CN110649307A - Hydrogen-oxygen fuel cell box based on mixed Poisson's ratio material - Google Patents

Abstract

The invention discloses an oxyhydrogen fuel cell box based on a mixed Poisson's ratio material, which belongs to the field of new energy automobiles. The invention comprises the following steps: a protection box and a battery pack; the protection box includes: the battery is integrally placed in the box body, the mixed Poisson ratio three-dimensional structure material is filled in the box body, the mixed Poisson ratio three-dimensional structure material enables the material to integrally generate a zero Poisson ratio effect in a mode that basic units of positive Poisson ratio materials and basic units of negative Poisson ratio materials are alternately arranged, four basic units of negative Poisson ratio are arranged on the periphery of each basic unit of positive Poisson ratio on each layer, four basic units of positive Poisson ratio are arranged on the periphery of each basic unit of negative Poisson ratio, and the composition structures of each layer are the same.

Description

Hydrogen-oxygen fuel cell box based on mixed Poisson's ratio material

Technical Field

The invention belongs to the field of new energy automobiles, and particularly relates to a hydrogen-oxygen fuel cell box based on a mixed Poisson's ratio material.

Background

With continuous progress and development of industrial technologies, more and more automobiles begin to adopt emerging energy sources to replace traditional fuel oil, most of the automobiles are powered by batteries, and the hydrogen-oxygen fuel battery has the advantages of complete replacement of the fuel oil, high energy conversion efficiency, zero emission, various fuel sources, flexible availability from renewable energy sources and the like on the fuel, so that the hydrogen-oxygen fuel battery is considered as one of important directions for realizing sustainable development of automobile industry in the future, and is also one of ideal schemes for solving global energy and environment.

The working principle of the hydrogen-oxygen fuel cell is as follows: during operation, hydrogen is supplied to the negative electrode, oxygen is supplied to the positive electrode, and the hydrogen is decomposed into positive ions H under the action of a catalyst on the negative electrode⁺And an electron e^-The hydrogen ions reach the anode through the proton exchange membrane, the electrons move to the anode along the external circuit, the electric load is connected in the external circuit, and on the anode, the oxygen and the hydrogen ions reaching the anode through the proton exchange membrane absorb the electrons reaching the anode to form water.

The biggest problem of the existing hydrogen-oxygen fuel cell lies in the safety problem. The hydrogen is extremely active, and once the high-pressure hydrogen storage device encounters severe collision, the hydrogen can be leaked and even explode, which is a great safety hazard of the hydrogen-oxygen fuel cell. The existing protection measures for hydrogen-oxygen fuel cells mainly aim at the protection of hydrogen cylinders, mainly starting from the walls of the hydrogen cylinders, and by material and structural reinforcement. However, in the face of severe collision, there is still a risk of leakage of the hydrogen cylinders, and other parts of the battery are not well protected, and damage to the hydrogen cylinders under severe collision also affects the operation and life of the battery.

Disclosure of Invention

The invention provides an oxyhydrogen fuel cell box based on a mixed Poisson's ratio material, which puts the integral structure of the oxyhydrogen fuel cell into a box body shell filled with the mixed Poisson's ratio, thereby reducing the damage to a hydrogen cylinder and a cell reaction part when an automobile meets severe collision, improving the integral safety of the oxyhydrogen fuel cell and ensuring the stable running of the automobile.

In order to achieve the purpose, the invention adopts the following technical scheme:

a hybrid poisson's ratio material based hydrogen-oxygen fuel cell case, comprising: a protection box and a battery pack; the protection box includes: the upper cover plate 1 is provided with a wire hole 20, so that wires connected with a positive electrode 30 and a negative electrode 22 of a battery part in the box body can be connected with a load outside the box body, and a clamping groove b26 corresponding to the positions of the positive electrode and the negative electrode is arranged on one side of the upper cover plate 1, which is provided with the wire hole 20; one side of the box body bottom plate 7 is provided with a groove 13 for placing the hydrogen cylinder 4 and a pump groove 10 for placing the pump body 14, the other side of the box body bottom plate 7 is provided with a clamping groove a25 aiming at the positions of the positive and negative electrodes, a hydrogen chamber is formed between the vertical baffle plate 21 and the negative electrode 22 and used for storing unreacted hydrogen, the vertical baffle plate 21 is provided with an air hole 11, the air hole 11 is connected with the pump body 14, the pump body 14 is used for circulating the residual hydrogen in each reaction, two catalyst layers platinum 23 are tightly attached to the negative electrode 22 and the positive electrode 30, a proton exchange layer 24 is arranged between the two catalyst layers platinum 23, the negative electrode 22 and the positive electrode 30 are connected with the catalyst layer 23, the catalyst layer 23 and the proton exchange layer 24 through welding, and the whole body is fixed in the clamping grooves a25 and the clamping groove; an oxygen chamber is formed between the inner wall of the box body 2 and the positive electrode 30, an oxygen hole 28 is formed in one side of the inner wall of the box body 2 close to the positive electrode, the inner part of the peripheral side wall of the box body 2 is in a hollow design, and is filled with a mixed poisson ratio three-dimensional structure material, the mixed poisson ratio three-dimensional structure material enables the material to integrally generate a zero poisson ratio effect through the mode that basic units of positive poisson ratio materials and basic units of negative poisson ratio materials are alternately arranged, four basic units of negative poisson ratio are arranged around each basic unit of positive poisson ratio on each layer, four basic units of positive poisson ratio are arranged around each basic unit of negative poisson ratio, and the composition structure of each layer is the same.

In the above structure, the basic unit of the positive poisson's ratio material is formed by two pieces of positive poisson's ratio material cells crossing at 90 degreesThe negative Poisson ratio material basic unit is formed by crossing two negative Poisson ratio material cells at an angle of 90 degrees; the positive Poisson ratio material cells and the negative Poisson ratio material cells are centrosymmetric graphs, 1/4 of an external outline is selected for parameter design, a 1/4 structure of the positive Poisson ratio material cells consists of a first transverse edge, a first oblique edge and a first vertical edge, a 1/4 structure of the negative Poisson ratio material cells consists of a second transverse edge, a second oblique edge, a third oblique edge and a second vertical edge, the side length of the first transverse edge is a/2, the side length of the first oblique edge is b, the side length of the first vertical edge is c/2, the side length of the second transverse edge is d/2, the side length of the second oblique edge is e, the side length of the third oblique edge is f, and the side length of the second vertical edge is g/2, wherein a is 10.4mm-11.2mm, b is c, g is 6mm-6.5mm, e is 3.8mm-4.1mm, and the thickness t of the cells with positive poisson ratio and negative poisson ratio.₁＝t ₂2 mm-2.5 mm, height h₁＝h₂The included angle between the first oblique edge and the horizontal plane is alpha, the included angle between the second transverse edge and the second oblique edge is beta, the included angle between the third oblique edge and the second vertical edge is sigma, and the included angle between the second oblique edge and the third oblique edge is theta, wherein beta is sigma;

the periphery of the upper cover plate 1 is provided with threaded holes d19, the lower side of the upper cover plate 1 is provided with a boss which can be clamped in the box body 2, the lower side of the boss is provided with a clamping groove b26 aiming at the positions of the positive electrode and the negative electrode, and the four corners of the boss and the four corners of the upper cover plate are chamfered; two threaded holes b9 are formed in two sides of each groove 13 of the box body bottom plate 7 and used for being matched with the integrated clamping ring 3 through long bolts 15 to fix the hydrogen cylinder 4, the pump body 14 is fixed through the small clamping ring 18, a circle of threaded holes a8 are formed in the periphery of the box body bottom plate 7, and four corners of the box body bottom plate are provided with fillets which are the same as those of the upper cover plate 1; the corresponding positions of the upper surface and the lower surface of the box body 2 are provided with screw holes c17 corresponding to the upper cover plate 1 and the box body bottom plate 7, thereby can carry out upper cover plate 1 through short bolt 12, the cooperation of box 2 and box bottom plate 7, four angular designs of box 2 have the fillet as upper cover plate 1 and box bottom plate 7, install filter screen 29 on the oxygen hole 28 and prevent dust, there are two hydrogen storage bottle 4 in every box 2, there is integral type valve port 5 hydrogen storage bottle 4 head, valve port 5 between two hydrogen storage bottle 4 passes through pipeline 6 and links to each other, valve port 5 of second hydrogen storage bottle 4 passes through pipeline 6 with pump body 14 entry and links to each other, two exports of pump body 14 opposite side also pass through pipeline 6 with the gas pocket on the vertical baffle 21 and link to each other, valve port 5 of first hydrogen storage bottle 4 also passes through pipeline 6 with gas pocket 16 on box 2 and links to each other, gas pocket 16 can be aerifyd to the hydrogen bottle through the.

Has the advantages that: the invention provides a hydrogen-oxygen fuel cell box based on a mixed Poisson's ratio material, wherein a hydrogen cylinder and a reaction part are integrated into a box body of the cell box, the box body is convenient to disassemble and assemble on the whole, internal equipment is convenient to overhaul, the occupied volume of the whole body is reduced, and the whole structure is convenient to protect a cell. The battery box body has the advantages that the four walls of the battery box body are of a hollow structure and are filled with mixed Poisson ratio materials, the mixed Poisson ratio three-dimensional structure materials enable the materials to integrally generate a zero Poisson ratio effect in a mode that basic units of positive Poisson ratio materials and basic units of negative Poisson ratio materials are alternately arranged, and the zero Poisson ratio materials can effectively reduce the impact on a hydrogen cylinder, an oxygen cylinder and a reaction part when an automobile is collided due to the excellent performance of the zero Poisson ratio materials in the aspect of energy absorption.

Drawings

FIG. 1 is a view showing the composition of a battery box;

FIG. 2 is a schematic view of a bottom plate of the case;

FIG. 3 is a map of the positive Poisson ratio cellular parameters;

FIG. 4 is a map of negative Poisson ratio cell parameters;

FIG. 5 is a schematic diagram of a single sheet of cells made of positive and negative Poisson's ratio material, the left diagram showing the positive Poisson's ratio material and the right diagram showing the negative Poisson's ratio material;

FIG. 6 is a basic unit diagram of positive and negative Poisson ratio materials, the left diagram is the positive Poisson ratio material, and the right diagram is the negative Poisson ratio material;

FIG. 7 is a schematic diagram of a single-layer positive and negative Poisson's ratio three-dimensional structure;

FIG. 8 is a three-dimensional filling diagram of a hybrid Poisson's ratio structure;

in the figure, 1 is an upper cover plate, 2 is a box body, 3 is an integrated snap ring, 4 is a hydrogen cylinder, 5 is a valve port, 6 is a pipeline, 7 is a box bottom plate, 8 is a threaded hole a, 9 is a threaded hole b, 10 is a pump groove, 11 is an air hole, 12 is a bolt, 13 is a groove for placing the hydrogen cylinder, 14 is a pump body, 15 is a long bolt, 16 is a box air hole, 17 is a threaded hole c, 18 is a small snap ring, 19 is a threaded hole d, 20 is an electric wire hole, 21 is a vertical baffle, 22 is a negative electrode, 23 is a catalyst layer platinum, 24 is a proton exchange layer, 25 is a clamping groove a, 26 is a clamping groove b, 27 is a through hole, 28 is an oxygen hole, 29 is a filter screen, and 30 is a positive.

Detailed Description

The invention is described in detail below with reference to the following figures and specific examples:

example 1

As shown in fig. 1, a hybrid poisson's ratio material based hydrogen-oxygen fuel cell case comprises: a protection box and a battery pack; the protection box includes: the upper cover plate 1 is provided with a wire hole 20, so that wires connected with a positive electrode 30 and a negative electrode 22 of a battery part in the box body can be connected with a load outside the box body, and a clamping groove b26 corresponding to the positions of the positive electrode and the negative electrode is arranged on one side of the upper cover plate 1, which is provided with the wire hole 20; as shown in fig. 2, a groove 13 for placing the hydrogen cylinder 4 and a pump groove 10 for placing the pump body 14 are designed on one side of the bottom plate 7 of the case, a clamping groove a25 for aligning and positioning the negative and positive electrodes is designed on the other side of the bottom plate 7 of the case, a hydrogen chamber is formed between the vertical baffle 21 and the negative electrode 22 for storing unreacted hydrogen, an air hole 11 is formed on the vertical baffle 21, the air hole 11 is connected with the pump body 14, the pump body 14 is used for circulating the residual hydrogen in each reaction, two platinum catalyst layers 23 are tightly attached to the negative electrode 22 and the positive electrode 30, a proton exchange layer 24 is arranged between the two platinum catalyst layers 23, and the negative electrode 22, the positive electrode 30, the catalyst layer 23 and the proton exchange layer 24 are connected by welding and are integrally fixed in the clamping grooves a25 and the clamping groove b 26; an oxygen chamber is formed between the inner wall of the box body 2 and the positive electrode 30, an oxygen hole 28 is formed in one side of the inner wall of the box body 2 close to the positive electrode, the inner part of the peripheral side wall of the box body 2 is in a hollow design, and a mixed poisson ratio three-dimensional structure material is filled in the inner part, as shown in fig. 7 and 8, the mixed poisson ratio three-dimensional structure material has a zero poisson ratio effect as a whole material in a mode that basic units of the positive poisson ratio material and basic units of the negative poisson ratio material are alternately arranged, four basic units of the negative poisson ratio are arranged around each basic unit of the positive poisson ratio on each layer, four basic units of the positive poisson ratio are arranged around each basic unit of the negative poisson ratio, and the composition structures of.

In the structure, the periphery of the upper cover plate 1 is provided with the threaded holes d19, the lower side of the upper cover plate 1 is provided with the boss which can be clamped in the box body 2, the lower side of the boss is provided with the clamping groove b26 aiming at the positions of the positive electrode and the negative electrode, and the four corners of the boss and the four corners of the upper cover plate are chamfered with round corners; two threaded holes b9 are formed in two sides of each groove 13 of the box body bottom plate 7 and used for being matched with the integrated clamping ring 3 through long bolts 15 to fix the hydrogen cylinder 4, the pump body 14 is fixed through the small clamping ring 18, a circle of threaded holes a8 are formed in the periphery of the box body bottom plate 7, and four corners of the box body bottom plate are provided with fillets which are the same as those of the upper cover plate 1; screw holes c17 corresponding to the upper cover plate 1 and the box bottom plate 7 are arranged at corresponding positions of the upper surface and the lower surface of the box body 2, thereby the upper cover plate 1 can be carried out through short bolts 12, the box body 2 and the box bottom plate 7 are matched, four corners of the box body 2 are designed with fillets which are the same as the upper cover plate 1 and the box bottom plate 7, a filter screen 29 is arranged on an oxygen hole 28 for dust prevention, two hydrogen storage bottles 4 are arranged in each box body 2, the heads of the hydrogen storage bottles 4 are provided with integrated valve ports 5, the valve ports 5 between the two hydrogen storage bottles 4 are connected through pipelines 6, the valve ports 5 of the second hydrogen storage bottle 4 are connected with the inlet of the pump body 14 through pipelines 6, two outlets at the other side of the pump body 14 are also connected with air holes on the vertical baffle plate 21 through pipelines 6, and the valve ports.

As shown in fig. 6, the basic unit of positive poisson ratio material is formed by two pieces of positive poisson ratio material cells crossing at 90 degrees, and the basic unit of negative poisson ratio material is formed by two pieces of negative poisson ratio material cells crossing at 90 degrees; the positive poisson ratio material cells and the negative poisson ratio material cells are in central symmetry patterns, 1/4 of the outer contour is selected for parameter design, and as shown in fig. 3 and 4, 1/4 structures of the positive poisson ratio material cells are formed byThe 1/4 structure of the negative poisson ratio material cell consists of a second transverse edge, a second oblique edge, a third oblique edge and a second vertical edge, the side length of the first transverse edge is a/2, the side length of the first oblique edge is b, the side length of the first vertical edge is c/2, the side length of the second transverse edge is d/2, the side length of the second oblique edge is e, the side length of the third oblique edge is f, and the side length of the second vertical edge is g/2, wherein a is 10.4mm, b is c is d is g is 6mm, e is f is 3.8mm, and the thicknesses t of the positive poisson ratio cell and the negative poisson ratio cell are 6mm and 3.8mm₁＝t₂2mm, height h₁＝h₂2mm, the first hypotenuse is alpha with the horizontal contained angle, the contained angle of second horizontal edge and second hypotenuse is beta, the contained angle of third hypotenuse and second vertical edge is sigma, the contained angle of second hypotenuse and third hypotenuse is theta, wherein alpha equals 30 degrees, beta equals 79 degrees, theta equals 68 degrees.

Example 2

As shown in fig. 1, a hybrid poisson's ratio material based hydrogen-oxygen fuel cell case comprises: a protection box and a battery pack; the protection box includes: the upper cover plate 1 is provided with a wire hole 20, so that wires connected to a positive electrode 30 and a negative electrode 22 of a battery part in the box body can be connected with a load outside the box body, and a clamping groove b26 corresponding to the positions of the positive electrode and the negative electrode is arranged on one side of the upper cover plate 1, which is provided with the wire hole 20; as shown in fig. 2, a groove 13 for placing the hydrogen cylinder 4 and a pump groove 10 for placing the pump body 14 are designed on one side of the bottom plate 7 of the case, a clamping groove a25 for aligning and positioning the negative and positive electrodes is designed on the other side of the bottom plate 7 of the case, a hydrogen chamber is formed between the vertical baffle 21 and the negative electrode 22 for storing unreacted hydrogen, an air hole 11 is formed on the vertical baffle 21, the air hole 11 is connected with the pump body 14, the pump body 14 is used for circulating the residual hydrogen in each reaction, two platinum catalyst layers 23 are tightly attached to the negative electrode 22 and the positive electrode 30, a proton exchange layer 24 is arranged between the two platinum catalyst layers 23, and the negative electrode 22, the positive electrode 30, the catalyst layer 23 and the proton exchange layer 24 are connected by welding and are integrally fixed in the clamping grooves a25 and the clamping groove b 26; an oxygen chamber is formed between the inner wall of the box body 2 and the positive electrode 30, an oxygen hole 28 is formed in one side of the inner wall of the box body 2 close to the positive electrode, the inner part of the peripheral side wall of the box body 2 is in a hollow design, and a mixed poisson ratio three-dimensional structure material is filled in the inner part, as shown in fig. 7 and 8, the mixed poisson ratio three-dimensional structure material has a zero poisson ratio effect as a whole material in a mode that basic units of the positive poisson ratio material and basic units of the negative poisson ratio material are alternately arranged, four basic units of the negative poisson ratio are arranged around each basic unit of the positive poisson ratio on each layer, four basic units of the positive poisson ratio are arranged around each basic unit of the negative poisson ratio, and the composition structures of.

In the structure, the periphery of the upper cover plate 1 is provided with the threaded holes d19, the lower side of the upper cover plate 1 is provided with the boss which can be clamped in the box body 2, the lower side of the boss is provided with the clamping groove b26 aiming at the positions of the positive electrode and the negative electrode, and the four corners of the boss and the four corners of the upper cover plate are chamfered with round corners; two threaded holes b9 are formed in two sides of each groove 13 of the box body bottom plate 7 and used for being matched with the integrated clamping ring 3 through long bolts 15 to fix the hydrogen cylinder 4, the pump body 14 is fixed through the small clamping ring 18, a circle of threaded holes a8 are formed in the periphery of the box body bottom plate 7, and four corners of the box body bottom plate are provided with fillets which are the same as those of the upper cover plate 1; screw holes c17 corresponding to the upper cover plate 1 and the box bottom plate 7 are arranged at corresponding positions of the upper surface and the lower surface of the box body 2, thereby the upper cover plate 1 can be carried out through short bolts 12, the box body 2 and the box bottom plate 7 are matched, four corners of the box body 2 are designed with fillets which are the same as the upper cover plate 1 and the box bottom plate 7, a filter screen 29 is arranged on an oxygen hole 28 for dust prevention, two hydrogen storage bottles 4 are arranged in each box body 2, the heads of the hydrogen storage bottles 4 are provided with integrated valve ports 5, the valve ports 5 between the two hydrogen storage bottles 4 are connected through pipelines 6, the valve ports 5 of the second hydrogen storage bottle 4 are connected with the inlet of the pump body 14 through pipelines 6, two outlets at the other side of the pump body 14 are also connected with air holes on the vertical baffle plate 21 through pipelines 6, and the valve ports.

As shown in fig. 6, the basic unit of positive poisson ratio material is formed by two pieces of positive poisson ratio material cells crossing at 90 degrees, and the basic unit of negative poisson ratio material is formed by two pieces of negative poisson ratio material cells crossing at 90 degrees; the material cells with positive Poisson's ratio and the material cells with negative Poisson's ratio are bothThe centrosymmetric graph is obtained by selecting 1/4 of the external outline for parameter design, as shown in fig. 3 and fig. 4, the 1/4 structure of the positive poisson ratio material cell consists of a first transverse edge, a first oblique edge and a first vertical edge, the 1/4 structure of the negative poisson ratio material cell consists of a second transverse edge, a second oblique edge, a third oblique edge and a second vertical edge, the side length of the first transverse edge is a/2, the side length of the first oblique edge is b, the side length of the first vertical edge is c/2, the side length of the second transverse edge is d/2, the side length of the second oblique edge is e, the side length of the third oblique edge is f, the side length of the second vertical edge is g/2, wherein a is 11.2mm, b is c, g is 6.5mm, e is f, f is 4.1mm, and the thickness t of the positive poisson ratio and the negative poisson ratio cell is t₁＝t₂2.5mm, height h₁＝h₂2.5mm, the first hypotenuse is alpha with the horizontal contained angle, the contained angle of second horizontal edge and second hypotenuse is beta, the contained angle of third hypotenuse and second vertical edge is sigma, the contained angle of second hypotenuse and third hypotenuse is theta, wherein alpha equals 30 degrees, beta equals 79 degrees, theta equals 68 degrees.

The foregoing is only a partial embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. A hybrid poisson's ratio material based hydrogen-oxygen fuel cell case, comprising: a protection box and a battery pack; the protection box includes: the upper cover plate (1) is provided with a wire hole (20), so that wires connected to a positive electrode (30) and a negative electrode (22) of a battery part in the box body can be connected with an external load of the box body, and a clamping groove b (26) aiming at the positions of the positive electrode and the negative electrode is arranged on one side of the upper cover plate (1) provided with the wire hole (20); one side of a box body bottom plate (7) is provided with a groove (13) for placing a hydrogen bottle (4) and a pump groove (10) for placing a pump body (14), the other side of the box body bottom plate (7) is provided with a clamping groove a (25) aiming at the positions of an anode and a cathode, a hydrogen chamber is formed between a vertical baffle plate (21) and the cathode (22) and used for storing unreacted hydrogen, the vertical baffle plate (21) is provided with an air hole (11), the air hole (11) is connected with the pump body 14, the pump body (14) is used for circularly reacting the residual hydrogen each time, two catalyst layers platinum (23) are tightly attached to the cathode (22) and an anode (30), a proton exchange layer (24) and the cathode (22) are arranged between the two catalyst layers platinum (23, the positive electrode (30) is connected with the catalyst layer (23), the catalyst layer (23) and the proton exchange layer (24) through welding and integrally fixed in the clamping grooves a (25) and b (26) on the upper cover plate (1) and the bottom plate (7); an oxygen chamber is formed between the inner wall of the box body (2) and the positive electrode (22), an oxygen hole (28) is formed in one side, close to the positive electrode, of the inner wall of the box body (2), the inner side wall of the periphery of the box body (2) is hollow, mixed Poisson ratio three-dimensional structure materials are filled in the box body, the mixed Poisson ratio three-dimensional structure materials are formed by alternately arranging basic units of positive Poisson ratio materials and basic units of negative Poisson ratio materials, four basic units of negative Poisson ratio are arranged on the periphery of each basic unit of positive Poisson ratio in each layer, four basic units of positive Poisson ratio are arranged on the periphery of each basic unit of negative Poisson ratio, and the forming structures of.

2. The hybrid poisson's ratio material-based hydrogen-oxygen fuel cell tank of claim 1, wherein the positive poisson's ratio material base unit is formed by two pieces of positive poisson's ratio material cells crossing at 90 degrees, and the negative poisson's ratio material base unit is formed by two pieces of negative poisson's ratio material cells crossing at 90 degrees.

3. The hydrogen-oxygen fuel cell box based on the mixed Poisson ratio material as claimed in claim 1 or 2, wherein the positive Poisson ratio material cells and the negative Poisson ratio material cells are centrosymmetric, 1/4 of the external outline is selected for parameter design, the 1/4 structure of the positive Poisson ratio material cells is composed of a first transverse edge, a first oblique edge and a first vertical edge, the 1/4 structure of the negative Poisson ratio material cells is composed of a second transverse edge, a second oblique edge, a third oblique edge and a second vertical edge, the side length of the first transverse edge is a/2, the side length of the first oblique edge is b, the side length of the first vertical edge is c/2, the side length of the second transverse edge is d/2, the side length of the second oblique edge is e, and the side length of the third oblique edge is bF, the length of the second vertical side is g/2, wherein a = 10.4mm-11.2mm, b = c = d = g =6mm-6.5mm, e = f =3.8mm-4.1mm, the thickness t of the cells with positive and negative poisson ratio₁=t₂=2mm ~ 2.5mm, height h₁=h₂=2mm ~ 2.5.5 mm, the first oblique side forms an angle α with the horizontal, the second transverse side forms an angle β with the second oblique side, the third oblique side forms an angle σ with the second vertical side, and the second oblique side forms an angle θ with the third oblique side, where β = σ.

4. The hydrogen-oxygen fuel cell box based on the mixed Poisson's ratio material as claimed in claim 1, wherein the underside of the upper cover plate (1) is designed with a boss which can be clamped in the box body 2, and the underside of the boss is designed with a clamping groove b (26) for the positions of the positive and negative electrodes.

5. The hybrid Poisson's ratio material-based hydrogen-oxygen fuel cell tank of claim 4, wherein the four corners of the boss and the four corners of the upper cover plate (1) are rounded.

6. The mixed Poisson's ratio material-based hydrogen-oxygen fuel cell box as claimed in claim 1, wherein two threaded holes b (9) are formed on both sides of each groove (13) of the box bottom plate (7) and used for matching with the integrated clamping ring (3) through long bolts (15) to realize the fixation of the hydrogen cylinders (4), and the pump body (14) is fixed through a small clamping ring (18).

7. The hybrid Poisson's ratio material-based hydrogen-oxygen fuel cell case according to claim 1 or 5, wherein four corners of the case (2) and four corners of the case bottom plate (7) are designed with rounded corners as same as the upper cover plate (1).

8. The hydrogen-oxygen fuel cell box based on the mixed Poisson's ratio material as claimed in claim 1, wherein threaded holes d (19) are designed around the upper cover plate (1) and the box body bottom plate (7), threaded holes c (17) corresponding to the upper cover plate (1) and the box body bottom plate (7) are formed in corresponding positions of the upper surface and the lower surface of the box body (2), and the upper cover plate (1), the box body (2) and the box body bottom plate (7) are fixedly connected through the threaded holes by short bolts (12).

9. The hybrid poisson's ratio material based hydrogen-oxygen fuel cell tank as claimed in claim 1, wherein a screen (29) is mounted on the oxygen holes (28).

10. The hydrogen-oxygen fuel cell box based on the mixed Poisson's ratio material as claimed in claim 1, wherein there are two hydrogen storage bottles (4) in each box body (2), the heads of the hydrogen storage bottles (4) have integrated valve ports (5), the valve ports (5) between the two hydrogen storage bottles (4) are connected through a pipeline (6), the valve port (5) of the second hydrogen storage bottle (4) is connected with the inlet of the pump body (14) through the pipeline (6), the two outlets on the other side of the pump body (14) are connected with the air hole on the vertical baffle plate (21) through the pipeline (6), and the valve port (5) of the first hydrogen storage bottle (4) is connected with the air hole (16) on the box body (2) through the pipeline (6).

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