CN220465832U

CN220465832U - Electric shock bottle opening device

Info

Publication number: CN220465832U
Application number: CN202322113095.5U
Authority: CN
Inventors: 龚松洁; 张旭; 谭学通; 薛友海
Original assignee: Xiangyang Hongwei Aircraft Co Ltd
Current assignee: Xiangyang Hongwei Aircraft Co Ltd
Priority date: 2023-08-07
Filing date: 2023-08-07
Publication date: 2024-02-09
Anticipated expiration: 2033-08-07

Abstract

The utility model discloses an electric shock bottle opening device, which comprises a tube body, a puncture needle, a bottle body, an elastic piece and a generator, wherein the tube body comprises a mounting tube, and an air outlet is formed in the mounting tube; the puncture needle is arranged in the mounting tube in a sealing sliding manner, so that a first mounting cavity and a second mounting cavity which are not communicated with each other are separated in the mounting tube. The beneficial effects of the utility model are as follows: this bottle opening device has stronger suitability to need not to arrange extra force application device in unmanned aerial vehicle and can open the gas cylinder, more adapt to unmanned aerial vehicle to the strict requirement of airborne equipment's weight and space, guaranteed unmanned aerial vehicle's airborne equipment and have less weight and space, can be widely used on unmanned aerial vehicle, in addition, compare in mechanical type bottle opening device, adopt this bottle opening device to open the back, the felting needle shifts out the bottleneck, and the air current channel sectional area of bottleneck equals the gas cylinder diaphragm diameter, and the gas velocity of flow is faster.

Description

Electric shock bottle opening device

Technical Field

The utility model relates to the technical field of bottle opening devices of cushioning air bags of unmanned aerial vehicles and pre-inflating air cylinders, in particular to a bottle opening device for electric shock.

Background

The landing of the unmanned aerial vehicle mainly comprises two modes of skid buffering and airbag buffering. When the airbag is adopted for buffering (such as an unmanned aerial vehicle active parachute opening recovery device and an unmanned aerial vehicle disclosed in application number 201910631252.7), the airbag on the unmanned aerial vehicle needs to be inflated in advance. The inflation gas source generally adopts two high-pressure gas cylinders, namely a reusable gas cylinder and a disposable pre-inflation gas cylinder used on a small unmanned aerial vehicle.

The pre-inflated gas bottle mainly comprises pre-inflated nitrogen and carbon dioxide gas, a bottle mouth is sealed by a metal film, when the bottle is used, a puncture needle of the mechanical bottle opening device punctures the film of the gas bottle, the gas bottle is opened, gas in the gas bottle is released, and the gas bag is inflated through a pipeline.

The prior mechanical bottle opening device comprises a tube body 100 ', a bottle body 200', a needle 300 ', a limiting mechanism 400' and an elastic piece 500 ', wherein the tube body 100' comprises a first mounting tube 110 'and a second mounting tube 120', the first mounting tube 110 'is provided with an air outlet 111', the second mounting tube 120 'extends along the length direction vertical to the first mounting tube 110', one end of the second mounting tube 120 'is communicated with the first mounting tube 110', the bottle body 200 'is arranged in the bottle mouth of the first mounting tube 110', the needle 300 'is arranged in the first mounting tube 110' in a sliding way, the needle 300 'is provided with an air flow channel 310', the outer side wall of the needle 300 'is provided with a clamping groove 320', one end of the second mounting tube 120 'is communicated with the first mounting tube 110', one end of the limiting mechanism 400 is clamped with the needle 300 ', so that the pricking pin 300' is far away from the bottle mouth of the bottle body 200 ', the elastic piece 500' is arranged in the first mounting tube 110 ', two ends of the elastic piece 500' are fixedly connected with the first mounting tube 110 'and the pricking pin 300' respectively, so that the pricking pin 300 'is inserted into the bottle body 200', when the pricking pin 300 'is inserted into the bottle body 200', the inlet end of the air flow channel 310 'is communicated with the bottle body 200', the outlet end of the air flow channel 310 'is communicated with the air outlet 111', the limiting mechanism 400 'comprises a steel ball 410', a top block 420 'and a pulling pin 430', the steel ball 410 'is clamped in the clamping groove 320', the top block 420 'is arranged in the second mounting tube 120' in a sliding manner, and can be abutted against one end of the steel ball 410 'along the length of the second mounting tube 120', one end of the pull pin 430 ' is disposed in the second mounting tube 120 ' and abuts against the other end of the top block 420 ', and the other end of the pull pin 430 ' extends out of the second mounting tube 120 '. Because the mechanical bottle opening device generally adopts spring compression energy storage, the spring compression is released when the mechanical bottle opening device is used, and the spring release pushes the puncture needle to puncture the membrane of the gas bottle so as to open the gas bottle. The compression of the spring adopts steel balls, ejector blocks and pulling pins to limit the puncture needles, compression energy storage of the spring is realized through the puncture needle compression spring, after the pulling pins are pulled away, the ejector blocks release position constraint and slide along the length direction of the second mounting tube, after the steel balls lose the constraint of the ejector blocks, the steel balls are removed from clamping grooves of the puncture needles, so that the spring is decompressed, and as the membrane of the gas cylinder is punctured, the tip of the puncture needle is left in the gas cylinder under the pressure action of the spring, and gas in the gas cylinder flows out along a gas flow channel in the puncture needle and inflates the air bag.

In the mechanical bottle opening device, since the bottle can be opened only by applying a pulling force to the pulling pin in a specified direction when the pulling pin is pulled, the mode has a certain limitation, and since an additional force application device is required to be arranged in the unmanned aerial vehicle to open the bottle, the unmanned aerial vehicle has strict requirements on the weight and the space of the airborne equipment, the additional force application device can increase the weight and the space of the equipment, and the mechanical bottle opening device cannot be widely used on the unmanned aerial vehicle. In addition, after the membrane of the gas cylinder is pierced, the puncture needle is left in the gas cylinder, the sectional area of the gas flow channel at the bottle mouth is smaller than the diameter of the membrane of the gas cylinder, the outflow of gas is slowed down, and the flow speed of the gas flow is slower.

Disclosure of Invention

The utility model aims to overcome the technical defects, and provides a bottle opening device for electric shock, which solves the problems that in the prior art, in a mechanical bottle opening device, a bottle can be opened only by applying a pulling force to a pulling pin in a specified direction when the pulling pin is pulled, so that the mode has certain limitation, and in addition, an additional force application device is required to be arranged in an unmanned aerial vehicle to open the bottle, the unmanned aerial vehicle has strict requirements on the weight and the space of airborne equipment, the additional force application device can increase the weight and the space of the equipment, and the mechanical bottle opening device cannot be widely used on the unmanned aerial vehicle. In addition, after the membrane of the gas cylinder is pierced, the puncture needle is left in the gas cylinder, the sectional area of the gas flow channel at the bottle mouth is smaller than the diameter of the membrane of the gas cylinder, and the technical problem of low gas flow rate due to the outflow of gas is solved.

In order to achieve the technical purpose, the technical scheme of the utility model provides an electric shock bottle opening device, which comprises:

the pipe body comprises a mounting pipe, and an air outlet is formed in the mounting pipe;

the puncture needle is arranged in the mounting pipe in a sealing sliding manner so as to separate a first mounting cavity and a second mounting cavity which are not communicated with each other in the mounting pipe;

the bottle mouth of the bottle body is arranged in the second mounting cavity and faces the pricker;

the elastic piece is arranged between the puncture needle and the bottle body, two ends of the elastic piece are respectively and fixedly connected with the mounting pipe and the puncture needle, so that the puncture needle is far away from the bottle mouth of the bottle body, and when the puncture needle is far away from the bottle mouth of the bottle body, the air outlet is communicated with the second mounting cavity;

the generator is arranged in the first installation cavity and used for generating instantaneous gas so as to push the puncture needle to be inserted into the bottle body, and when the puncture needle is inserted into the bottle body, the air outlet is communicated with the first installation cavity.

Further, the puncture needle comprises a needle seat and a needle head, the needle seat is arranged in the mounting tube in a sealing sliding manner, and the needle head is arranged in the second mounting cavity and is fixed on the needle seat.

Further, the side wall of the needle seat is provided with a plurality of vent holes with one ends communicated with the first installation cavity in a circumferential direction.

Further, when the needle is inserted into the bottle body, the other end of at least one of the exhaust holes is communicated with the air outlet.

Further, the pipe body further comprises a partition plate, the partition plate is fixedly arranged in the installation pipe, the partition plate and the needle seat are used for sequentially separating a first installation cavity, a second installation cavity and a third installation cavity in the installation pipe, and through holes for communicating the second installation cavity with the third installation cavity are formed in the partition plate.

Furthermore, both ends of the installation tube are provided with openings.

Further, the bottle mouth of the bottle body is arranged in the third mounting cavity and faces the through hole.

Further, the generator is an electric firing head, which is electrically connected with the unmanned aerial vehicle via a cable.

Further, the elastic piece is a spring, the spring is arranged in the second installation cavity and sleeved outside the needle head, one end of the spring is fixedly connected with the partition board, and the other end of the spring is fixedly connected with the needle seat.

Further, the pipe body further comprises an air flow pipe, two ends of the air flow pipe are respectively provided with an opening, one end of the air flow pipe is fixedly connected with the mounting pipe and communicated with the air outlet, and the other end of the air flow pipe is communicated with the air bag.

Compared with the prior art, the utility model has the beneficial effects that: when in use, the air outlet is communicated with the air bag, a large amount of air can be instantaneously generated by operating the generator, the air can push the puncture needle to be inserted into the bottle body, so that the membrane at the bottle mouth of the bottle body can be punctured by the puncture needle, at the moment, the elastic piece is in a compressed state under the extrusion of the puncture needle, because the air outlet is communicated with the first installation cavity when the puncture needle is inserted into the bottle body, a large amount of air in the first installation cavity can be discharged into the air bag along the air outlet, the pressure in the first installation cavity is restored to an initial state, the elastic piece releases the compressed elastic potential energy, the puncture needle is restored to an initial position under the simultaneous action of the elastic piece and the air bottle, at the moment, the puncture needle is moved out and is far away from the bottle mouth of the bottle body, and the air outlet is communicated with the second installation cavity, the gas in the bottle can get into the gasbag along second installation cavity, gas outlet, realize the inflation to the gasbag, compare in traditional mode that need apply pulling force to pulling out the round pin and just can open the gas cylinder according to prescribed direction, this bottle opening device has stronger suitability, and need not arrange extra force application device in unmanned aerial vehicle and can open the gas cylinder, more adapt to unmanned aerial vehicle and to the strict requirement of airborne equipment's weight and space, unmanned aerial vehicle's airborne equipment has been guaranteed and has less weight and space, can be widely used on unmanned aerial vehicle, in addition, compare in mechanical type bottle opening device, after adopting this bottle opening device to open the bottle, the felting needle shifts out the bottleneck, the air current channel cross section of bottleneck equals the gas cylinder diaphragm diameter, the gas velocity of flow is faster.

Drawings

FIG. 1 is a schematic view of a prior art mechanical bottle opening device;

FIG. 2 is a schematic view of the mechanical bottle opener of FIG. 1 as the spike pierces the bottle membrane;

fig. 3 is a schematic structural view of a shock bottle opening device according to the present utility model;

FIG. 4 is a schematic view of the shock-absorbing device of FIG. 3 when the spike pierces the membrane of the bottle body;

FIG. 5 is a schematic view of the shock-absorbing device of FIG. 4, after the spike pierces the membrane of the bottle body and the spike is reset;

in the figure: 100 ' -pipe body, 110 ' -first installation tube, 111 ' -gas outlet, 120 ' -second installation tube, 200 ' -bottle body, 300 ' -felting needle, 310 ' -gas flow channel, 320 ' -clamping groove, 400 ' -limit mechanism, 410 ' -steel ball, 420 ' -top block, 430 ' -pulling pin, 500 ' -elastic piece, 100-pipe body, 110-installation tube, 111-gas outlet, 112-first installation cavity, 113-second installation cavity, 114-third installation cavity, 120-baffle, 121-through hole, 130-gas flow tube, 200-felting needle, 210-needle seat, 211-exhaust hole, 220-needle head, 300-bottle body, 400-elastic piece and 500-generator.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The utility model provides an electric shock bottle opening device, the structure of which is shown in fig. 3 and 4, comprising a tube body 100, a puncture needle 200, a bottle body 300, an elastic piece 400 and a generator 500, wherein the tube body 100 comprises a mounting tube 110, and an air outlet 111 is arranged on the mounting tube 110; the puncture needle 200 is hermetically and slidably arranged in the mounting tube 110 to separate a first mounting cavity 112 and a second mounting cavity 113 which are not communicated with each other in the mounting tube 110; the bottle mouth of the bottle body 300 is arranged in the second mounting cavity 113 and faces the pricking pin 200; the elastic member 400 is disposed between the spike 200 and the bottle 300, and two ends of the elastic member are fixedly connected with the mounting tube 110 and the spike 200, respectively, so that the spike 200 is away from the bottle mouth of the bottle 300, and when the spike 200 is away from the bottle mouth of the bottle 300, the air outlet 111 is communicated with the second mounting cavity 113; the generator 500 is disposed in the first mounting cavity 112, and is configured to generate a transient gas to push the lancet 200 into the bottle 300, and when the lancet 200 is inserted into the bottle 300, the air outlet 111 communicates with the first mounting cavity 112.

In use, the air outlet 111 is communicated with the air bag, by operating the generator 500, a large amount of air can be instantaneously generated by the generator 500, the air can push the puncture needle 200 to be inserted into the bottle 300, so that the membrane at the bottle mouth of the bottle 300 can be punctured by the puncture needle 200, at the moment, the elastic member 400 is in a compressed state under the extrusion of the puncture needle 200, since the air outlet 111 is communicated with the first mounting cavity 112 when the puncture needle 200 is inserted into the bottle 300, a large amount of air in the first mounting cavity 112 can be discharged into the air bag along the air outlet 111, the pressure in the first mounting cavity 112 is restored to an initial state, the elastic member 400 releases the compressed elastic potential energy, the puncture needle 200 is restored to an initial position under the simultaneous action of the elastic member 400 and the air bottle air, at the moment, the puncture needle 200 moves out and is far away from the bottle mouth of the bottle body 300, the air outlet 111 is communicated with the second installation cavity 113, air in the bottle body 300 can enter the air bag along the second installation cavity 113 and the air outlet 111, and the air bag is inflated, compared with the traditional mode that the air bottle can be opened only by applying pulling force to the pulling pin according to the specified direction, the bottle opening device has stronger applicability, the air bottle can be opened without arranging an additional force application device in the unmanned aerial vehicle, the strict requirements of the unmanned aerial vehicle on the weight and the space of the airborne equipment are met, the airborne equipment of the unmanned aerial vehicle is ensured to have smaller weight and space, the unmanned aerial vehicle can be widely used, in addition, compared with the mechanical bottle opening device, after the bottle opening device is adopted, the puncture needle 200 moves out, the air flow channel cross section area of the bottle mouth is equal to the diameter of the air bottle, the gas flow rate is relatively fast.

As a preferred embodiment, referring to fig. 3, the spike 200 includes a needle holder 210 and a needle 220, wherein the needle holder 210 is slidably and sealingly disposed in the mounting tube 110, so that the first mounting cavity 112 and the second mounting cavity 113 are not communicated with each other through the needle holder 210, and the needle 220 is disposed in the second mounting cavity 113 and is fixed on the needle holder 210, so that a membrane at a bottleneck of the bottle 300 is conveniently pierced by the needle 220.

As a preferred embodiment, referring to fig. 3, a plurality of vent holes 211 are circumferentially formed in the sidewall of the needle holder 210, each of which has one end connected to the first mounting cavity 112, so that after the membrane is pierced, the gas in the first mounting cavity 112 can be released through the vent holes 211 and the vent holes 111, and the pressure in the first mounting cavity 112 can be released.

As a preferred embodiment, referring to fig. 4, when the needle 220 is inserted into the bottle 300, the other end of at least one of the vent holes 211 is communicated with the air outlet 111, so that the air in the first mounting chamber 112 can be released through the vent hole 211 after the membrane is pierced to communicate with the air outlet 111, thereby releasing the pressure in the first mounting chamber 112.

As a preferred embodiment, please refer to fig. 3, the tube body 100 further includes a partition board 120, the partition board 120 is fixedly disposed in the mounting tube 110, the partition board 120 and the needle seat 210 are used for sequentially separating the mounting tube 110 into a first mounting cavity 112, a second mounting cavity 113 and a third mounting cavity 114, a through hole 121 for communicating the second mounting cavity 113 and the third mounting cavity 114 is formed in the partition board 120, so that one end of the elastic member 400 is conveniently fixed on the partition board 120, and a bottleneck of the bottle body 300 is conveniently abutted against the partition board 120, so that a part of gas in the bottle body 300 enters the third mounting cavity 114 after the membrane is pierced.

As a preferred embodiment, referring to fig. 3 and 4, both ends of the mounting tube 110 are provided with openings, so as to facilitate the mounting of the bottle 300 and the generator 500.

As a preferred embodiment, referring to fig. 3, the bottle mouth of the bottle 300 is disposed in the third mounting cavity 114 and faces the through hole 121, so as to facilitate the mounting of the bottle 300, and also facilitate the bottle mouth of the bottle 300 to abut against the partition board 120, so as to avoid that part of the gas in the bottle 300 enters the third mounting cavity 114 after the membrane is pierced, and is discharged to the outside of the mounting tube 110 along the opening at the end of the mounting tube 110, thereby wasting the gas in the bottle 300.

As a preferred embodiment, please refer to fig. 3 and 4, the generator 500 is an electric ignition head, the electric ignition head is electrically connected with the unmanned aerial vehicle via a cable, a large amount of gas is generated after the electric ignition head is electrified, the electric ignition head is used as a working member, and the bottle opening and the needle 200 returning are completed by using the pressure of the gas, so that the rapid inflation and the adaptability enhancement are realized.

As a preferred embodiment, referring to fig. 4 and 5, the elastic member 400 is a spring, the spring is disposed in the second mounting cavity 113 and sleeved outside the needle 220, one end of the spring is fixedly connected with the partition board 120, and the other end of the spring is fixedly connected with the needle seat 210, so that when the spring is pressed by the needle seat 210, the spring can store compression elastic potential energy, and when the gas in the first mounting cavity 112 is released, the needle seat 210 can be restored to the initial position under the simultaneous actions of the elasticity of the spring and the gas of the gas cylinder.

As a preferred embodiment, referring to fig. 4 and 5, the tube body 100 further includes an air flow tube 130, two ends of the air flow tube 130 are respectively provided with an opening, one end of the air flow tube 130 is fixedly connected with the mounting tube 110 and is communicated with the air outlet 111, and the other end of the air flow tube 130 is used for communicating with an air bag, so that the air in the bottle body 300 enters the air bag along the air flow tube 130.

For better understanding of the present utility model, the following details of the working principle of the technical solution of the present utility model are described with reference to fig. 3 to 5:

when in use, the other end of the air flow tube 130 is communicated with the air bag, the electric ignition head is electrified, so that a large amount of air is generated by the electric ignition head, the air pushes the needle seat 210 to move towards the direction close to the bottle body 300, the needle 220 is inserted into the bottle body 300, the membrane at the bottle mouth of the bottle body 300 can be pierced through the pricking needle 200, at the moment, the elastic piece 400 is in a compressed state under the extrusion of the pricking needle 200, because the air outlet 111 is communicated with the first mounting cavity 112 through the air outlet hole 211 when the pricking needle 200 is inserted into the bottle body 300, a large amount of air in the first mounting cavity 112 is discharged into the air bag along the air outlet 111, the pressure in the first mounting cavity 112 is restored to the initial state, the elastic piece 400 releases the compressed elastic potential energy, the puncture needle 200 is restored to the initial position under the simultaneous action of the elastic member 400 and the air bottle gas, at this time, the puncture needle 200 is moved out and far away from the bottle mouth of the bottle body 300, the air outlet 111 is communicated with the second installation cavity 113, the gas in the bottle body 300 can enter the air bag along the second installation cavity 113 and the air outlet 111, the air bag is inflated, compared with the traditional mode that the air bottle can be opened only by applying the pulling force to the pulling pin in the specified direction, the bottle opening device has stronger applicability, the air bottle can be opened without arranging an additional force applying device in the unmanned aerial vehicle, the strict requirements of the unmanned aerial vehicle on the weight and the space of the airborne equipment are better met, the airborne equipment of the unmanned aerial vehicle is ensured to have smaller weight and space, and the bottle opening device can be widely used on the unmanned aerial vehicle, after the bottle opening device is used for opening the bottle, the puncture needle 200 moves out of the bottle opening, the sectional area of an air flow channel of the bottle opening is equal to the diameter of a gas bottle diaphragm, and the gas flow speed is high.

The electric shock bottle opening device provided by the utility model has the following beneficial effects:

(1) After the electric ignition head is electrified, a large amount of gas is generated, the electric ignition head is adopted as a working piece, bottle opening and puncture needle 200 return are completed by utilizing the pressure of the gas, rapid inflation is realized, and adaptability is enhanced;

(2) Compared with the traditional mode that the air bottle can be opened only by applying pulling force to the pulling pin in a specified direction, the air bottle opening device has stronger applicability, and the air bottle can be opened without arranging an additional force application device in the unmanned aerial vehicle, so that the air bottle opening device is more suitable for strict requirements of the unmanned aerial vehicle on the weight and space of the airborne equipment, the airborne equipment of the unmanned aerial vehicle is ensured to have smaller weight and space, and the air bottle opening device can be widely used on the unmanned aerial vehicle;

(3) After the bottle opening device is used for opening the bottle, the puncture needle 200 moves out of the bottle opening, the sectional area of an air flow channel of the bottle opening is equal to the diameter of a gas bottle diaphragm, and the gas flow speed is high.

The above-described embodiments of the present utility model do not limit the scope of the present utility model. Any of various other corresponding changes and modifications made according to the technical idea of the present utility model should be included in the scope of the claims of the present utility model.

Claims

1. An electric shock bottle opening device, comprising:

2. The shock bottle opening device according to claim 1, wherein the spike comprises a needle seat and a needle, the needle seat is arranged in the mounting tube in a sealing sliding manner, and the needle is arranged in the second mounting cavity and is fixed on the needle seat.

3. The electric shock bottle opening device according to claim 2, wherein a plurality of exhaust holes with one ends communicated with the first installation cavity are formed in the side wall of the needle seat in a circumferential direction.

4. A shock absorbing bottle assembly as set forth in claim 3 wherein the other end of at least one of said vent holes communicates with said air outlet when said needle is inserted into said bottle.

5. The electric shock bottle opening device according to claim 4, wherein the tube body further comprises a partition plate, the partition plate is fixedly arranged in the installation tube, the partition plate and the needle seat are used for sequentially separating a first installation cavity, a second installation cavity and a third installation cavity in the installation tube, and a through hole used for communicating the second installation cavity and the third installation cavity is formed in the partition plate.

6. The shock bottle dispensing device of claim 5, wherein both ends of the mounting tube are open.

7. The shock wave bottle opening device according to claim 6, wherein a bottle mouth of the bottle body is disposed in the third mounting cavity and faces the through hole.

8. The shock bottle dispensing device of claim 1, wherein the generator is an electrical firing head electrically connected to the drone via a cable.

9. The electric shock bottle opening device according to claim 5, wherein the elastic member is a spring, the spring is disposed in the second mounting cavity and sleeved outside the needle, one end of the spring is fixedly connected with the partition plate, and the other end of the spring is fixedly connected with the needle seat.

10. The electric shock bottle opening device according to claim 1, wherein the tube body further comprises an air flow tube, both ends of the air flow tube are provided with openings, one end of the air flow tube is fixedly connected with the mounting tube and communicated with the air outlet, and the other end of the air flow tube is used for being communicated with the air bag.