CN115289910A - Military bulletproof intelligent house and manufacturing method thereof - Google Patents

Abstract

The invention relates to a military bulletproof intelligent house capable of damping bullet penetration and having heating, heat preservation and humidification functions and a manufacturing method thereof, wherein a house wall column is a bulletproof heat preservation wall column, and a charging storage battery is arranged in the bulletproof heat preservation wall column; the house wallboard is a bulletproof heat-insulation wallboard, and the bulletproof heat-insulation board is an electric heating board; the house roof is a bulletproof roof, a solar charging panel or a wind power generator is arranged on the surface of the bulletproof roof, a power supply generated by the solar charging panel or the wind power generator is connected with a charging battery through a connecting wire and a charger, a temperature and humidity infrared sensing controller controls whether a graphene electric heating film in the bulletproof heat-insulation wall board works or not, controls whether a graphene electric heating film in the bulletproof heat-insulation wall column works or not and controls whether a humidifier works or not according to return signals detected by a temperature sensor, a humidity sensor, an infrared sensor and a pressure sensor, and a temperature and humidity red induction controller is provided with a pressure alarm; the door frame, the door and the window are bulletproof door frames, bulletproof doors and bulletproof windows.

Description

Military bulletproof intelligent house and manufacturing method thereof

Technical Field

The invention relates to a military bulletproof intelligent house which can damp bullet penetration, has heat insulation and heat preservation functions, and can realize electric heating and humidification and a manufacturing method thereof, which are mainly used for frontier defense sentries, barracks, hospitals and command rooms and belong to the field of manufacturing of bulletproof heat-preservation military houses.

Background

In recent years, although the lodging barracks for soldiers are constructed by fast-assembling color steel plates with the thickness of 100mm, the heat preservation effect is greatly improved, the indoor temperature can reach 10-12 ℃, but the energy consumption is high, the logistics support pressure is high, and more importantly, the barracks do not have the bulletproof function and also do not have the attack alarm function.

Disclosure of Invention

The design purpose is as follows: the defects in the background technology are avoided, and the military bulletproof intelligent house capable of damping bullet penetration, insulating heat and preserving heat and realizing electric heating and humidification and the manufacturing method are designed.

The design scheme is as follows: the design purpose is realized. The invention is in structural design: 1. the design that one layer or a plurality of layers of aramid fiber III loom cloth are solidified by high-strength, high-toughness and high-hardness water-based resin powder to form the bulletproof plate is one of the technical characteristics of the invention. The purpose of this design is: (1) The aramid fiber III is a ternary polymerization para-aromatic polyamide fiber with a heterocyclic ring structure, is formed by copolycondensation of three monomers, namely p-phenylenediamine, paraphthaloyl chloride, diamine containing a heterocyclic ring structure and the like, and is called aramid fiber III and also called heterocyclic aramid fiber. The heterocyclic structure of the aramid fiber III enables the aramid fiber III to have ultrahigh strength (domestic) tensile strength of 5.0 GPa-5.5 GPa and ultrahigh modulus (domestic elastic modulus of 130 GPa-160 GPa), has excellent performances in the aspects of high temperature resistance, impact resistance, wear resistance, wave transmission and the like, and is more beneficial to compounding of fibers and resin, so that the comprehensive anti-elasticity performance is more excellent. In addition, aramid fiber III also overcomes the defects of poor ultraviolet resistance and the like of aramid fiber II and PBO fiber, and aramid fiber III can be said to be mass-produced organic fiber with the best comprehensive performance in the world at present. (2) The ultrahigh tensile breaking strength of the aramid fiber III is the fundamental reason of excellent bulletproof performance. The higher the breaking strength of the ballistic resistant fiber, the greater the energy absorption at break of the fiber, and the better the ballistic resistance of the fiber. The elongation at break of the home-made aramid III (StaramidF-358) fiber is less than 3.5 percent, and the tensile strength reach 5.0 GPa-5.5 GPa. Secondly, the density of the aramid fiber III is only 1.43g/cm < 3 > -1.45 g/cm < 3 >, and the aramid fiber III belongs to a real light high-strength material. (3) The aramid fiber III has good heat resistance, can still maintain good mechanical property at 200 ℃, can be decomposed when the temperature reaches 538 ℃ in a nitrogen environment or 520 ℃ in an air environment, has very good thermal stability, and has the change condition of the tensile strength after the aramid fiber III is placed at 220 ℃ for 800 hours. The result shows that the retention rate of the fiber strength of the aramid fiber III in the air at the high temperature of 240 ℃ for 3 hours reaches 92%. More importantly: after the aramid fiber III is placed at the temperature of minus 40 ℃ for 4 hours, the breaking strength of the fiber is tested to be almost unchanged compared with that at room temperature. (4) The aramid fiber III is irradiated for 360 hours by adopting 340nm ultraviolet rays without water spraying (ultraviolet aging test standard: GB/T16585-1996), the result shows that the tensile strength of the aramid fiber III is only reduced by 7 percent, and for the bulletproof chip, the influence of illumination on the bulletproof chip is greatly reduced if the bulletproof chip is sealed in a vacuumized black light-proof, waterproof cloth cover with higher strength. (5) Aramid III has excellent flame retardant properties with a limiting oxygen index as high as 42 and does not burn off the flame, and aramid III has good moisture resistance and can be used for a long time without changing properties. The good comprehensive performance of the aramid III material is not only reflected in the excellent anti-elasticity performance of the aramid III material, but also has excellent performance in the aspect of light weight, and the aramid III bulletproof material has excellent performances of high strength, high toughness, impact resistance and the like, so the woven fabric woven by the aramid III filaments is organically combined with the high-strength high-toughness high-hardness water-based resin powder, and the wallboard with excellent bulletproof effect can be obtained. 2. The bulletproof panel is designed by adopting the UHMWPE fiber, which is the second technical characteristic of the bulletproof panel. The purpose of this design is: the ultra-high molecular weight polyethylene fiber (UHMWPE) is a fiber spun by polyethylene with the relative molecular mass of 100-500 ten thousand, is the fiber with the highest strength and the lightest specific gravity in the world at present, and has the strength 15 times higher than that of a steel wire, but is very light and 40% lighter than aramid fiber and other materials. The invention is used as the adhesion material of the light panel, which not only has reliable bulletproof effect, but also has light weight. 3. The design that one layer or a plurality of layers of carbon fiber woven cloth or woven net are solidified by high-strength, high-toughness and high-hardness water-based resin powder to form the bulletproof plate is the third technical characteristic of the invention. The purpose of this design is: the carbon fiber composite material has very strong mechanical property, and the specific strength and the specific modulus of the carbon fiber composite material are many times higher than those of other alloys with similar functions, namely, under the same tensile strength and tensile modulus, when the product meets the performance requirements, the weight of a carbon fiber product is far lower than that of the alloy product. Second, carbon fibers are typically made from Polyacrylonitrile (PAN) fibers by oxidation and higher temperature carbonization. When a gun is used to shoot a carbon fiber plate, because the dense net woven by the fibers is similar to a football goal net, the impact of the shooting object is absorbed by the whole net no matter which position of the net the shooting object hits. Therefore, the machine-woven cloth woven by the carbon fibers is organically combined with the high-strength high-toughness high-hardness aqueous resin powder, so that the bulletproof wallboard with excellent bulletproof effect can be obtained. 4. The flame-retardant heat-preservation fiber layer is compounded on one surface of the bulletproof plate through the flame-retardant adhesive, and the graphene electrothermal film is compounded on the flame-retardant heat-preservation fiber layer through the insulating adhesive. The purpose of this design is: although the flame-retardant heat-preservation fiber layer has the double functions of flame retardance and heat preservation, the heat absorption function of the flame-retardant heat-preservation fiber layer cannot form the function of heat absorption and heat storage at the room temperature of 20 ℃, and only the function of relatively preventing the room temperature from conducting outwards can be achieved, so that the effective temperature heat preservation value cannot be achieved under the condition of consuming the same energy consumption at the room temperature. According to the invention, the graphene electrothermal film is compounded on the flame-retardant heat-insulating fiber layer through the insulating adhesive, as the graphene has very good heat conduction performance, the heat conduction coefficient of pure defect-free single-layer graphene is as high as 5300W/mK, and the graphene is a carbon material with the highest heat conduction coefficient so far, the structure of the graphene is very stable, the carbon-carbon bond is only 1.42, the connection between carbon atoms in the graphene is very flexible, when an external force is applied to the graphene, the carbon atom surface can be bent and deformed, so that the carbon atoms do not need to be rearranged to adapt to the external force, the structure is kept stable, and the stable lattice structure enables the graphene to have excellent heat conduction. When the graphene electrothermal film is electrified to heat, part of heat energy generated by the graphene electrothermal film is dissipated indoors, and part of heat energy enters the flame-retardant heat-preservation fiber layer to be stored, when the storage value of the heat energy reaches the value equal to that of the graphene electrothermal film, almost all heat generated by the graphene electrothermal film enters the indoor space, so that the indoor temperature is quickly increased, because the graphene electrothermal film radiates heat energy through far infrared after being electrified, generally, the wavelength of the far infrared ray of the graphene electrothermal film is 5-12 microns, and the far infrared ray can be just absorbed by a human body to provide heat for the human body and provide heat for a room, the electric-heat conversion rate is up to 87%, and the electric-heat conversion rate is far higher than that of other electric appliances; after the graphite alkene electric heat membrane outage, can prevent indoor heat energy to run off fast again, play complementary effect. 5. The outer wall decoration panel is a rigid plate, and the pressure sensors are distributed on the back surface of the rigid plate. The purpose of this design is: when the bulletproof heat-insulating wallboard is impacted by external force (such as bullet, shell and mountain stone impact), the internal pressure sensor and the pressure sensor of the bulletproof heat-insulating wallboard can be triggered to send signals to the alarm in a wired or wireless mode to automatically alarm, and indoor soldiers are reminded to prepare for fighting or deal with the accident. 6. The charged accumulator shell in the bulletproof heat-insulating column shell is provided with a temperature sensor which controls whether an electric heating wire in the bulletproof heat-insulating column shell works or not through a temperature controller, and the bulletproof heat-insulating column shell is characterized in six technical characteristics. The purpose of this design is: the frontier defense sentry, barracks, hospitals and the like arranged in extremely cold weather have direct relevance to the capacity attenuation of the rechargeable storage battery due to the environment temperature of minus 40-60 ℃. The electric heating mode is adopted to act on the graphene bulletproof heating layer, and the graphene bulletproof heating layer is opposite to the rechargeable battery, so that the rechargeable battery is kept in a relatively warm environment by heat generated by the graphene bulletproof heating layer, and the capacity of the rechargeable battery is ensured to be in an optimal state. 7. The design of the bulletproof roof is the seventh design purpose of the invention. The purpose of this design is: the bulletproof roof is formed by sequentially overlapping a high elastic plate, a bulletproof plate, a heat-insulating flame-retardant heat-preservation fiber layer and a moisture absorption plate on the structural design, the high elastic plate has the function of ejecting a shell falling on the high elastic plate instantly, the shell is prevented from directly impacting the roof to detonate, the bulletproof plate plays a role in blocking the shell which is ejected instantly and exploded, the shell is prevented from penetrating through the roof to enter the house to hurt people, and the heat-insulating flame-retardant heat-preservation fiber layer plays a role in heat insulation, heat preservation and flame retardance; the moisture absorption plate is used for preventing indoor moisture from forming water vapor on the roof. 8. The design that the bulletproof heat-insulating wall column, the bulletproof heat-insulating wall plate and the bulletproof roof are provided with the pressure sensors is eight of the technical characteristics of the invention. The purpose of this design is: when the bulletproof heat-insulating wall column, the bulletproof heat-insulating wall plate and the bulletproof roof are impacted by external force, such as bullets, shells and external force, the pressure sensor in the bulletproof heat-insulating wall column, the bulletproof heat-insulating wall plate and the bulletproof roof carries the signal output end to be connected with the alarm to give an alarm, and the indoor personnel are reminded to prepare for fighting. 9. The design that the feed inlet of the humidifier is provided with the rapid snow melter is nine technical characteristics of the invention. The purpose of this design is: because the environment of the frontier defense sentry post and the barracks is quite bad, the climate is dry, water taking is quite difficult, the heavy snow can be used for sealing the mountain for half a year in winter, only snow or ice can be taken, and the rapid snow melting device is arranged at the inlet of the warmer to melt the snow rapidly, so that the water using requirement of the humidifier is met. 10. The design of the indoor infrared sensor is ten of the technical characteristics of the invention. The purpose of this design is: because the power consumption of frontier defense sentry post, barracks comes from solar charging panel or wind energy generator, its electric energy is very precious, in order to realize the purpose of using electricity wisely, when indoor infrared inductor detects that the barracks do not have the man-hour, then through the automatic cutout heating of temperature humidity infrared induction controller, supply wet power. 11. The invention relates to a design of a detachable quick-assembly shelter around a bulletproof heat-insulation house wall, which is the eleven technical characteristic of the invention. The purpose of this design is: the invention is characterized in that the shelter is arranged along the wall in the barracks and can be assembled or disassembled quickly, and the shelter has reliable bulletproof function, shooting hole and bulletproof observation window, so that soldiers can enter into the battle by using the shelter under the special condition that the barracks are overturned by shells and missiles to resist the enemies of the offenders.

The technical scheme 1: a military bulletproof intelligent house comprises a house, wherein a house wall column is a bulletproof heat-insulating wall column, and a charging storage battery is arranged in the bulletproof heat-insulating wall column; the house wallboard is a bulletproof heat-insulation wallboard, and an electric heating surface is arranged inside the bulletproof heat-insulation board; the house roof is a bulletproof roof, a solar charging panel or a wind power generator is arranged on the surface of the bulletproof roof, the power output end of the solar charging panel or the wind power generator is connected with the power supply end of a charging storage battery in the bulletproof heat-insulation wall column through a connecting line and a charger, the power output end of the charging storage battery is connected with the power input terminal of a temperature and humidity infrared induction controller through a power line, one path of a control switch in the temperature and humidity infrared induction controller is connected with a graphene electrothermal film positioned in the bulletproof heat-insulation wall panel, the other path of the control switch is connected with the power supply end of the graphene electrothermal film in the bulletproof heat-insulation wall column, the other path of the control switch is connected with the power supply end of a humidifier, the signal output ends of a temperature sensor, a humidity sensor, an infrared sensor and a pressure sensor are connected with the signal input end of the temperature and humidity infrared induction controller, and the temperature and humidity infrared induction controller is provided with an alarm at a red position; the door frame and the door are bulletproof door frames and bulletproof doors; the window is a bullet-proof glass window.

The technical scheme 2 is as follows: a manufacturing method of a military bulletproof intelligent house comprises the following steps of 1, manufacturing a high-strength high-toughness high-hardness bulletproof heating plate: 1) Fixing the periphery of one or more layers of aramid fiber III weaving machine cloth on the wall plate forming cavity wall and enabling the one or more layers of aramid fiber III weaving machine cloth to be in a tensioning state; 2) Preparing high-toughness and high-hardness water-based resin powder, namely water and a curing agent in proportion; 3) Uniformly stirring a curing agent and water in proportion to form a standby solvent A; 3) Adding high-strength, high-toughness and high-hardness aqueous resin powder into a container in proportion, and then pouring the standby solvent A into the high-strength, high-toughness and high-hardness aqueous resin powder to be uniformly mixed to form standby resin liquid B; 4) Injecting the spare resin liquid B into a wallboard forming die cavity, and demolding after standing for a plurality of minutes after air bubbles are extracted or exhausted by vacuum to obtain the high-strength high-toughness high-hardness bulletproof plate; 5) The flame-retardant heat-insulation fiber layer is compounded on one surface of the bulletproof plate through a bonding agent, and the graphene electrothermal film is compounded on the flame-retardant heat-insulation fiber layer through an insulating bonding agent; 2. the manufacturing method of the high-strength high-toughness high-hardness bulletproof fast-installation wall column comprises the following steps: 1) Fixing the periphery of one or more layers of aramid fiber III woven fabric on the wall column forming die cavity wall and enabling the one or more layers of aramid fiber III woven fabric to be in a tensioning state; 2) Preparing high-toughness high-hardness water-based resin powder, namely preparing water and a curing agent in proportion; 3) Uniformly stirring a curing agent and water in proportion to form a standby solvent A; 3) Adding high-strength, high-toughness and high-hardness aqueous resin powder into a container in proportion, and then pouring the standby solvent A into the high-strength, high-toughness and high-hardness aqueous resin powder to be uniformly mixed to form standby resin liquid B; 4) Injecting the standby resin liquid B into a wall column forming die cavity, and demolding after standing for a plurality of minutes after air bubbles are extracted or exhausted by vacuum to obtain a high-strength high-toughness high-hardness bulletproof column shell; 5) The flame-retardant heat-preservation fiber layer is compounded in the bulletproof column shell through a flame-retardant adhesive, the graphene electrothermal film is compounded on the flame-retardant heat-preservation fiber layer through an insulating adhesive, and the charging storage battery is positioned in the hollow body of the bulletproof heating column; 3. the manufacturing method of the high-elastic bulletproof roof comprises the following steps: the bulletproof roof is formed by sequentially superposing a surface layer, a high-elasticity plate, a bulletproof plate, a heat-insulation flame-retardant heat-preservation fiber layer and a moisture absorption plate, the high-elasticity plate is elastically connected with the bulletproof plate, the heat-insulation flame-retardant heat-preservation fiber layer is adhered to the outer surface of the bulletproof plate, the moisture absorption plate is adhered to the inner surface of the bulletproof plate, and the surface layer is adhered to the surface of the high-elasticity plate; installation: the high-strength high-toughness high-hardness bulletproof heating plate and the high-strength high-toughness high-hardness bulletproof fast-assembly wall column are in concave-convex splicing fit to form a wall body; solar charging panel and wind power generator install at the roof, the electric energy that solar charging panel or wind power generator produced charges to the rechargeable battery who is located shellproof heat preservation post through power lead and charging circuit, rechargeable battery output electric energy connects the power wiring end of temperature humidity infrared induction controller through the power introduction, temperature humidity infrared induction controller is according to installing at indoor temperature sensor, install the temperature sensor in shellproof heat preservation post shell, install the temperature at indoor humidity sensor and install the infrared inductive probe passback in indoor, humidity, infrared induction detection data: when the indoor temperature and humidity are lower than the set temperature or humidity in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be electrified for heating and the humidifier to be electrified for humidifying, otherwise, when the internal temperature and humidity reach the set temperature or humidity in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be powered off and the humidifier to be powered off; when the infrared induction probe detects that no person is in a room, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to power off and the humidifier to power off; when the temperature sensor arranged on the charged storage battery shell in the bulletproof heat-insulating wall column detects that the temperature of the charged storage battery shell is lower than the heat-insulating temperature of the charged storage battery set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film positioned in the bulletproof heat-insulating wall column to be electrified and heated to insulate the charged storage battery, otherwise, when the temperature in the bulletproof heat-insulating wall column reaches the temperature set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be powered off, so that the charged storage battery is always in the set temperature range.

Compared with the background technology, the invention firstly creates the stand column which is not only a frontier sentry post and a camp wall board, but also a precedent of a charging storage battery for the military bulletproof intelligent room; secondly, the bullet can be prevented from penetrating, the heat of the storage battery can be insulated, and the capacity attenuation of the rechargeable storage battery in an extremely cold environment can be prevented; thirdly, the column type bulletproof heat-insulation charging storage battery receives the converted electric energy of solar energy or wind energy, and can output the electric energy to heat and warm the frontier defense sentry post and the barracks wallboard and to work a humidifier, thereby fundamentally improving the living environment of soldiers in the frontier defense sentry post and the barracks; fourthly, the bullet-proof roof is designed, so that the bullet can be rebounded away from the bullet-proof roof at the moment of being hit by the bullet and the shell, and the bullet and the shell are prevented from directly damaging the bullet-proof roof; fifthly, the bulletproof heat-insulating wall board, the bulletproof heat-insulating wall column shell and the pressure sensor in the bulletproof roof are designed, so that a warning can be given at the moment when the bulletproof house is impacted, and a soldier is reminded to enter a battle post; and sixthly, designing a shelter around the bulletproof heat-preservation house wall, so that the bullet-proof house can enter into a barrier battle under the condition that the bulletproof house is overturned by shells and missiles and the condition that soldiers in the shelter are not killed by assault enemies.

Drawings

Fig. 1 is a schematic diagram of a military bulletproof smart house.

Fig. 2 is a schematic sectional structural diagram of a high-strength high-toughness high-hardness bulletproof heating plate I.

Fig. 3 is a schematic sectional structure diagram of a high-strength, high-toughness and high-hardness bulletproof heating plate II.

Fig. 4 is a schematic sectional structure diagram of a high-strength high-toughness high-hardness bulletproof heating plate III.

Fig. 5 is a schematic sectional structure diagram of a high-strength high-toughness high-hardness bulletproof heating plate.

Fig. 6 is a first structural schematic diagram of the military bulletproof intelligent house wall column.

Fig. 7 is a top schematic view of fig. 6.

Fig. 8 is a structural schematic diagram of a military bulletproof intelligent house wall column II.

Fig. 9 is a schematic top view of fig. 8.

Fig. 10 is a schematic top view of fig. 7, 9 in combination with a ballistic panel.

Figure 11 schematic side-sectional view of a ballistic insulation panel.

Fig. 12 is a schematic sectional view of the bulletproof roof.

Fig. 13 is a schematic view of a fast-assembled shelter.

Figure 14 is a schematic top cross-sectional view of the firing window of figure 13.

Detailed Description

Example 1: reference is made to fig. 1-10. A military bulletproof intelligent house comprises a house, wherein a house wall column is a bulletproof heat-insulating wall column 1, and a column charging storage battery 11 is arranged in the bulletproof heat-insulating wall column; the house wallboard is a bulletproof heat-insulation wallboard 2, and the bulletproof heat-insulation board surface is an electric heating surface; the house roof is a bulletproof roof 3, a solar charging panel 7 or a wind power generator 8 is arranged on the surface of the bulletproof roof, the power output end of the solar charging panel 7 or the wind power generator 8 is connected with the power supply end of a charging storage battery 11 in a bulletproof heat-insulation wall column through a connecting wire and a charger, the power output end of the charging storage battery 11 is connected with the power supply input terminal of a temperature and humidity infrared induction controller 10 through a power line, one path of a control switch in the temperature and humidity infrared induction controller 10 is connected with the power supply end of a graphene electrothermal film 4 in the bulletproof heat-insulation wall panel, the other path of the control switch is connected with the power supply end of the graphene electrothermal film 4 in the bulletproof heat-insulation wall column, and the other path of the control switch is connected with the power supply end of a humidifier 9, the signal output ends of a temperature sensor, a humidity sensor, an infrared sensor and a pressure sensor are connected with the signal input end of the temperature and humidity infrared induction controller 10, the temperature and humidity infrared induction controller 10 is provided with an alarm, and the temperature and humidity infrared induction controller 10 is combined with the prior art, and no description is given here. The door frame and the door are a bulletproof door frame 4 and a bulletproof door 5; the window is a bullet proof glass window 6.

The solar power generation panel or the wind driven generator charges the charging storage battery 8 in the bulletproof heat-insulation column shell through the temperature and humidity infrared induction controller 10 and the charging circuit, and the charging storage battery 8 supplies power and heats the electric heating layer 35 in the bulletproof heat-insulation column shell through the temperature and humidity infrared induction controller 10 and the quick connection power supply connecting line and supplies power and heats the electric heating layer 25 in the bulletproof heat-insulation plate 21. Namely, the temperature and humidity infrared induction controller 10 controls whether the graphene electrothermal film in the bulletproof heat-insulation wall board works, whether the graphene electrothermal film in the bulletproof heat-insulation wall column works and controls whether the humidifier works according to return signals detected by the medium pressure sensors arranged on the bulletproof heat-insulation wall board 2, the bulletproof heat-insulation wall column 1 and the bulletproof top board 3, and the temperature and humidity infrared induction controller is provided with a pressure alarm to alarm return signals detected by the medium pressure sensors on the bulletproof heat-insulation wall board 2, the bulletproof heat-insulation wall column 1 and the bulletproof top board 3.

The bulletproof window 6 is a double-layer sandwich bulletproof glass window. The bulletproof glass window 6 is of an outward turning structure. The double-layer sandwich bulletproof glass window is characterized in that 63 is formed by inner layer bulletproof glass 61, outer layer bulletproof glass 62 and a transparent weather-resistant adhesive layer, wherein the transparent weather-resistant adhesive layer 63 is positioned between the inner layer bulletproof glass 61 and the outer layer bulletproof glass 62 and bonds the inner layer bulletproof glass 61 and the outer layer bulletproof glass 62 into an integral structure.

And a concave-convex quick-mounting connecting structure is arranged between the bulletproof door frame 4 and the bulletproof heat-insulating wall column 1. The lower end of the bulletproof heat-insulation wall column 1 is provided with a flange 13, a fast-assembly connecting structure (bolt connecting structure) is arranged between the flange 13 and the ground, and the purpose of fast fixing with bolts on the ground is facilitated. The bulletproof door frame 4 and the bulletproof heat-insulating column shell 1 are structured, and heat-insulating materials are filled in the cavity of the bulletproof door frame. The bulletproof door 5 is in the same structure with the bulletproof heat-insulation board 2.

The bulletproof heat-insulation wall column 1 and the bulletproof heat-insulation wall plate 2 are in a concave-convex quick-assembly connecting structure, namely, the connecting surface of the bulletproof heat-insulation wall column 1 and the bulletproof heat-insulation wall plate 2 is a groove structure 12, and the connecting surface of the bulletproof heat-insulation wall plate 2 and the bulletproof heat-insulation wall column is in a tenon structure, such as a dovetail groove quick plug-in connecting mounting structure and a trapezoid concave-convex quick connecting structure.

One or more layers of aramid fiber III woven fabric 21 in the bulletproof heat-insulation wallboard 2 are solidified by high-strength, high-toughness and high-hardness water-based resin powder to form a sandwich board, a flame-retardant heat-insulation fiber layer 23 is compounded on one surface of the bulletproof board 22 through a flame-retardant adhesive, and a graphene electrothermal film 24 is compounded on the flame-retardant heat-insulation fiber layer 23 through an insulating adhesive.

The lower end of the wall column shell of the bulletproof heat-insulation fast-assembly wall column 8 is connected with a flange base 13, the charging storage battery 11 is positioned in the fast-assembly wall column shell, and the charging storage batteries 11 are connected in series or in parallel or in series and parallel to form a charging storage battery column.

One or more layers of aramid fiber III woven fabric 21 in the fast-assembly wall column shell are coated and solidified by high-strength, high-toughness and high-hardness water-based resin powder to form a bulletproof column shell (consisting of a plurality of bulletproof plates 22). The flame-retardant heat-preservation fiber layer 23 is compounded in the bulletproof column shell (formed by a plurality of bulletproof plates 22)) through a flame-retardant adhesive, the graphene electrothermal film 24 is compounded on the flame-retardant heat-preservation fiber layer 23 through an insulating adhesive, and the rechargeable battery 11 is positioned in the bulletproof column shell.

The graphene electrothermal film 24 and an aluminum foil layer 25 are arranged between the graphene electrothermal film and the graphene electrothermal film. The graphene electrothermal film 24 is provided with a heat conducting plate 26, and the heat conducting plate 26 is a metal heat conducting plate or a non-metal heat conducting plate, so as to conduct and dissipate heat generated by the graphene electrothermal film 24 indoors.

The exterior of the bulletproof cylindrical shell (which is composed of a plurality of bulletproof plates 22) is provided with an exterior wall decoration panel 27, and the exterior wall decoration panel 27 is used for decorating and disguising barracks (such as sentries, command posts and the like).

Be located and be equipped with temperature sensor (not drawn) on the 11 shells of rechargeable battery in the fast-assembling wall post shell, the signal input part of temperature sensor signal input termination temperature humidity infrared induction controller 10, the signal output termination actuating mechanism signal input part of temperature humidity infrared induction controller 10, switching on or the outage of 4 powers of actuating mechanism signal output part control graphite alkene electric heat membrane, switch on 4 work of graphite alkene electric heat membrane and produce the heat, 4 out-of-work of outage graphite alkene electric heat membrane, do not produce the heat. The purpose builds a suitable power supply working environment for rechargeable battery, prevents rechargeable battery electric quantity decay under extremely cold environment.

The bulletproof top is formed by sequentially overlapping a surface layer 31, a high-elastic plate 32, a bulletproof plate 33, a heat-insulating flame-retardant heat-insulating fiber layer 34 and a moisture absorption plate 35. The facing layer 31 is a weatherable nanolayer.

And a feed inlet of the humidifier 9 is provided with a quick snow melter. And a feed inlet of the humidifier 9 is provided with a quick snow melter. The fabrication of fast zone snow melter is prior art and will not be described herein.

Example 2: on the basis of example 1, the aramid fiber III woven cloth (21) can be replaced by an ultrahigh molecular weight polyethylene fiber woven cloth.

Example 3: on the basis of example 1, the aramid iii woven fabric (21) may be replaced with a carbon fiber woven fabric.

Example 4: based on embodiment 1, the exterior wall decoration panel 7 is a rigid plate, and pressure sensors (not shown) are disposed on the back surface of the rigid plate, and a signal output end of the pressure sensor is connected to an alarm (i.e., a voice alarm is disposed in the temperature and humidity infrared sensing controller 10, which is prior art and will not be described here), and the pressure sensors are one or more.

Example 5: the bulletproof roof is provided with a pressure sensor (not shown), the signal output end of the pressure sensor is connected with an alarm (namely, a voice alarm is arranged in the temperature and humidity infrared sensing controller 10, which belongs to the prior art and is not described herein), and the pressure sensor or the pressure sensors are one or more.

Example 6: reference is made to fig. 11. The upper end face and the lower end face of the bulletproof heat-insulation wallboard are wide in end face, and arc-shaped ends are the same as the thickness of the plate.

Example 7: on the basis of the embodiment 1, the military bulletproof intelligent house refers to an official lodging barracks.

Example 8: on the basis of the embodiment 1, the military bulletproof intelligent house is a military hospital house.

Example 9: on the basis of the above embodiment 1, the military bulletproof intelligent house is a house used for frontier sentry.

Example 10: on the basis of the above example 1, the military bulletproof intelligent house is a military living house.

Example 11: on the basis of the embodiment 1, the military bulletproof intelligent room is a battlefield command room.

Example 12: on the basis of the embodiment 1, the military bulletproof intelligent room refers to a military material storage user.

Example 13: reference is made to figures 13 and 14. The periphery of the indoor bulletproof heat-insulation wall is provided with a fast-assembling bulletproof shelter 14, and one or more layers of aramid fiber III woven fabric 21 in the bulletproof plate 14 are wrapped by high-strength, high-toughness and high-hardness aqueous resin powder and are cured and formed. One bulletproof plate 14 is equivalent to a bulletproof module, and a fast-assembly connecting structure (such as a mortise and tenon plug-in connecting structure and a mortise and tenon connecting part which is transversely provided with an anti-falling bolt) is arranged between the bulletproof module and the bulletproof module. The bulletproof shelter is provided with a shooting port 15, and a bulletproof glass observation window 16 is arranged above the shooting port 15. The fast-assembled bulletproof shelter 14 is composed of one or more bulletproof plates (modules) and a base for fixing the bulletproof plates, the base can enhance the stability of the bulletproof modules, and the plurality of bulletproof plates (modules) are connected into a rectangular or irregular shelter by quick buckles.

The bulletproof shelter is provided with a shooting port 15, and a switch is an automatic telescopic split bulletproof shooting door. The automatic stretching split bulletproof shooting door is composed of door pressure springs 17 and split bulletproof shooting doors 18, the door pressure springs 17 are located in wall pressure spring holes in the left middle side and the right middle side of a shooting port of a bulletproof shelter, the split bulletproof shooting doors 18 are in elastic fit with the door pressure springs 17 in the wall pressure spring holes in the left side and the right side respectively, and gun tube holes 19 are formed in the centers of the split bulletproof shooting doors. That is, when the barrel extends out of the barrel hole 19, the split bulletproof shooting door 18 automatically contacts with the barrel body of the barrel, and the split bulletproof shooting door 18 moves along with the barrel under the swinging of the barrel, so as to shoot enemies, prevent bullets from entering wounded persons through the shooting port 15 and protect the safety of fighters.

Example 14: on the basis of the embodiment, the manufacturing method of the military bulletproof intelligent room is characterized by comprising the following steps of: the manufacturing method of the high-strength high-toughness high-hardness bulletproof heating plate comprises the following steps: 1) Fixing the periphery of one or more layers of aramid fiber III weaving machine cloth on the wall plate forming cavity wall and enabling the one or more layers of aramid fiber III weaving machine cloth to be in a tensioning state; 2) The high-toughness high-hardness waterborne resin powder is prepared by mixing water and a curing agent in proportion (the specific detailed mixture ratio is the prior art, and is not described herein); 3) Uniformly stirring a curing agent and water in proportion to form a standby solvent A; 3) Adding high-strength high-toughness high-hardness aqueous resin powder into a container in proportion, and then pouring the standby solvent A into the high-strength high-toughness high-hardness aqueous resin powder to be uniformly mixed to form standby resin liquid B; 4) Injecting the spare resin liquid B into a wallboard forming die cavity, and demolding after standing for a plurality of minutes after air bubbles are extracted or exhausted by vacuum to obtain the high-strength high-toughness high-hardness bulletproof plate; 5) The flame-retardant heat-preservation fiber layer is compounded on one surface of the bulletproof plate through a flame-retardant adhesive, and the graphene electrothermal film is compounded on the flame-retardant heat-preservation fiber layer through an insulating adhesive;

the manufacturing method of the high-strength high-toughness high-hardness bulletproof fast-assembly wall column comprises the following steps: 1) Fixing the periphery of one or more layers of aramid fiber III weaving machine cloth on the wall of a wall column forming die cavity wall and enabling the one or more layers of aramid fiber III weaving machine cloth to be in a tensioning state; 2) The high-toughness high-hardness waterborne resin powder is prepared by mixing water and a curing agent in proportion (the detailed mixture ratio is the prior art and is not described herein); 3) Uniformly stirring a curing agent and water in proportion to form a standby solvent A; 3) Adding high-strength, high-toughness and high-hardness aqueous resin powder into a container in proportion, and then pouring the standby solvent A into the high-strength, high-toughness and high-hardness aqueous resin powder to be uniformly mixed to form standby resin liquid B; 4) Injecting the standby resin liquid B into a wall column forming die cavity, and demolding after standing for a plurality of minutes after air bubbles are extracted or exhausted by vacuum to obtain a high-strength high-toughness high-hardness bulletproof column shell; 5) The flame-retardant heat-insulation fiber layer is compounded in the bulletproof column shell through a flame-retardant adhesive, the graphene electrothermal film is compounded on the flame-retardant heat-insulation fiber layer through an insulating adhesive, and the charging storage battery is positioned in the hollow body of the bulletproof heating column;

the method for manufacturing the high-elastic bulletproof roof comprises the following steps: the bulletproof roof is formed by sequentially superposing a surface layer, a high-elasticity plate, a bulletproof plate, a heat-insulation flame-retardant heat-preservation fiber layer and a moisture absorption plate, the high-elasticity plate is elastically connected with the bulletproof plate, the heat-insulation flame-retardant heat-preservation fiber layer is adhered to the outer surface of the bulletproof plate, the moisture absorption plate is adhered to the inner surface of the bulletproof plate, and the surface layer is adhered to the surface of the high-elasticity plate;

the high-strength high-toughness high-hardness bulletproof heating plate and the high-strength high-toughness high-hardness bulletproof fast-assembly wall column are in concave-convex splicing fit to form a wall body; solar charging panel and wind power generator install at the roof, the electric energy that solar charging panel or wind power generator produced charges to the rechargeable battery who is located shellproof heat preservation post through power lead and charging circuit, rechargeable battery output electric energy connects the power wiring end of temperature humidity infrared induction controller through the power introduction, temperature humidity infrared induction controller is according to installing at indoor temperature sensor, install the temperature sensor in shellproof heat preservation post shell, install the temperature at indoor humidity sensor and install the infrared inductive probe passback in indoor, humidity, infrared induction detection data: when the indoor temperature and humidity are lower than the temperature or humidity set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be electrified for heating and the humidifier to be electrified for humidifying, otherwise, when the internal temperature and humidity reach the temperature or humidity set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be powered off and the humidifier to be powered off; when the infrared sensing probe detects that no person is in a room, the temperature and humidity infrared sensing controller instructs the graphene electrothermal film to be powered off and the humidifier to be powered off; when a temperature sensor arranged on a charged storage battery shell in the bulletproof heat-insulating wall column detects that the temperature of the charged storage battery shell is lower than the heat-insulating temperature of a charged storage battery set in a temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs a graphene electrothermal film positioned in the bulletproof heat-insulating wall column to be electrified and heated to insulate the charged storage battery, otherwise, when the internal temperature reaches the temperature set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be powered off, so that the charged storage battery is always in the set temperature range; and (3) arranging a bulletproof shelter: the bulletproof shelter is close to an indoor bulletproof wallboard, a bulletproof plate in the bulletproof shelter is formed to be a bulletproof module, a quick-assembly connecting and locking structure is arranged between the bulletproof module and the bulletproof module, a plurality of bulletproof modules form the quick-assembly bulletproof shelter, each bulletproof module is provided with a shooting port and an observation window, the shooting port is provided with an automatic oppositely-opened telescopic door, the center of the automatic oppositely-opened telescopic bulletproof door is provided with a gun tube hole, when a gun tube extends out of the gun tube hole, the opposite-opened bulletproof shooting door automatically contacts with a gun tube body in an elastic mode, the bulletproof shooting door moves along with the gun tube under the swinging of the gun tube, shooting enemies are achieved, bullets are prevented from entering wounded people through the shooting ports, and the safety of the fighters is protected.

It is to be understood that: although the above embodiments have been described in some detail for the purpose of illustrating the present invention, these descriptions are only intended to be a brief description of the design of the present invention, and are not intended to limit the design of the present invention, and any combination, addition or modification without departing from the scope of the present invention.

Claims (39)

1. The utility model provides a shellproof intelligent room for military use, includes the room, characterized by: the house wall column is a bulletproof heat-insulating wall column, and a charging storage battery is arranged in the bulletproof heat-insulating wall column; the house wallboard is a bulletproof heat-insulation wallboard, and an electric heating surface is arranged in the bulletproof heat-insulation wallboard; the house roof is a bulletproof roof, a solar charging panel or a wind driven generator is arranged on the surface of the bulletproof roof, the power output end of the solar charging panel or the wind driven generator is connected with the power supply end of a charging storage battery in the bulletproof heat-insulating wall column through a connecting line and a charger, the power output end of the charging storage battery is connected with the power input terminal of a temperature and humidity infrared induction controller through a power line, one path of a control switch in the temperature and humidity infrared induction controller is connected with a graphene electrothermal film in the bulletproof heat-insulating wall plate, the other path of the control switch is connected with the power supply end of the graphene electrothermal film in the bulletproof heat-insulating wall column, the other path of the control switch is connected with the power supply end of a humidifier, the signal output ends of a temperature sensor, a humidity sensor, an infrared sensor and a pressure sensor are connected with the signal input end of the temperature and humidity infrared induction controller, and the temperature and humidity red induction controller is provided with an alarm; the door frame and the door are bulletproof door frames and bulletproof doors; the window is a bullet-proof glass window.

2. The military ballistics smart home of claim 1, wherein: and a concave-convex quick-mounting connecting structure is arranged between the bulletproof door frame and the bulletproof heat-insulating wall column.

3. The military ballistics smart home of claim 1, wherein: the lower end of the bulletproof heat-insulation wall column is provided with a flange, and a fast-assembly connecting structure is arranged between the flange and the ground.

4. The military ballistics smart home of claim 1, wherein: and a concave-convex quick-mounting connecting structure is arranged between the bulletproof heat-insulating wall column and the bulletproof heat-insulating wall plate.

5. The military ballistics smart home of claim 1, wherein: the upper end face and the lower end face of the bulletproof heat-insulation wallboard are wide in end face, and arc-shaped ends are the same as the thickness of the plate.

6. The military ballistics smart home of claim 1, wherein: the bulletproof window is a double-layer sandwich bulletproof glass window.

7. The military ballistics smart home of claim 1, wherein: one or more layers of aramid fiber III weaving cloth in the bulletproof heat-insulation wallboard are solidified by high-strength, high-toughness and high-hardness water-based resin powder to form a sandwich board, the flame-retardant heat-insulation fiber layer is compounded on one surface of the bulletproof board through a flame-retardant adhesive, and the graphene electrothermal film is compounded on the flame-retardant heat-insulation fiber layer through an insulating adhesive.

8. The military ballistics smart home of claim 11, wherein: the outer wall decoration panel is a rigid plate, pressure sensors are distributed on the back surface of the rigid plate, the signal output ends of the pressure sensors are connected with an alarm, and one or more pressure sensors are arranged.

9. The military ballistics smart home of claim 1, wherein: the lower end of the bulletproof heat-insulation fast-assembly wall column shell is connected with the flange base, and the charging storage battery is positioned in the fast-assembly wall column shell.

10. The military ballistics smart home of claim 1, wherein: one or more layers of aramid fiber III weaving cloth in the fast-assembly wall column shell are coated and cured by high-strength, high-toughness and high-hardness aqueous resin powder to form a bulletproof column shell, the flame-retardant heat-preservation fiber layer is compounded in the bulletproof column shell through a flame-retardant adhesive, the graphene electrothermal film is compounded on the flame-retardant heat-preservation fiber layer through an insulating adhesive, and the rechargeable battery is positioned in the bulletproof column shell.

11. The military ballistic smart home of claim 10 wherein: the fast-assembling connecting surface between the fast-assembling wall column shell and the bulletproof wallboard is of a groove structure.

12. The military ballistics smart home of claim 7 or 10, wherein: the graphene electrothermal film is arranged with an aluminum foil layer between.

13. The military ballistics smart home of claim 7 or 10, wherein: the graphene electrothermal film is provided with a heat conducting plate, and the heat conducting plate is a metal heat conducting plate or a non-metal heat conducting plate.

14. The military ballistics smart home of claim 7 or 10, wherein: an exterior wall decoration panel is arranged outside the bulletproof cylinder shell.

15. The military ballistics smart home of claim 7 or 10, wherein: be located and be equipped with temperature sensor on the rechargeable battery shell in the fast-assembling wall column shell, temperature sensor signal input end connects the signal input part of temperature humidity infrared induction controller, and the signal output termination of temperature humidity infrared induction controller is actuating mechanism signal input end, and actuating mechanism signal output part controls switching on or the outage of graphite alkene electric heat membrane power.

16. The military ballistic smart home of claim 7 or 10, wherein: the aramid fiber III loom cloth can be replaced by ultra-high molecular weight polyethylene loom cloth.

17. The high strength, high toughness and high hardness bulletproof fast-assembled wall column as claimed in claim 7 or 10, wherein: the aramid III weaving cloth can be replaced by carbon fiber weaving cloth.

18. The military ballistic smart home of claim 1 wherein: the bulletproof top is formed by sequentially overlapping a surface layer, a high-elasticity plate, a bulletproof plate, a heat-insulation flame-retardant heat-preservation fiber layer and a moisture absorption plate.

19. The military ballistics smart home of claim 18, wherein: the surface layer is a weather-resistant nano layer.

20. The military ballistic smart home of claim 1 wherein: the bulletproof door frame and the bulletproof heat-insulating column shell structure are filled with heat-insulating materials in the cavity of the bulletproof door frame.

21. The military ballistic smart home of claim 1 wherein: the bulletproof door has the same structure as the bulletproof heat-insulation plate.

22. The military ballistics smart home of claim 1, wherein: the double-layer sandwich bulletproof glass window is composed of inner layer bulletproof glass, outer layer bulletproof glass and a transparent weather-resistant adhesive layer, wherein the transparent weather-resistant adhesive layer is positioned between the inner layer bulletproof glass and the outer layer bulletproof glass and adheres the inner layer bulletproof glass and the outer layer bulletproof glass into an integral structure.

23. The military ballistics smart home of claim 1, wherein: the bulletproof glass window is of a rocker-arm outwards-turning structure.

24. The military ballistics smart home of claim 1, wherein: the military bulletproof intelligent house is an official and soldier lodging barracks.

25. The military ballistic smart home of claim 1 wherein: the military bulletproof intelligent house is a military hospital house.

26. The military ballistics smart home of claim 1, wherein: the military bulletproof intelligent house is a house used for frontier sentry.

27. The military ballistics smart home of claim 1, wherein: the military bulletproof intelligent house refers to military living users.

28. The military ballistics smart home of claim 1, wherein: the military bulletproof intelligent house is a command house in a battlefield.

29. The military ballistics smart home of claim 1, wherein: the military bulletproof intelligent house is a military material storage standby house.

30. The military ballistic smart home of claim 1 wherein: the humidifier feed inlet is equipped with quick snow melter.

31. The military ballistics smart home of claim 1, wherein: and a pressure sensor is arranged on the bulletproof roof, and the signal output end of the pressure sensor is connected with an alarm.

32. The military ballistic smart home of claim 1 wherein: the periphery of the bulletproof heat-insulating wall in the house is provided with a fast-assembling bulletproof shelter, the bulletproof shelter is provided with a shooting port, and a bulletproof glass observation window is arranged above the shooting port.

33. The military ballistic smart home of claim 32 wherein: the fast-assembled bulletproof shelter is composed of one or more bulletproof plates and a base used for fixing the bulletproof plates, and the bulletproof plates are connected into a rectangular or irregular shelter through quick buckles.

34. The military ballistic smart home of claim 32 wherein: one or more layers of aramid fiber III loom cloth in the bulletproof plate are coated by high-strength, high-toughness and high-hardness water-based resin powder and are cured and formed.

35. The military ballistics smart home of claim 32, wherein: the bullet-proof shelter is provided with a firing port switch which is of an automatic telescopic structure.

36. The military ballistics smart home of claim 35, wherein: the automatic telescopic structure consists of a door pressure spring and split bulletproof shooting doors, the door pressure spring is positioned in wall pressure spring holes at the left middle side and the right middle side of a shooting port of the bulletproof shelter, the split bulletproof shooting doors are respectively in elastic fit with door pressure springs in wall pressure spring holes at the left side and the right side, and gun tube holes are formed in the centers of the split bulletproof shooting doors.

37. The military ballistics smart home of claim 34, wherein: the aramid fiber III loom cloth can be replaced by ultra-high molecular weight polyethylene loom cloth.

38. A high strength, high toughness, high hardness, ballistic resistant fast installed wall column according to claim 34 wherein: the aramid III weaving cloth can be replaced by carbon fiber weaving cloth.

39. A manufacturing method of a military bulletproof intelligent house is characterized by comprising the following steps: the manufacturing method of the high-strength high-toughness high-hardness bulletproof heating plate comprises the following steps: 1) Fixing the periphery of one or more layers of aramid fiber III weaving machine cloth on the wall plate forming cavity wall and enabling the one or more layers of aramid fiber III weaving machine cloth to be in a tensioning state; 2) Preparing high-toughness and high-hardness water-based resin powder, namely water and a curing agent in proportion; 3) Uniformly stirring a curing agent and water in proportion to form a standby solvent A; 3) Adding high-strength, high-toughness and high-hardness aqueous resin powder into a container in proportion, and then pouring the standby solvent A into the high-strength, high-toughness and high-hardness aqueous resin powder to be uniformly mixed to form standby resin liquid B; 4) Injecting the spare resin liquid B into a wallboard forming die cavity, and demolding after standing for a plurality of minutes after air bubbles are extracted or exhausted by vacuum to obtain the high-strength high-toughness high-hardness bulletproof plate; 5) The flame-retardant heat-preservation fiber layer is compounded on one surface of the bulletproof plate through a flame-retardant adhesive, and the graphene electrothermal film is compounded on the flame-retardant heat-preservation fiber layer through an insulating adhesive;

the manufacturing method of the high-strength high-toughness high-hardness bulletproof fast-assembly wall column comprises the following steps: 1) Fixing the periphery of one or more layers of aramid fiber III weaving machine cloth on the wall of a wall column forming die cavity wall and enabling the one or more layers of aramid fiber III weaving machine cloth to be in a tensioning state; 2) Preparing high-toughness and high-hardness water-based resin powder, namely water and a curing agent in proportion; 3) Uniformly stirring a curing agent and water in proportion to form a standby solvent A; 3) Adding high-strength, high-toughness and high-hardness aqueous resin powder into a container in proportion, and then pouring the standby solvent A into the high-strength, high-toughness and high-hardness aqueous resin powder to be uniformly mixed to form standby resin liquid B; 4) Injecting the standby resin liquid B into a wall column forming die cavity, and demolding after standing for a plurality of minutes after air bubbles are extracted or exhausted by vacuum to obtain a high-strength high-toughness high-hardness bulletproof column shell; 5) The flame-retardant heat-insulation fiber layer is compounded in the bulletproof column shell through a flame-retardant adhesive, the graphene electrothermal film is compounded on the flame-retardant heat-insulation fiber layer through an insulating adhesive, and the charging storage battery is positioned in the hollow body of the bulletproof heating column;

the method for manufacturing the high-elastic bulletproof roof comprises the following steps: the bulletproof top is formed by sequentially overlapping a surface layer, a high-elasticity plate, a bulletproof plate, a heat-insulation flame-retardant heat-preservation fiber layer and a moisture absorption plate, the high-elasticity plate is elastically connected with the bulletproof plate, the heat-insulation flame-retardant heat-preservation fiber layer is adhered to the outer side of the bulletproof plate, the moisture absorption plate is attached to the inner side of the bulletproof plate, and the surface layer is adhered to the surface of the high-elasticity plate;

the high-strength high-toughness high-hardness bulletproof heating plate and the high-strength high-toughness high-hardness bulletproof fast-assembly wall column are in concave-convex splicing fit to form a wall body; solar charging panel and wind power generator install at the roof, the electric energy that solar charging panel or wind power generator produced charges to the rechargeable battery who is located shellproof heat preservation post through power lead and charging circuit, rechargeable battery output electric energy connects the power wiring end of temperature humidity infrared induction controller through the power introduction, temperature humidity infrared induction controller is according to installing at indoor temperature sensor, install the temperature sensor in shellproof heat preservation post shell, install the temperature at indoor humidity sensor and install the infrared inductive probe passback in indoor, humidity, infrared induction detection data: when the indoor temperature and humidity are lower than the temperature or humidity set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be electrified for heating and the humidifier to be electrified for humidifying, otherwise, when the internal temperature and humidity reach the temperature or humidity set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be powered off and the humidifier to be powered off; when the infrared sensing probe detects that no person is in a room, the temperature and humidity infrared sensing controller instructs the graphene electrothermal film to be powered off and the humidifier to be powered off; when a temperature sensor arranged on a charging storage battery shell in the bulletproof heat-preservation wall column detects that the temperature of the charging storage battery shell is lower than the heat-preservation temperature of the charging storage battery set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film positioned in the bulletproof heat-preservation wall column to be electrified and heated to preserve the heat of the charging storage battery, otherwise, when the temperature in the bulletproof heat-preservation wall column reaches the temperature set in the temperature and humidity infrared induction controller, the temperature and humidity infrared induction controller instructs the graphene electrothermal film to be powered off, so that the charging storage battery is always in the set temperature range.

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