KR20130024216A - Composite honeycomb super high-pressure vessel - Google Patents

Abstract

PURPOSE: A composite honeycomb ultra-high pressure container is provided to improve sealing safety and strength safety and to control the inflow and outflow of ultra-high pressure gas by coupling an opening and closing valve at the center of a semi-spherical cap. CONSTITUTION: A composite honeycomb ultra-high pressure container comprises a honeycomb cylindrical body(27). Multiple triangular channels(22) or rectangular channels(23) formed between an inner container(20) and an outer container(21), multiple radial support plates(26,26') are extruded in the honeycomb cylindrical body. Interior female threads(14,14') of the inner container are coupled to external male threads(28,28') of semi-spherical caps(24,24'). The ends of the outer container and L-shaped ends of the semi-spherical caps are welded to have outer welding lines(29,29'). An opening and closing valve(30) is coupled to a female formed at the center of one of the semi-spherical caps. Refrigerant entered through an inflow pipe(32) flows out to an outflow pipe(33) through the triangular or rectangular channels. An axial composite wire(34), a helical composite wire(17), a hoop-directional composite wire are alternatively wound and laminated between protruded pins(25,25') in three different directions. [Reference numerals] (AA) Inflow of low-temperature media; (BB) Outflow of low-temperature media

Description

Composite honeycomb super high-pressure vessel

The present invention relates to a composite honeycomb ultra high pressure vessel, and more particularly, a triangular channel or along an axial direction between an inner vessel formed with a plurality of radial support plates integrally formed in the inner diameter of the cylindrical ultra high pressure vessel and an outer vessel formed to have concentric circles. A honeycomb circular body extruded to form a monolithic channel is formed with a female screw on the inner diameter side of the cylindrical body, and is coupled to a pair of hemispherical caps, and a double vessel shape welded on the outer diameter side,

In addition, between the hemispherical cap and the numerous protruding pins formed on the outer surface of the honeycomb circular body, a high elastic wire such as carbon fiber or glass fiber is alternately wound to form a three-way lamination in the axial direction, the helical direction, and the hoop direction. Cylindrical composite honeycomb ultra-high pressure container in pursuit of light weight, high capacity.

The opening and closing valve of the hemispherical cap is fastened to ensure the inflow and outflow of ultra-high pressure gas, and the inlet pipe and the outflow pipe are respectively fastened to the edge front to form a triangular channel in which the low temperature air or the refrigerant body of the air conditioner is extended in the axial direction. By effectively reducing the temperature and pressure of the ultra-high pressure gas by the heat exchange action generated through the square channel, the charging time can be greatly shortened, and the strength and safety of the composite ultra-high pressure container can be significantly improved.

Conventional cylindrical composite ultra-high pressure vessels have a two-way lamination of high-elastic wire such as carbon fiber or glass fiber in the helical and hoop directions along the outer surface of an ultra-high pressure vessel formed by back extrusion deep drawing or extrusion of aluminum, plastic, or steel. It is a composite ultra high pressure container that is wound to form and secured strength safety.

Composite ultra high pressure vessels are wound in two directions on the outer surface of a super high pressure vessel that is extruded with a relatively thick material to ensure sufficient resistance to ultra high pressure gases. Difficulties in manufacturing large-capacity ultra-high pressure containers due to fuel efficiency, cost increase, and back-extrusion molding processing, especially long-term charging due to low-speed charging to reduce the risk of rapid temperature rise during the filling process of ultra high pressure gas, If the safety valve that can control the pressure rise due to external radiant heat supplied to the mounted composite ultra-high pressure container is bad, there is a problem that the risk is rapidly increased.

The present invention has been made to solve the above-mentioned conventional problems, the object is to ensure the strength and sealing safety enough to withstand the pressure acting on the cylindrical composite ultra-high pressure container, and the storage capacity It is to provide a composite honeycomb ultra-high pressure vessel capable of high-speed filling by increasing light manufacturing.

In addition, rather than increasing the thickness of the ultra-high pressure vessel to secure strength safety, a radial support plate is formed on the inner diameter side of the ultra-high pressure vessel, and a honeycomb triangular channel or a square channel is integrally formed in the axial direction between the inner vessel and the outer vessel. Extruded in the shape of a container, and formed on both ends of the honeycomb circular body by fastening the screw with the hemispherical cap or by additional welding, between the honeycomb circular body and the numerous protruding pins formed on the outer surface of the hemispherical cap. High elastic wires such as fibers are wound in alternating axial, helical, and hoop directions to form three-way stacks to ensure strength and airtightness, and the inlet and outlet pipes are fastened to the outside of the outer edge of the hemispherical cap, respectively. The low temperature air of the air or the refrigerant body of the air conditioner passes through the axial channel formed in the honeycomb circular body. To drop the temperature and pressure of the ultra-high pressure gas by heat exchange action shorten the charging time of the composite honeycomb high pressure vessel, and to provide additional strength and stability it is an object of sealing.

In order to achieve the object of the present invention, the inner diameter portion of the composite ultra-high pressure vessel for storing ultra-high pressure gas is integrally formed with an axial triangular channel or square channel between the inner vessel formed with a plurality of support plates radially and the outer vessel formed of concentric circles. High elastic wire, such as carbon fiber, between the honeycomb round body and the number of protruding pins formed on the outer surface of the hemispherical cam by extrusion or by fastening a pair of hemispherical caps to screws formed at both ends of the honeycomb circular body. The three-way lamination in the axial direction, the helical direction, and the hoop direction is alternately wound to form a high capacity light weight structure, which greatly improves the strength safety and the sealing safety.

In addition, a shut-off valve is installed at the center of the hemispherical cap, in which both ends of the honeycomb circular body are screwed or welded, and the inlet pipe and the outlet pipe are fastened to the outside of the outer edge of the honeycomb to allow the low-temperature air or refrigerant to flow from the honey. The heat exchange effect generated by passing through the triangular or square channel formed in the comb circular body in the axial direction decreases the temperature and pressure of the ultra-high pressure gas stored in the inner container, thereby increasing the storage capacity and shortening the filling time. It is characterized by greatly increasing safety and providing high durability.

In the present invention, the inner diameter of the composite ultra-high pressure vessel is a honeycomb round body end of a double-vessel shape formed by integrally extruding a plurality of triangular channels or square channels between an inner container formed of a plurality of radial support plates and an outer container of concentric circles. A high elastic wire such as carbon fiber or glass fiber is axially, helically or hooped between a honeycomb round body welded to the thread formed in the screw part or a number of protruding pins formed on the outer surface of the hemispherical cam. It is possible to expect the effect of greatly improving the strength safety and the sealing safety in a high-capacity, lightweight structure by alternately winding so as to form a three-way stack in the direction.

In addition, the opening and closing valve of the hemispherical cap ensures the inflow and outflow of ultra-high pressure gas, and the inlet pipe and the outflow pipe are respectively fastened to the outside of the outer edge of the hemispherical cap to form a honeycomb circle. The heat exchange acts through the axial channel of the body to reduce the temperature and pressure of the ultra-high pressure gas stored in the inner container to shorten the charging time due to the high-pressure and high-speed filling, and break down the strength and sealing safety of the composite honeycomb ultra-high pressure container. Can be expected to improve the effect.

In addition, the honeycomb circular body extruded by the inner container and the outer container, the axial channel and the support plate as a single body has the effect of reducing the weight relative to the storage capacity even though the strength and safety.

1 is a cross-sectional view of a conventional composite ultra-high pressure container.
Figure 2 is a cross-sectional view showing a composite honeycomb ultra high pressure vessel of the present invention.
Figure 3 is a cross-sectional view of a composite honeycomb ultra-high pressure vessel showing a first embodiment of the present invention.
Figure 4 is a cross-sectional view of a nozzle-type composite honeycomb ultra-high pressure vessel showing a second embodiment of the present invention.
Figure 5 is a cross-sectional view of a nozzle-type composite honeycomb ultra-high pressure vessel showing a third embodiment of the present invention.

Hereinafter, the configuration of the present invention in detail with reference to the accompanying drawings as follows.

As shown in Figure 1, the conventional cylindrical composite ultra-high pressure vessel is formed of a cylindrical cylindrical body 10 using an aluminum, plastic, steel, etc. integrally, one end of the body 10 is a plug 11 The other end is a structure in which the valve 15 is fastened to the female screw 14 formed in the inner diameter portion of the dome 12 and the nozzle-shaped protruding tab 13.

In addition, the outer wall surface of the body 10 by using a high elastic wire 16, such as carbon fiber, glass fiber, helical direction composite wire (17, 17 ', 17' ') and hoop direction composite wire (18, 18) It is possible to greatly increase the strength and safety of the composite ultra-high pressure vessel by forming a multi-layer composite wire laminated portion 19 by winding alternating ', 18') in two directions.

Figure 2 is a cross-sectional view showing a cylindrical composite honeycomb ultra-high pressure container according to the present invention, as shown in the present invention is a plurality of triangular along the axial direction between the inner cylinder 20 and the outer container 21 of the cylindrical cylinder The channel 22 or the square channel 23 is integrally elongated by extrusion, and a number of protruding pins 25 and 25 are formed along the outer surface of the hemispherical cap 24 and 24 ′ formed in the hemispherical shape with the outer container 21. ') Respectively,

A honeycomb circular body 27 is formed by integrally molding a plurality of radial support plates 26 and 26 'along the axial direction of the inner container 20, and is formed at both ends of the honeycomb circular body 27. The female threads 14 and 14 'formed on the inner diameter side of the container 20 are fastened with the L-shaped outer diameter male threads 28 and 28' formed at the outer edges of the hemispherical caps 24 and 24 ', and the outer container ( The end of 21 is welded to the L-shaped vertical end formed on the outer edge of the hemispherical cap 24 and 24 'to form a double high pressure vessel having an outer welding line 29 and 29', thereby securing safety and strength. To ensure safety and sealability,

In addition, the female screw 14 formed to protrude in the center of the hemispherical cap 24 is fastened to the inlet and outlet of the ultra-high pressure gas by fastening the on-off valve 31 with the built-in safety valve 30,

In addition, the inlet pipe 32 and the outlet pipe 33 are fastened to the female threads 14 and 14 'formed on the outer edges of the hemispherical caps 24 and 24', respectively. Due to the heat exchange action that occurs in the process of the refrigerant body passing through the triangular channel 22 or the square channel 23 formed in the honeycomb circular body 27, the temperature and pressure of the ultrahigh pressure gas are dropped to greatly shorten the charging time, Additional safety and sealing safety,

In addition, a high elastic wire 16 such as carbon fiber or glass fiber is used between the hemispherical caps 24 and 24 'and the numerous protruding pins 25 and 25' formed on the outer surface of the honeycomb circular body 27. The axial composite wire 34, the helical composite wire 17, and the hoop composite wire 18 are alternately wound in three directions to form a stack, thereby improving strength and safety in a lightweight structure, and fast filling of ultra high pressure gas. This makes it possible to form a cylindrical composite honeycomb ultra-high pressure vessel with a dramatically increased storage capacity.

Figure 3 is a cross-sectional view of a composite honeycomb ultra high pressure vessel showing a first embodiment of the present invention. Here, the characteristics are high elastic wire 16, triangular channel 22, square channel 23, hemispherical caps (24, 24 '), protruding pins (25, 25'), support plates (26, 26 '), honeycomb round The body 27, the opening and closing valve 31, the inlet pipe 32, the outlet pipe 33 is composed of a portion as shown in Figure 2, the inner container 20 constituting both sides of the honeycomb circular body 27 and The ends of the outer container 21 are opposed to the L-shaped outer diameter side and inner diameter side ends formed at the outer edges of the hemispherical caps 24 and 24 ', respectively, and welded sequentially from the inside along the circumferential surface to form the inner welding line 35 ( A double high pressure vessel of a honeycomb circular body 27 having a 35 ') and an outer weld line 29, 29',

In addition, a high elastic wire 16 such as carbon fiber or glass fiber is used between the hemispherical caps 24 and 24 'and the numerous protruding pins 25 and 25' formed on the outer surface of the honeycomb circular body 27. The axial composite wire 34, the helical composite wire 17, and the hoop composite wire 18 are alternately wound in three directions to form a stack, thereby improving strength and safety in a lightweight structure, and fast filling of ultra high pressure gas. This makes it possible to form a cylindrical composite honeycomb ultra-high pressure vessel with a dramatically increased storage capacity.

Figure 4 is a cross-sectional view of a nozzle-type composite honeycomb ultra-high pressure vessel showing a second embodiment of the present invention. Here, the characteristics are high elastic wire 16, triangular channel 22, square channel 23, hemispherical caps (24, 24 '), protruding pins (25, 25'), support plates (26, 26 '), honeycomb round The body 27, the opening and closing valve 31, the inlet pipe 32, the outlet pipe 33 is composed of a portion as shown in Figure 2, the inner container 20 constituting both sides of the honeycomb circular body 27 and Female nozzles 14, 14 'and male threads formed on the inner diameter side and the outer diameter side of the dome 12, 12' are formed by forming nozzle-shaped domes 12, 12 'having reduced cross-sectional areas at both ends of the outer container 21. The outermost side of the hemispherical caps 24 and 24 'which is screwed into the small hemispherical caps 24 and 24' to 28 and 28 ', and which are in contact with the outer diameter side surfaces of the dome 12 and 12'. The end is welded to form a double high pressure vessel of the honeycomb circular body 27 having outer welding lines 29 and 29 ',

In addition, the inlet pipe 32 and the outlet pipe 33 are fastened to the female threads 14 and 14 'formed on the outer edges of the hemispherical caps 24 and 24', respectively, and the low temperature air or the air conditioner introduced from the outside. Coolant is introduced into the annular groove (37) formed by the upper end of the honeycomb circular body 27 and the inner space of the hemispherical cap (24) and then through the triangular channel (22) or square channel (23) By reducing the temperature and pressure of the ultra-high pressure gas by the heat exchange action generated in the process of exiting the outflow pipe 33 through the annular groove 37 ', the charging time is greatly shortened, and additionally secures strength and sealing safety. ,

In addition, between the hemispherical caps 24 and 24 'and the numerous protruding pins 25 and the protruding pins 25' formed on the outer surface of the honeycomb circular body 27, a high elastic wire such as carbon fiber or glass fiber 16 By using), the axial composite wire 34, the helical composite wire 17, and the hoop composite wire 18 are alternately wound in three directions to form a stack, thereby improving the strength and safety of the lightweight structure. High-speed filling of the gas is possible, and a cylindrical nozzle-type composite honeycomb ultrahigh pressure container with a dramatically increased storage capacity is formed.

5 is a cross-sectional view of a nozzle-type composite honeycomb ultrahigh pressure vessel according to a third embodiment of the present invention. Here, the features are high elastic wire 16, triangular channel 22, square channel 23, hemispherical cap 24, protruding pins (25, 25 '), support plates (26, 26'), honeycomb round body (27) ), The opening and closing valve 31, the inlet pipe 32, the outlet pipe 33 is composed of the same as Figure 4, one side of the honeycomb circular body 27 is sealed, the other is the inner container 20 And a small dome shaped cap having a nozzle-shaped dome 12 having a reduced end cross-sectional area of the outer container 21 and formed on the inner and outer diameter side surfaces of the dome 12 respectively. A double high pressure vessel of a honeycomb circular body 27 having an outer welding line 29 by fastening with a screw formed at 24 and welding the outermost end of the hemispherical cap 24 in contact with the outer diameter side of the dome 12. Form the

In addition, the inlet and outlet of the ultra-high pressure gas is made by the on-off valve 31 attached to the center of the hemispherical cap 24, between the upper end of the honeycomb circular body 27 and the inner space of the hemispherical cap 24 It is attached to one side of the hemispherical cap 24 by dividing the annular groove (37, 37 ') space formed by forming a pair of separating ends (36, 36') into two zones, inflow and outflow at the boundary. External low-temperature air or refrigerant flows through the inlet pipe 32 and passes through the triangular channel 22 or the square channel 23 of the honeycomb circular body 27 all the way through the outlet pipe 33 installed on the other side. By dropping the temperature and pressure of ultra-high pressure gas in the process of outflow to the furnace, the structure of double-composite honeycomb high-pressure vessel of nozzle type composite has secured strength and operation safety.

In addition, between the hemispherical cap 24 and the numerous protruding pins 25 and 25 'formed on the outer surface of the honeycomb circular body 27, an axial composite using a high elastic wire 16 such as carbon fiber or glass fiber is used. By winding the wire 34, the helical composite wire 17, and the hoop composite wire 18 alternately in three directions to form a laminate, the strength and safety of the lightweight structure can be improved, and high-speed filling of ultra-high pressure gas becomes possible. In addition, a cylindrical nozzle-type composite honeycomb ultra high pressure vessel with a dramatically increased storage capacity is formed.

In the present invention, the shape and number of the triangular channel or square channel connecting between the inner container and the outer container, the shape and number of the support plate, the screw or welding method for fastening the hemispherical cap, the installation position of the inlet pipe and the outlet pipe The number, the angle of winding the high elastic wire, etc. can be variously changed according to the design method of the composite honeycomb ultra-high pressure vessel.

The present invention described above is not limited to the structure and operation as shown and described. In other words, the present invention is susceptible to various changes and modifications within the spirit and scope of the appended claims.

10: torso 11: plug
12: dome 13: protrusion tab
14,14 ': Female thread 15: Valve
16: High elastic wire 17,17 ', 17'': Helical direction composite wire
18,18 ', 18'': Hoop direction composite wire 19: Composite wire laminated part
20: inner container 21: outer container
22: triangular channel 23: square channel
24,24 ': Hemispherical cap 25,25': Protruding pin
26,26 ': Support plate 27: Honeycomb round body
28,28 ': Male thread 29,29': Outer weld line
30: safety valve 31: on-off valve
32: inlet pipe 33: outlet pipe
34: axial composite wire 35,35 ': inner weld line
36,36 ': Separation stage 37,37': Annular groove

Claims (4)

A plurality of triangular channels 22 or square channels 23 formed between the cylindrical inner container 20 and the outer container 21, and a plurality of radial support plates 26, 26 'in the inner container 20 in the axial direction Extruded honeycomb round body (27) to be integral with
In addition, the external thread (28,28 ') formed on the outer edge of the hemispherical cap (24,24') formed in a hemispherical shape to the female thread (14,14 ') formed on the inner diameter side of the inner container 20, The end of the outer container 21 forms a honeycomb ultra-high pressure vessel welded to have an L-shaped end formed on the outermost side of the hemispherical caps 24 and 24 'and an outer welding line 29 and 29'.
In addition, the on-off valve 30 is fastened to the female screw 14 formed to protrude in the center of the hemispherical cap 24,
In addition, the refrigerant body introduced through the inlet pipe 32 fastened to the female screw 14 formed on the outer edge of the hemispherical cap 24 is discharged through the triangular channel 22 or the square channel 23. To escape)
In addition, an axial composite wire 34 is formed by using a high elastic wire 16 between the outer container 21 and a number of protruding pins 25 and 25 'protruding from the outer surfaces of the hemispherical caps 24 and 24'. , Composite honeycomb ultra-high pressure vessel, characterized in that the laminate is formed by winding the helical direction composite wire (17), the hoop direction composite wire (18) alternately in three directions. The method of claim 1,
The ends of the inner container 20 and the outer container 21 constituting both sides of the honeycomb circular body 27 are opposed to both ends of the L-shape formed at the outer edges of the hemispherical caps 24 and 24 ', respectively. Numerous welding pins (25, 25) formed on the outer surface of the outer container 21 and the hemispherical cap (24, 24 ') having the inner welding line (35, 35') and the outer welding line (29, 29 ') by sequentially welding A composite honeycomb ultra-high pressure vessel, characterized in that a laminate is formed by alternately winding axial composite wire (34), helical composite wire (17), and hoop composite wire (18) in three directions. The method of claim 1,
Female threads on the inner diameter side and the outer diameter side of the nozzle-shaped domes 12 and 12 'integrally formed by reducing the cross-sectional areas of both ends of the inner container 20 and the outer container 21 constituting both of the honeycomb circular bodies 27. (14,14 ') and male threads (28,28') are formed and fastened with screws formed on the small hemispherical caps (24, 24 '),
The outermost container 21 and the hemispherical cap 24 having outer weld lines 29 and 29 'are welded by welding the outermost ends of the hemispherical caps 24 and 24' contacting the outer diameter side surfaces of the domes 12 and 12 '. The axial composite wire 34, the helical composite wire 17 and the hoop composite wire 18 are alternately wound in three directions between a number of protruding pins 25 and 25 'formed on the outer surface of the 24'). Forming a stack,
In addition, the refrigerant body introduced through the inlet pipe 32 fastened to the female screw 14 formed on the outer edge of the hemispherical cap 24 is inside the upper end of the honeycomb circular body 27 and the hemispherical cap 24. Composite honeycomb ultra high pressure, characterized in that formed through the annular groove 37 formed between the space to pass through the triangular channel 22 or the square channel 23 to the annular groove 37 'and the outlet pipe 33. Vessel. The method of claim 3,
One side of the honeycomb circular body 27 is sealed, and the other side of the inner vessel 20 and the outer vessel 21 is reduced in cross-sectional area between the inner diameter side and the outer diameter side of the nozzle-shaped dome 12 formed integrally. The female thread 14 and the male thread 28 are respectively formed and fastened with screws formed in the small hemispherical cap 24, and the outermost end of the hemispherical cap 24 in contact with the outer diameter side of the dome 12 is welded. An axial composite wire 34 and a helical composite wire 17 between an outer container 21 having an outer weld line 29 and a number of protruding pins 25 and 25 'formed on the outer surface of the hemispherical cap 24. , Alternately winding the hoop direction composite wire 18 in three directions to form a laminate,
In addition, the annular groove (37,37 ') divided into two zones by a pair of separation ends (36,36') formed between the upper end of the honeycomb circular body 27 and the inner space of the hemispherical cap (24). A space, and the refrigerant body introduced through the inlet pipe 32 passes through the triangular channel 22 or the square channel 23 straight and then flows out through the other outlet pipe 33. Honeycomb ultra high pressure container.

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