JP2002349794A - Structure of cylinder for liquid energy - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structure of a cylinder for liquid energy of simple manufacturing processes, capable of mixing gas of sufficient concentration, and of beautiful appearance. SOLUTION: On an inner wall of a cylinder main body 1 of aluminum, a support 11 and an engagement column 12 are provided, and a vaporization box 4 is engaged with the outer side of the engagement column 12. An upper cover 2 provided with a circulation prohibiting valve 5, a gas emitting beak 21, and an oil injecting tube 22 are engaged in the cylinder main body 1. The gas emitting beak 21 is connected to a divided flow control box 23 where plural divided flow passages 233 are provided, and a gas emitting duct 72 of an air charging pump 7 provided on the upper cover 2 is connected to the circulation prohibiting valve 5. A bottom part of the circulation prohibiting valve 5 is inserted into the cylinder main body 1 to be connected to a second circulation prohibiting valve 6. A gas advance tube 63 is connected to a bottom part of the second circulation prohibiting valve 6, and a gas emitting cover 64 to generate fine bubbles is provided on an end of a bottom part of the vaporization box where the gas advance tube 63 is inserted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of a cylinder for liquid energy, and more particularly, to a structure which is easy to manufacture, is mixed with a gas having a sufficient concentration when used, and is aesthetically pleasing.

[0002]

2. Description of the Related Art As shown in FIG. 1, a control valve 301 is provided at the uppermost portion of a steel bottle 30 in a known cylinder structure into which liquid energy such as petroleum or liquefied gas is injected. Reference numeral 301 denotes a gas discharge valve 302 for discharging gas, a gas inlet valve 303 for injecting outside air into the steel bottle 30 and mixing with the gas, a gas inlet pipe 304, and the like. In the manufacturing process,
Since any liquid injected into the cylinder is of high risk, the steel bottle must withstand high pressure and corrosion so that it will not leak out and cause an accident. The steel jar 30 is made of a thick steel plate, formed by rolling it into a cylindrical shape, cut into an appropriate height, and then welded at the top and bottom.

[0003]

As described in the above-mentioned known structure, the product is expensive due to various restrictions on the cylinder, and the manufacturing process is relatively complicated and difficult. In addition, its weight and shape make transport very difficult. Also, due to its shape and weight, the cylinder is placed on the ground when it is used, but its appearance is not very beautiful in appearance, and it can be harmonious when placed indoors or outside. Sometimes, it feels like it's breaking the whole ambiance. Therefore, in order to solve these drawbacks, the structure of the liquid energy cylinder of the present invention is provided.

[0004]

In order to solve the above-mentioned problems, the present invention mainly comprises a cylinder main body, an upper lid, a bottom lid and the like. The cylinder body is formed by extruding a hollow aluminum through which the top and bottom are penetrated, and a vertical support and a fitting pillar are provided on the inner wall of the cylinder body in the same manner as the cylinder, respectively. A vaporization box is fitted and fixed to the outside of the device. The upper lid is a lid designed in accordance with the hollow shape of the cylinder body and having a stepped surface. The upper lid is fitted into the cylinder body and fixed with the support and the fitting post,
Further, a gas discharge beak and a lubrication pipe are installed, and the gas discharge beak is connected to a diversion control box further provided with a plurality of diversion passages. A circulation blocking valve is provided at a position of the upper lid corresponding to the vaporizing box of the cylinder body. Further, a pump for filling air is further provided on the lower surface of the upper lid, and a gas discharge conduit of the pump is connected to the circulation blocking valve of the upper lid, and the bottom of the circulation blocking valve is advanced into the cylinder body. To connect with the second flow blocking valve. A gas inlet pipe is connected to the bottom of the second flow blocking valve, and a gas discharge cover for discharging air bubbles is installed at an end of the bottom of the vaporization box into which the gas inlet pipe has entered. In addition, the bottom cover is adapted to the space inside the cylinder main body, a concave groove is opened in accordance with a conduit and a gas discharge cover inside the cylinder main body, and a gas entry pipe is provided. In addition to the one being inclined downward, the bottom lid is fixedly provided at the bottom of the column in the cylinder body.

[0005]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS As shown in FIGS. 2 to 8, a liquid energy cylinder 10 of the present invention comprises a cylinder
It is composed of a bottom cover 3.

The cylinder body 1 has a space inside, and is formed in a tubular shape by extruding aluminum vertically penetrating therethrough.
The length differs depending on the capacity, and the inner wall of the cylinder main body 1 is protruded to have a vertical column 11 slightly shorter than the height of the cylinder main body 1 (the interior is a hollow and reduced cost) and the cross section is trapezoidal. A presenting post 12 is provided, and both the support 11 and the post 12 are integrally formed with the one. After the cylinder main body 1 is cut into an appropriate size, a cutting process is performed so that the uppermost and lowermost portions of the columns 11 and the fitting columns 12 are accommodated in the cylinder main body 1. The
An opening 13 is opened near the top of the front wall surface of the cylinder body 1 by pressing so that the user can easily hold it with his / her finger. Hook holes 15 are provided on both sides near the uppermost portion of the rear wall surface of the cylinder body 1. Further, a vaporizing box 4 (see FIG. 3) is provided inside the cylinder main body 1, and a fitting groove 41 corresponding to the fitting column 12 of the cylinder main body inner wall is provided on a side wall of the vaporizing box 4. Inside the vaporization box 4, there are provided a plurality of horizontal separator plates 42 to isolate the inside of the box into several chambers, and each of the separator plates 42 has a gas discharge opposed to the top and bottom. A hole 421 and a hole 422 are opened.

The upper lid 2 is a stepped lid, which is designed in accordance with the shape of the upper part of the cylinder main body, and is fixed on the columns 11 and the fitting columns 12 in the cylinder main body 1. A gas discharge beak 21 and a lubrication pipe 22 are provided at a high portion of the upper cover 2, and the gas discharge beak 21 is connected to a flow control box 23 installed inside the upper cover 2.
As shown in FIG. 4, the branching control box 23 includes a main gas discharge passage 231 and the upper lid 2 at the extreme end of the main gas discharge passage 231.
The control valve 232 of the gas discharge beak 21 is fixed. Further, the flow control box 23 has a plurality of flow paths 233 formed in a recessed manner inside the flow control box 23 to provide a portion pointing to a flow split gas discharge beak 234 which is a soft tube. On the other side of the inside of the box 23, there is provided a diversion blocking screw hole 235 corresponding to and communicating with the branch passage 233.
A flow blocking bolt 236 is screwed in each of the flow blocking screw holes 235 so as to close each of the branch passages 233, and a packing 237 for sealing is provided on each of the flow blocking bolts 236.

[0008] The upper lid 2 is provided at the position corresponding to the perforation 422 of the vaporization box 4 inside the cylinder main body 1 with a flow preventing valve 5.
(See FIG. 5). The circulation blocking valve 5 includes a circulation blocking head 51 on the upper lid 2, a pipe passage 511 is formed inside the circulation blocking head 51, an inner spiral 413 is provided therein, and a packing is provided. A step surface 512 on which the 514 is provided is provided. A convex fence 5 for further installing the spring 52 on the step surface 512
15 are provided, and a notch 516 is further provided on the convex fence 515.
The outside of the spring 52 is covered by a circulation blocking cap 53 opening toward the pipe passage 511 side, and the gas is formed on a stepped surface 512 that is depressed inside the circulation blocking head 51. An entry head 54 is provided. A pipe 541 is similarly formed inside the gas entry head 54, and a concave groove 542 is formed for installing the circulation preventing cap 53 inside the other end of the gas entry head 54. 2 (see FIG. 6), the gas entry head 54 is in tight contact with the packing 514 to form a sealed state, and the spring 52 closes the circulation blocking cap 53. The pipe 541 inside the gas entry head 54 is pushed up.
The outlet is sealed. The diverting head 51 of the diverting valve 5 enters from the upper lid 2 and enters the cylinder body 1, and the diverting head 51 is connected to the second diverting valve 6.

As shown in FIG. 7, the second recirculation valve 6 has upper and lower lids 61 and 62 which are screwed to each other, and a soft valve 611 is fixed to the bottom of the upper lid 61. The soft valve 6
A projection 612 for closing the conduit of the upper lid 61 is provided on the upper surface of the upper lid 11, and a gas inlet pipe 63 is connected to the bottom of the lower lid 62. The gas enters the perforation 422 of the separator 42, and further reaches below the lowermost layer separator 42 of the vaporization box 4. At the end of the gas inlet tube 63, a gas discharge cover 64 is screwed.
A large number of small holes 641 communicating with the gas inlet tube 63 are provided on the gas inlet tube 4, and springs 642 and 642 are stopped inside the gas discharge cover 64 and the gas inlet tube 63 ends. Has a sphere 643 (see FIG. 8) that closes the sphere.

A gas filling pump 7 and an alarm device 8 are provided on a lower surface of the upper lid 2, and a gas guide pipe 71 of the gas filling pump 7 is connected to a gas entry head of the circulation blocking valve 5. The alarm device 8 includes a lamp, a pressure gauge, a liquid level alarm, a gas leak alarm, a radio, and the like, and has a purpose of warning so that a radio broadcast can be heard at the time of use. Has become. The alarm device 8 is a liquid level alarm, and includes a touch switch 24 on the upper lid 2.
(See FIG. 9), the upper lid 2 corresponding to the bottom of the touch switch 24, and the point in the cylinder body 1 that contacts the top of the liquid volume measuring tube 25 of the bottom lid 3. Is provided. Liquid is supplied from an inlet 251 opened at the bottom of the liquid amount measuring tube 25, and a float 252 is provided inside the liquid amount measuring tube 25, and a magnet 253 is provided at the top and bottom of the float 252, respectively. Is provided.

The bottom cover 3 is fitted at the lower end of the support 11 in the cylinder body 1 so as to be inclined downward toward the fitting column 12 according to the shape of the space in the cylinder body 1. The bottom cover 3 is provided with a concave groove 31 at the position of the gas inlet tube 63 and the gas discharge cover 64 inside the vaporization box 4, and a touch switch 32 corresponding to the liquid amount measuring tube 25 is provided at the bottom portion ( (See FIG. 9). The circuit of the touch switch 32 is connected to the 9 liquid level warning device on the upper lid 2.

As shown in FIG. 10, first, 4 is inserted into the cylinder body 1, the fitting column 12 inside the cylinder body 1 is fitted into the fitting groove 41 of the vaporizing box 4, and Four fitting grooves 41
The vaporization box 4 is screwed onto the fitting column 12 of the cylinder main body 1 through the inner wall, and the vaporization box 4 is fixed inside the cylinder main body 1. The upper lid 2 and the bottom lid 3 are respectively fitted from above and below the cylinder body 1 and are fixed on the upper and lower surfaces of the column 11, respectively. The pipe passage 511 in the recirculation valve 5 on the upper lid 2 prevents the second recirculation. The gas inlet head is connected to the upper lid 61 of the valve 6, and the gas entry head is connected to the gas guide pipe 71 of the gas filling pump 7 and is screwed and fixed by a nut 543 (see FIGS. 5 and 6). The gas inlet pipe 63 connected to the lower lid 62 of the double flow prevention valve 6 is penetrated into 422 on the four separators 42 and reaches below the lowermost separator 42, and the cylinder body 1 and the cylinder body 1, respectively. It is fixed to the top lid 2 and the bottom lid 3 by a method such as welding.

When the upper cover 2 is fixed inside the cylinder body 1, the gas filling pump 7 and the alarm device 8 are fixedly installed on the upper cover 2, and the branch passage 232 of the flow control box 23 is connected to the upper cover 2. 2 and connected to the gas discharge beak 21 on
After piercing the cylinder body 1, the split gas discharge beak 234 is screwed and fixed on the upper lid 2, thereby completing the sealed liquid energy cylinder 10 as shown in FIGS. 10 and 13. Liquid energy cylinder 10 after assembly
Inside, a gas discharge cover 64 at the end of the gas inlet tube 63 is located in the concave groove 31 of the bottom cover 3, and the bottom of the vaporization box 4 is located on the bottom cover 3.
The cylinder main body 1 and the vaporizing box 4 are in communication with each other due to the design of the concave groove 31. It is connected by tubing on the equipment of the required liquid energy, such as a vessel.

In use, the liquid energy 20 is first injected into a liquid energy cylinder, and then an appropriate amount of air is injected to mix the air and the liquid energy 20 into a high-pressure gas in an appropriate ratio. In detail, as shown in FIG. 10, an appropriate amount of the liquid energy 20 is previously injected into the liquid energy cylinder 10, an appropriate space is maintained between the liquid surface and the upper lid 2, and the liquid in the cylinder is Energy 20 is 31
It further enters the vaporizing box 4 and fills the entire vaporizing box 4. The liquid energy 20 simultaneously enters the liquid amount measuring tube 25 from an inlet 251 at the bottom of the liquid amount measuring tube 25, and a float 252 provided in the liquid amount measuring tube 25 floats on the liquid, and the amount of liquid is increased. Rise with the increase.

Further, air is supplied from the gas guide pipe 71 by the gas filling pump 7 to the circulation stop valve 5 and the second circulation stop valve 6.
The air is compressed through the gas filling pump 7 as shown in FIG.
, And the gas flow is directed to the line 54 of the gas entry head.
Separate the circulation blocking cap 53 at one outlet. At this time, the spring 52 is in a compressed state, so that the air current flows through the gap between the gas inflow head and the circulation blocking cap 53 and the cutout 516 on the convex wall 515.
1 through the pipe passage 511 and into the upper lid 61 of the second flow blocking valve 6, pushes open the pipe passage 511 in the flow blocking head 51 to open the second flow blocking valve 6 and the gas. It enters the approach pipe 63. At the time when the air flow has flowed into the gas inlet pipe 63, as shown in FIG. 13, the air flow pushes out the sphere 643 in the gas discharge cover 64 and presses the spring 642, and then the small hole of the gas discharge cover 64 641 enters the liquid energy 20 in the vaporizing box 4, and the air becomes fine and dense bubbles through the small holes 641 of the gas discharge cover 64, so that a large number of fine bubbles in the vaporizing box 4 are To the uppermost layer of the separator 42 through the S-shaped bypass formed by the respective separators 42.
And enters the cylinder body 1 (see FIG. 14). When a large amount of fine air bubbles discharged from 14 passes through the detour in the vaporization box 4, the gas is more sufficiently mixed due to the long contact time with the liquid energy 20, and the gas having an increased concentration is obtained. Are concentrated above the liquid level of the liquid energy 20.

In this manner, the gas inside the cylinder main body 1 becomes sufficient to a constant pressure value by the pumping operation, and the pressure of the gas inside the cylinder main body 1 becomes higher than the pressure inside the gas inlet pipe 63. Therefore, the spring 642 in the gas release cover 64 returns to push the sphere 643 to close the gas release cover 64 (see FIG. 8). Then, the air in the gas inlet pipe 63 cannot be taken out of the gas discharge cover 64, and the pressure gradually increases in the gas inlet pipe 63. At this time, the pressure in the gas inlet pipe 63 increases and the air Of the second flow blocking valve 6
And the upper lid 61 is pushed in close contact with the bottom of the upper lid 61, and the soft valve 611 on the upper lid 61 seals the pipeline, so that the compressed air of the gas filling pump 7 is re-discharged. Without entering the second diverter valve 6, the air therefore remains in the gas entry head of the diverter valve 5. Therefore, the spring 52 inside the circulating head 51 of the circulating valve 5 returns and pushes the circulating cap 53 to seal the outlet of the pipe 541 of the gas entry head (see FIG. 8).
The compressed air of the gas filling pump 7 is prevented from entering the gas inlet pipe 63 from the circulation preventing valve 5, and the gas filling pump 7 is automatically cut off by the air circulation of the gas guide pipe 71. Accordingly, the pumping operation of the liquid energy cylinder 10 is completed. The user opens the circulation blocking bolt 236 of the shunt control box 23 to release gas and ignites, and the alarm device 8 on the upper lid 2 measures that the gas pressure in the cylinder is insufficient and starts the operation. The power of the gas filling pump 7 is restored, and the pumping operation can be performed again.

When the uniformly mixed gas is concentrated below the upper lid 2, the gas circulates and enters the diversion control box 23 from the gas discharge beak 21 on the upper lid 2, as shown in FIG. First, the user opens the main gas discharge passage 231 and, if necessary, opens the main gas discharge passage 231 or opens only the circulation blocking bolt 236 on one of the branch passages 233 to form a passage inside the branch control box 23 so that the gas is released. Make sure it goes out smoothly. Conversely, when the use is completed, the control valve 232 outside the 231 and the diversion blocking bolt 236 on the distribution passage 233 are tightly closed, and as shown in FIG. 16, all the passages are completely shut out to prevent gas leakage. The packing 237 on the diverter bolt 236 plays a role in maintaining the hermetically sealed state of the diversion control box 23 even in a state where the passages communicate with each other and in a state where the passage is shut out, so that the diverting control box 23 is effectively sealed. The gas is prevented from leaking from the circulation blocking screw hole 235.

Further, a description will be given of a design in which the gas filling pump 7 automatically shuts off electricity by the air circulation in the gas guide tube 71. A power supply is automatically provided mainly inside the gas filling pump 7 separately. A gas filling device 9 to be shut out is provided. As shown in FIG. 17, a gas discharge pipe 72 of the gas filling pump 7 is
After passing through, the air is divided and connected to the internal gas filling device 9 and the external gas guide tube 71, and when the air is compressed and sent out smoothly, the air inside the gas guide tube 71 is filled with the gas It is no longer circulated to the device 9.

As shown in FIG. 18, the structure of the gas filling device 9 mainly includes a box 91, and a leg 911 is provided in the box 91.
The gas filling pump 7 and the convex button 9112 of the fine movement switch 911 of the power supply are separately provided.
It is linked to A hexagonal cap 912 further projects from the opening end of the box body 91 toward the internal space, and a small through hole 9121 is opened in the wall surface of the box body 91 at the bottom of the cap 912. Inside, a nut 913 is screwed with a bolt 913, and an adjustment end 9132 of the bolt 913 protrudes from the box body 91 through a through hole 9121 of the cap 912. Further, a spring 914 is fitted on the bolt 913, and a fitting groove 915 is provided on the wall surface of the open end of the box body 91, and the fitting groove 915 is provided.
A slightly inclined pressure control plate 916 is fitted into the opening end of the box body 91, and the convex button 9112 and the spring 914 of the fine movement switch 911 are respectively provided with a protruding pressure control piece 9161 and a convex grain. 9162 corresponds. A gas filling unit is fixed to the open end of the box 91. The gas filling unit is composed of an inner clamping piece 921 and an outer clamping piece 9.
22 and a pad 923 between the inner pinching piece 921 and the outer pinching piece 922, a perforation 9211 is formed on the inner pinching piece 921 adjacent to the box body 91, and A gas entry beak 9212 is provided. Outer clamping piece 9
22 is provided with a chamber 9221, a fitting groove 9222 is provided on the outer periphery of the chamber 9221, and an air chamber 923 in which a hole 9211 of the inner pinching piece 921 is formed in the center of the pad 923.
1 and the inner pinching piece 921 is provided on one side of the air chamber 9231.
A fitting groove 9232 is provided corresponding to the gas intrusion beak 9212, and a convex ring 9233 fitted in the fitting groove 9222 of the 922 is provided.

The assembled state of the gas charging switch 9 is as shown in FIGS. 19 to 22, in which a fine movement switch 911 is fixed in the box 91 and the convex button 9112 is provided.
Faces the opening end of the box 91 (see FIG. 19), and the legs 9111
The part is facing outwards in reverse (see FIG. 20) and is connected to the gas filling pump 7 and a power supply. The nut 9
131 is screwed on the bolt 913 and the nut 9
131 and the bolt 913 are both caps 9 of the box body 91.
12, the adjustment end 9132 of the bolt 913 penetrates through the through hole 9121 in the wall surface of the box 91 and projects outside the box 91 (see FIG. 21). The spring 914 is fitted to the bolt 913, and the bottom of the pressure control plate 916 is
Of the fine movement switch 911, and the convex grain 9162 fits the extreme end of the spring 914 to provide a place for positioning. (See FIG. 21). The pad 923 of the gas filling unit is interposed between the inner clamping piece 921 and the outer clamping piece 922, and the air chamber 9231 of the pad 923 projects from the perforation 9211 of the inner clamping piece 921 and faces the pressure control plate 916. And a convex ring 9223 on the other surface of the pad 923.
Is fitted in the fitting groove 9222 of the outer pinching piece 922. Further, the gas intrusion beak 9212 of the inner pinching piece 921 enters the fitting groove 9232 of the pad 923 so that the outer pinching piece 922
22 is in communication with the second chamber 9221 (FIG. 22).
The box spring 914 is fixed by screwing the screw 92 (see FIG. 18) to the box body spring 914 so that the pressure plate 916 is fixed. Is pressed into the air chamber 9231 inside the perforation 9211 of the inner pinching piece 921 (see FIGS. 21 and 22). At this time, the air in the air chamber 9231 is not filled with air, and the air chamber 9231 is in a deflated state. Has become.

With the above arrangement, the air compressed by the gas filling pump 7 is allowed to enter the liquid energy cylinder 10, so that the inside of the cylinder main body is saturated or the pressure reaches a set value, and the gas entrance pipe 63 is set. The gas filling pump 7 keeps the compressed air from the gas guide pipe 71 to the gas discharge pipe 72 through the trifurcated head 73 because the circulation blocking valves 5 and 6 are all closed. In other words, the gas entering beak 9212 of No. 9 causes the gas entering beak 9212 in the inner pinching piece 921 and the fitting groove 9232 of the pad 923 to enter the chamber 9221 of the outer pinching piece 922, and gradually the chamber 9221 and the air chamber 9231 of the pad 923 is filled. The air chamber 9231 is gradually filled with air and swells in the direction of the box 91, and the pressure control plate 916
Is tilted toward the fine movement switch 911, and as shown in FIG. 23, the pressure control plate 916 presses the spring 914, and the convex button 911 of the fine movement switch 911 is pressed by the pressure suppression piece 9161.
2 (see FIG. 24), the convex button 9112 is buried in the fine movement switch 911 and the power is shut out, that is, the gas charging pump 7 automatically stops the pumping operation and Will not be filled.
Further, at this time, the gas in the chamber 9221 and the gas chamber 9231 leaks slowly into the gas inlet beak 9212, and the return of the spring 914 pushes the pressure control plate 916 to press the gas chamber 912.
231 is pressed, and the gas intrusion beak 9212 is completely discharged, and the state shown in FIGS. 21 and 22 is restored.

The gas filling device 9 has not only the above-mentioned automatic power shut-off function, but also a fine adjustment function, so that the user can adjust the gas saturation in the liquid energy cylinder 10. If it is desired to increase the pressure value, simply rotate the adjustment end 9132 of the bolt 913 using a tool, and the nut 9131 inside the cap 912 will be inserted into the hexagon inside the cap 912. 25, the bolt 913 is connected to the nut 9131 by the pressing plate 91 as shown in FIG.
The spring 914 moves in the six directions, and the spring 914 is pressed to generate a slightly large pressing force, thereby pressing the pressure control plate 916. Therefore, a more large amount of gas is circulated into the gas chamber 9231 to generate a slightly larger pressure.
6, the power is shut out. Similarly, when lowering the saturation or the pressure value in the liquid energy cylinder 10, the bolt 913 is rotated, and the nut 9131 is separated from the pressure control plate 916. Therefore, the gas filling device 9 of the present invention can be adjusted at any time according to the needs of the user, and is designed with an adjusting function and various selectivity.

Further, the alarm device 8 has a function of measuring a liquid amount,
Therefore, the liquid energy 2 in the liquid energy cylinder 10
When the oil amount of 0 is insufficient, the alarm device 8 automatically sounds an alarm bell to notify the user that liquid energy must be added. That is, as shown in FIG. 26, when the liquid energy 20 is about to be exhausted, the liquid level descends and approaches the upper part of the bottom lid 3, and the floating 2
52 naturally lowers with the lowering of the liquid level, so that the magnet 253 at the bottom of the float 252 approaches the touch switch 32 at the bottom of the bottom cover 3 and comes into contact with the touch switch 32 by the attraction of the magnet. This causes the current in the alarm device 8 to enter a circuit state and sound an alarm, indicating that the user must add liquid energy. Conversely, when the user injects the liquid energy 20 into the liquid energy cylinder 10, the liquid level rises with the float 252, and the float 252 approaches the upper lid 2, causing the liquid level 20 to rise. The upper magnet 253 is a touch switch 24 on the upper lid 2.
Then, as shown in FIG. 27, the touch switch 24 turns on the alarm device 8 and the current, and the alarm device 8 emits an alarm again to inform the user that the liquid is saturated. Informs the liquid to prevent it from overflowing.

[0024]

According to the present invention, the manufacturing process can be simplified and the cost can be reduced because the manufacturing process is performed by extruding aluminum. At the same time, the weight can be reduced and the appearance can be improved. did it. In addition, by attaching the tires, the utility has been enhanced, such that the tires can be easily pulled and moved by hand, and some hooks can be hung on a wall.

Further, in the vaporization box installed inside the cylinder body, the purpose of effectively increasing the density of gas by mixing air and liquid energy more sufficiently is achieved.
Further, the upper lid is provided with a gas discharge cover having a circulation preventing function, a second circulation preventing valve, and a circulation preventing valve, thereby preventing the internal pressure from being excessively increased by injecting too much air. By providing a switch for automatically switching the power source inside the filling pump, a circulation was caused by the air that was over-compressed, which ensured safety and prevented the life of the pump from being shortened at the same time.

In the installation of the air filling switch, it has a fine adjustment function, so that it can be adjusted to the required pressure inside the cylinder body, and in the gas filling device, electricity is automatically shut out. Therefore, the user does not need to wait for the operation to be completed,
It became convenient. In addition, in the case of the top cover and the bottom cover, first, the bottom cover has an inclined state, so that the liquid energy is sufficiently used, and since the liquid amount measuring pipe and the float are provided inside the cylinder body, the oil amount is reduced. Is now alerted by a warning device that it is low or full. In addition, the flow control box provided on the upper lid can control the gas flow inside the cylinder body by opening and closing the circulation blocking screw, and can be adjusted to be fully open or only one open as needed, so that it can be used. It became more convenient.

[Brief description of the drawings]

FIG. 1 is a structural explanatory view of a steel bottle having a known structure.

FIG. 2 is a perspective view of the present invention.

FIG. 3 is a three-dimensional exploded view of the vaporization box of the present invention.

FIG. 4 is a three-dimensional exploded view of the diversion control box of the present invention.

FIG. 5 is a three-dimensional exploded view of a flow blocking valve portion of the present invention.

FIG. 6 is an assembled sectional view of FIG. 5;

FIG. 7 is a three-dimensional exploded view of a second flow blocking valve and a gas inlet pipe portion of the present invention.

FIG. 8 is an assembled sectional view of FIG. 7;

FIG. 9 is an assembled sectional view of the liquid bundle tube according to the present invention.

FIG. 10 is an assembled sectional view of the present invention.

FIG. 11 is an explanatory view of a use state in which the gas of the present invention is not filled.

FIG. 12 is an explanatory view of the operation of the circulation blocking valve portion of the present invention.

FIG. 13 is an operation explanatory view of a conduit portion of the present invention.

FIG. 14 is an explanatory view of a use state filled with the gas of the present invention.

FIG. 15 is an assembled sectional view 1 of the diversion control box of the present invention.

FIG. 16 is an assembled sectional view 2 of the diversion control box of the present invention.

FIG. 17 is a structural explanatory view of a gas filling pump of the present invention.

FIG. 18 is a three-dimensional sectional view of a gas charging switch portion of the present invention.

FIG. 19 is an assembled external view (front view) of the gas charging switch portion of the present invention.

FIG. 20 is an assembled external view (right side) of the gas charging switch portion of the present invention.

21 is a sectional view taken along the line AA of FIG. 20.

FIG. 22 is a sectional view taken along the line BB of FIG. 19;

FIG. 23 is an explanatory view of the operation of the gas filling switch of the present invention.

24 is an explanatory view of a gas filling operation in the CC direction of FIG. 20.

FIG. 25 is an explanatory diagram of an adjustment state of the gas filling switch of the present invention.

FIG. 26 is an operation explanatory view 1 of the liquid amount measuring tube of the present invention.

FIG. 27 is an operation explanatory view 2 of the liquid amount measuring tube of the present invention.

FIG. 28 is an explanatory diagram of a moving state according to the present invention.

FIG. 29 is an explanatory view of a state in which the present invention is suspended and used.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Liquid energy cylinder 20 Liquid energy 30 Steel bottle 301 Control valve 302 Gas release valve 303 Gas entry valve 304 Gas entry pipe 1 Cylinder main body 11 Column 12 Fitting column 13 Opening 14 Tire 15 Hook hook hole 2 Top lid 21 Gas emission beak 22 Note Oil pipe 23 Separation flow control box 231 Main gas discharge passage 232 Control valve 233 Separation flow passage 234 Separation gas discharge beak 235 Flow stop screw hole 236 Flow stop bolt 237 Packing 24 Touch switch 25 Liquid amount measurement tube 251 Inlet 252 Float 253 Magnet 3 Bottom cover DESCRIPTION OF SYMBOLS 31 Concave groove 32 Touch switch 4 Vaporization box 41 Fitting groove 42 Separator plate 421 Gas discharge hole 422 Drilling 43 Screw 5 Round flow prevention valve 51 Round flow prevention head 511 Pipe passage 512 Floor surface 513 Inner spiral 514 Packing 515 Convex wall 516 Missing Outlet 52 Spring 53 Circulation blocking cap 54 Gas entry head 541 Pipe 542 Concave groove 543 Nut 6 Second circulation blocking valve 61 Upper lid 611 Soft valve 612 Projection 62 Lower lid 63 Gas entrance pipe 64 Gas release cover 641 Small hole 642 Spring 643 Sphere 7 Gas filling pump 71 Gas guide tube 72 Gas discharge tube 73 Trifurcated head 8 Alarm device 9 Gas filling switch 91 Box 911 Fine movement switch 9111 Leg 9112 Convex button 912 Cap 9121 Through hole 913 Bolt 9131 Nut 9132 Adjusting end 914 Spring 915 Fitting groove 916 Suppression plate 9161 Suppression piece 9162 Convex grain 92 Gas filling unit 921 Inner suppression piece 9211 Perforation 9212 Gas entry beak 922 Outer suppression piece 9221 Storage chamber 9222 Fitting groove 923 Pad 9231 Gas chamber 9232 Fitting 9233 Totsuwa 93 screws

Claims (5)

[Claims] 1. A structure for a liquid energy cylinder in which a cylinder main body, an upper lid and a bottom lid are fixedly provided. There are provided a plurality of pillars integrally supporting and fixing the upper lid and the bottom lid, and a vertical dovetail-shaped fitting pillar, and a wall on one side is formed outside the fitting pillar in a shape of the fitting pillar. A vaporization box having a fitting groove depressed at the same time is installed, and a plurality of horizontal separators are installed inside the vaporization box, and each of the separators has a large amount of gas discharge holes in relation to the upper and lower separators. Is provided on each separator, and a perforation is formed on each separator to allow a gas inlet tube to enter, and the vaporizing box is installed on the bottom lid, and liquid energy is transmitted from the concave groove of the bottom lid to the vaporizing box. Inside the cylinder and reaches the same height as the liquid level of the cylinder body. Gas enters along the gas inlet pipe, and becomes a large amount of fine bubbles through a gas discharge cover that is installed at the end of the gas inlet pipe and enters the inside of the box. , The large amount of bubbles rises to the bottom of the separator and is released from each of the gas discharge holes, and the gas is discharged from the gas discharge holes of the uppermost separator while forming a detour in order. And a gas cylinder that is characterized by increasing the vaporization rate by sufficiently mixing the gas into the liquid energy to increase the concentration, and a step shape according to the shape of the hollow cylinder body. A gas discharge beak fitted into the cylinder main body and fixed to the column and the gas inlet pipe, and connected to a diversion control box provided with a plurality of diversion passages at an upper part thereof; In the top lid where the oil pipe is installed, A main gas discharge passage is formed inside the diversion control box, and a control valve connected to a gas discharge beak is provided at an extreme end of the main gas discharge passage, and the main gas discharge passage is provided inside the diversion control box. A branch gas discharge beak into which a tube is inserted is installed at the extreme end of the branch passage, and a branch gas discharge beak is installed in the branch control box. A diversion blocking bolt is provided at the other end and communicates with the diversion passage. A packing is fitted inside each diversion blocking bolt, and the main gas discharge passage and the diversion passage are disposed together with the diversion bolt. The space is closed and sealed, and a circulation blocking valve is provided at a position corresponding to the vaporization box of the cylinder body, and the circulation blocking valve is provided on the upper lid and is connected to the gas inlet pipe of the cylinder body. A circulating stop head; The part has a floor provided with an inner spiral on the side facing the upper lid forming a penetrating conduit, a spring is provided on the floor, and an opening is provided on the outside of the spring. It is covered with a flow blocking cap facing the flow blocking head, and a gas entry head is screwed in the floor of the flow blocking head, and a pipe is formed inside the gas entry head. On the side facing the upper lid, there is provided a groove for positioning the circulation blocking cap, and at the other end of the groove, a gas guide tube for connecting a gas filling pump is provided, and a lower portion of the upper lid is provided. Is provided with the gas filling pump, and the gas guide pipe of the gas filling pump is connected to the circulation blocking valve of the upper lid. Connected to the stop valve, The gas inlet pipe is connected to the gas inlet pipe, and the gas inlet pipe is provided with a gas discharge cover that enters and is fixed to the bottom of the vaporization box and emits fine bubbles, and a gas discharge cover is provided on the surface of the gas discharge cover. A large number of small holes communicating with the gas inlet pipe are provided, and a spring and a sphere installed at the gas outlet pipe end outlet under the pressure of the spring are provided in the gas discharge cover. Further, a touch switch is fixed on the upper lid, and at a position corresponding to the touch switch on the bottom of the upper lid, a liquid amount measuring tube inserted into the cylinder body is provided. An inlet is provided, and an upper lid to which a magnet is fixed at each of upper and lower positions of a float provided in the pipe, and a shape adapted to a cavity in the cylinder body, and on a side facing the gas inlet pipe. Is inclined downward, and the bottom of the strut is located within the cylinder body. A bottom cover is provided with a concave groove at a location corresponding to the conduit and the gas release cover inside the cylinder body, and a touch switch is fixed at a location corresponding to the bottom of the liquid volume measurement tube. A structure of a cylinder for liquid energy, comprising: 2. A filling switch for automatically turning off a power supply is provided inside the air filling pump. The filling switch has a box, and legs inside the box are provided with fine movement switches for the power supply. And the upper end of the spring and the convex button of the fine movement switch face the open end of the box, and the fine movement switch and the spring are inclined on the open end face of the box. A pressure suppression plate corresponding to a convex button of the fine movement switch and a convex grain corresponding to the spring are provided on a surface of the pressure suppression plate on a side of the box body; and an opening of the box body. The end face is further provided with a gas filling unit of the gas intrusion beak, and on the side of the gas filling unit facing the pressure control plate, an air chamber that expands by filling with gas is provided in a convex manner. Therefore, the gas filling unit is screwed and fixed facing the opening end side of the solid, and The gas pushes the pressure control plate to the outside of the air chamber to incline the air chamber, causing gas to circulate and enter the gas filling unit from inside the gas entrance beak, and the air chamber is directed toward the box body. At the same time as pressing the spring by pressing the pressure control plate, and simultaneously pressing the convex button of the fine movement switch,
The structure of the cylinder for liquid energy according to claim 1, wherein the connected power supply is shut out. 3. A cap having a hexagonal cavity into which a bolt into which a hexagonal nut is screwed is inserted, wherein the cap has a bottom portion on the wall of the box. Has a through hole, an adjusting end of the bolt projects out of the box body from the through hole, and one end of a spring is fitted on the bolt, and the other end of the spring is The adjustment end of the bolt is in contact with the pressure plate, so that the nut moves in the cap, that is, the nut makes a fine adjustment by changing the pressure on the spring and the force with which the spring presses the pressure plate. 3. The structure of the cylinder for liquid energy according to claim 2, wherein a location is provided. 4. The gas filling unit includes an inner pinching piece having a gas intrusion beak formed outside the opened perforation and adjacent to the box, and a gas intrusion piece adjacent to the box. An outer pinching piece in which a chamber communicating with the beak is recessed, and a pinched between the inner pinching piece and the outer pinching piece, the center of which rises toward the box body and An air chamber perforating the inner pinching piece; and a pad having a convex ring fitted into the fitting groove of the outer pinching piece, wherein the volume of the outer pinching piece from the gas entry beak is contained by gas. 3. The structure for a cylinder for liquid energy according to claim 2, wherein the pad is expanded by inflating the pad by gradually filling the air chamber of the pad with gas, thereby moving the pressure control plate. 5. An opening which is open to the outside near the uppermost portion of the front wall surface of the cylinder main body, and a wheel is provided at the bottom of the cylinder main body, so that the opening is formed. 2. The wheel according to claim 1, wherein the wheel is easily rotated and moved by being pulled by hand, and hook holes for wall hanging are provided on both sides near the uppermost portion of the rear surface of the cylinder body. Structure of the liquid energy cylinder.