piezoelectric sensor (69) detects the pressure at the time of the collision of the advancing second blade (40). In the second casing (36), the piezoelectric sensor (69) is located on the front side of the second harness (14) (the opposite side across the second blade (40) and the second harness (14)). ). For this reason, after cutting the second harness (14), the tip of the second blade (40) collides with the piezoelectric sensor (69). Then, the piezoelectric sensor (69) converts the collision pressure into an operation signal that is an electrical signal.

    One end of the sensor signal line (70) is connected to the piezoelectric sensor (69), and the other end extends to the outside of the second casing (36), and the third gas generating part ( 62) is connected.

-Driving action-
Next, the operation of the actuation system (10) according to the fourth embodiment will be described. In the operation system (10) according to the fourth embodiment, the first cutting device (21) is installed in a state where the first ignition unit (24) is connected to the ECU (11). Then, for example, when a vehicle fire or a collision occurs, the ECU (11) sends a cutting signal which is an electric signal to the first cutting device (21). The first ignition unit (24) explodes the explosive in the first gas generation chamber (25) by inputting the cutting signal.

    When the explosive explodes, high-pressure gas is generated along with the explosion, whereby the pressure in the first gas generation chamber (25) rises and forward thrust is given to the first blade (26). Thereby, the 1st blade (26) advances and the blade part of the 1st cutting part (27) cuts the 1st harness (13) instantly.

    Further, when the first blade (26) advances, the tip of the first blade (26) collides with the piezoelectric sensor (45). In the piezoelectric sensor (45), the pressure due to the collision is converted into an operation signal which is an electric signal. The operation unit (29) sends an operation signal to the second gas generation unit (37) of the second cutting device (35) through the sensor signal line (47). The second ignition part (38) explodes the explosive in the second gas generation chamber (39) by the input of the operation signal.

    When the explosive explodes, high pressure gas is generated along with the explosion, whereby the pressure in the second gas generation chamber (39) rises, and forward thrust is given to the second blade (40). Thereby, a 2nd braid | blade (40) advances and the blade part of a 2nd cutting part (41) cut | disconnects a 2nd harness (14) instantaneously.

    Next, when the second blade (40) further advances, the tip of the second blade (40) collides with the piezoelectric sensor (69). In the piezoelectric sensor (69), the pressure due to the collision is converted into an operation signal which is an electric signal. The operation unit (68) sends an operation signal to the third gas generation unit (62) of the third cutting device (60) through the sensor signal line (70). In response to the input of the operation signal, the third ignition unit (63) explodes the explosive in the third gas generation chamber (64).

    When the explosive explodes, high pressure gas is generated along with the explosion, whereby the pressure in the third gas generation chamber (64) rises, and forward thrust is given to the third blade (65). Thereby, the 3rd blade (65) advances and the blade part of the 3rd cutting part (66) cuts the 3rd harness (15) instantly.

-Effect of Embodiment 4-
According to the fourth embodiment, since the operation unit (68) is provided, the third gas generation unit (62) connected in series can be operated by the pressure of the high pressure gas of the second gas generation unit (37). That is, by operating the second cutting device (35), the third cutting device (60) can be operated using the pressure of the high-pressure gas generated from the second gas generation unit (37). Thereby, a some cutting device (21,35,60) can be operated continuously. Other configurations, operations and effects are the same as those of the second embodiment.

<Other embodiments>
This invention is good also as following structures about the said Embodiment 1-4.

    In the first to fourth embodiments, the cutting device is used as the device according to the present invention. However, this is merely an example, and the present invention can be applied to any device that operates using a gas generating agent such as an airbag. can do.

    In the first to third embodiments, two devices (two cutting devices) are operated. However, the present invention is not limited to this, and can be applied to three or more devices. Further, in Embodiments 1 to 4, the cutting device is used as a device, but the present invention is not limited to this, and the present invention can also be applied by combining different types of devices.

    In the second embodiment or the fourth embodiment, one device (second cutting device (35)) is connected to the first cutting device (21). However, the present invention is not limited to this. A plurality of sensor signal lines may be extended from one cutting device (21), and the first cutting device (21) and a plurality of devices may be connected.

    Next, in Embodiment 3, the piston (52) is caused to collide with the piezoelectric sensor (56). However, the present invention is not limited to this, and the gas generation chamber (55) is used without using the piston (52). Alternatively, the pressure of the high-pressure gas may be directly applied to the piezoelectric sensor (56), the pressure may be detected, and the detected pressure may be converted into an operation signal that is an electrical signal.

    According to this embodiment, an operation signal that is a device operation signal can be generated based on the detection of the pressure of the high-pressure gas generated by the reaction of the gas generating agent in the gas generation chamber (55). Thereby, the gas generation part (23, 37) of each cutting device (21, 35) can be operated without operating the cutting device (21, 35) by the ECU (11). As a result, the plurality of cutting devices (21, 35) can be operated while suppressing the electrical signal output from the ECU (11).

    In the third embodiment, the signal distribution device (50) in FIG. 4 and the first and second cutting devices (21, 35) (that is, the first signal line (57) and the second signal line). (58)) may be provided with a delay device (not shown). Therefore, the first cutting device (21) and the second cutting device (35) can be operated with a time difference. That is, as described above, the device to which the present invention is applied is not limited to a cutting apparatus, and can be applied to various devices using a gas generating agent. Can be operated with.

    In the fourth embodiment, a delay device (not shown) may be provided for each (or any one) of the sensor signal lines (47, 70) in FIG. By carrying out like this, the time which operates the 2nd cutting device (35) or the 3rd cutting device (60) can be delayed. Thereby, both the cutting devices (35, 60) can be operated at an optimal timing. In the second embodiment, a delay device (not shown) may be provided on the sensor signal line (47) in FIG.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a device operating system that operates a plurality of devices.

11 ECU
21 First cutting device 23 First gas generating unit 26 First blade 29 Actuating unit 31 Hammer 35 Second cutting device 37 Second gas generating unit 45 Piezoelectric sensor 50 Signal distribution device 53 Gas generating unit 60 Third cutting device 62 Third Gas generating part 68 Actuating unit 69 Piezoelectric sensor

Claims (10)

Two devices (21, 35) each having a gas generating part (23, 37) that generates a high-pressure gas by reaction of the gas generating agent, the gas generating part (23, 37) of both devices (21, 35) A device operating system for operating
The electronic control device (11) that outputs an electric signal for operating the gas generating part (23) of one of the two devices (21, 35) and the high pressure generated by the reaction of the gas generating agent An operating unit (29) for operating the gas generating part (37) of another device (35) by the pressure of the gas ,
The operating unit (29) includes a hammer member (31) that is operated by the pressure of the high-pressure gas generated by the reaction of the gas generating agent, and the gas generation of the other device (35) by the operation of the hammer member (31). A device actuation system configured to actuate the section (37) . Two devices (21, 35) each having a gas generating part (23, 37) that generates a high-pressure gas by reaction of the gas generating agent, the gas generating part (23, 37) of both devices (21, 35) A device operating system for operating
The electronic control device (11) that outputs an electric signal for operating the gas generating part (23) of one of the two devices (21, 35) and the high pressure generated by the reaction of the gas generating agent An operating unit (29) for operating the gas generating part (37) of another device (35) by the pressure of the gas,
The operation unit (29) includes a piezoelectric sensor (45) for detecting pressure, and is configured to operate the gas generation unit (37) of the other device (35) by a device operation signal generated based on the detection. device actuation system according to claim <br/> that it is. In claim 2 ,
It has an advancing member (26) that advances in a predetermined advancing direction with the high-pressure gas generated by the reaction of the gas generating agent,
The device operating system, wherein the piezoelectric sensor (45) is configured to detect a pressure of a collision of the advancing member (26). In claim 2 ,
The device operating system, wherein the piezoelectric sensor (45) is configured to detect a pressure of a high-pressure gas generated by a reaction of a gas generating agent. In any one of Claims 2-4 ,
A device operating system, wherein a delay device for shifting the operation timing of the other device (35) is provided between the piezoelectric sensor (45) and the other device (35). In any one of Claims 1-5 ,
A device (60) having at least a gas generator (62) is connected in series to the other device (35) via an operating unit (68),
The operating unit (68) operates the gas generating part (62) of the device (60) by the pressure of the high pressure gas generated by the reaction of the gas generating agent of the gas generating part (37) of the other device (35). A device actuation system, characterized in that the device actuation system is configured. In claim 6 ,
The operation unit (68) includes a piezoelectric sensor (69) that detects pressure, and is configured to operate the gas generation unit (62) of the device (60) by a device operation signal generated based on the detection.
A device operating system, characterized in that a delay device for shifting the operation timing of the device (60) is provided between the piezoelectric sensor (69) and the device (60). Each includes a plurality of devices (21, 35) each having a gas generation section (23, 37) for generating a high-pressure gas by reaction of a gas generating agent, and the gas generation sections (23, 35) of the plurality of devices (21, 35) 37) a device operating system for operating on the basis of an electrical signal from the electronic control device (11),
Each device (21, 35) has a gas generator (53) that operates based on the electrical signal from the electronic control unit (11), and the pressure of the high-pressure gas generated in the gas generator (53). And a signal distribution device (50) for generating a device operation signal for operating the gas generation unit (23, 37) of the gas generator and distributing the device operation signal to the devices (21, 35). Device operating system. In claim 8 ,
The signal distribution device (50) includes a piezoelectric sensor (56) that detects pressure, and is configured to generate the device activation signal based on the detection. In claim 8 or 9 ,
Device operation characterized in that a delay device for shifting the operation timing of the plurality of devices (21, 35) is provided between the signal distribution device (50) and each device (21, 35). system.

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