CN117468607B - Green energy-conserving assembled building wall - Google Patents

Abstract

The invention discloses a green energy-saving assembled building wall, which belongs to the technical field of assembled building walls and comprises two wall mechanisms, wherein a processing mechanism is arranged on one wall mechanism, the processing mechanism comprises a placing groove, a fan is arranged at the bottom of the inner wall of one protecting shell, a sensor is arranged on the rear surface of a sealing plate, a reinforcing frame is fixed in the placing groove, an L-shaped porous block is fixed on the upper side of the reinforcing frame, an adsorption layer is arranged in one groove of the reinforcing frame, a liquid storage box is arranged in the other protecting shell, and a controller is arranged on one side of the inner wall of one protecting shell.

Description

Green energy-conserving assembled building wall

Technical Field

The invention relates to the technical field of assembled building walls, in particular to an environment-friendly energy-saving assembled building wall.

Background

The fabricated building wall refers to a building mode in which building wall components are prefabricated in factories and then assembled and installed on a construction site.

The prior fabricated building wall has the advantages of improving construction efficiency, building quality, building safety, reducing building garbage and the like in the actual use process, but does not have a fire emergency treatment function, when a fire disaster happens in a house using the fabricated building wall, a large amount of harmful gas generated in the fire disaster process can be scattered in the house, and if the fire disaster emergency treatment equipment is not matched, the harmful gas filled in the house can possibly cause difficulty in breathing of indoor personnel, even choking, namely, the use effect of the fabricated building wall is reduced, and meanwhile, the use efficiency of the fabricated building wall is reduced.

Therefore, a new green energy-saving fabricated building wall needs to be proposed so as to solve the above-mentioned problems.

Disclosure of Invention

The invention aims to provide a green energy-saving assembled building wall body, which aims to solve the problems that the prior assembled building wall body provided by the background art does not have a fire emergency treatment function, when a fire disaster happens in a house using the assembled building wall body, a large amount of harmful gas generated in the fire disaster process can be scattered in the house, and people in the house can generate dyspnea and even choking caused by the adsorption of the harmful gas, namely the use effect of the assembled building wall body is reduced, and the use efficiency of the assembled building wall body is reduced.

In order to achieve the above purpose, the present invention provides the following technical solutions: the green energy-saving assembled building wall comprises two wall mechanisms, wherein a processing mechanism is arranged on one wall mechanism;

the utility model provides a processing mechanism includes the standing groove, the closing plate is installed to the notch department of standing groove, two symmetrical rectangular holes have been seted up to the inner wall of standing groove, every the protecting crust is all installed to the inside of rectangular hole between, one of them the fan is installed to the inner wall bottom of protecting crust, the mounting hole has been seted up to the positive surface of closing plate, the rear surface mounting of closing plate has the sensor, the inside activity of mounting hole has cup jointed the intake pipe, the connecting pipe is installed to the output of fan, first check valve is installed to the output of connecting pipe, the air duct is installed to the output of first check valve, the inside of standing groove is fixed with the enhancement frame, the upside of enhancement frame is fixed with L type porous piece, the adsorbed layer is set up to one of them recess inside of enhancement frame, the rectangular plate is installed to the entrance of enhancement frame, a plurality of cylinder holes have all been seted up to two recess inner wall bottoms and inner wall bottom, another the inside of protecting crust has placed the reservoir, the inlet end and the outlet end of reservoir all install the air duct, two back of the exhaust pipe is installed to the inside of two side of the reservoir, one side of the air duct is close to the top of two and is installed the air duct.

Preferably, the detection end of the sensor movably penetrates through the rear surface of the sealing plate, the outlet of the air inlet pipe is mounted with the input end of the fan, the input end of the air duct movably penetrates through the outer wall of one of the protective shells, the front surface and the rear surface of the L-shaped porous block are respectively contacted with the surface of the sealing plate and the inner wall of the placing groove, the output end of the air duct is positioned at the top of the L-shaped porous block, the front surface of the rectangular plate is contacted with the rear surface of the sealing plate, the front surface of the reinforcing frame is contacted with the rear surface of the sealing plate, the opposite ends of the two air ducts movably penetrate through the inner wall of the reinforcing frame, and the sensor and the fan are electrically connected with the controller.

Preferably, the entrance of intake pipe is fixed with the perforated plate, the inside of blast pipe is close to entrance and is fixed with the link, the surface mounting of link has the spring, the round platform is installed to the one end of spring, the inside of blast pipe is fixed to be cup jointed the ring piece, the round platform activity cup joints in the inside of ring piece, the fixed surface of round platform has the connecting block, the connecting block activity cup joints in the inside of blast pipe, the tube cap is installed to the exit of blast pipe, the wire guide has been seted up to the inner wall bottom of standing groove, the upside activity of strengthening frame is run through there is the conduit, the output of conduit and the input of wire guide meet mutually.

Preferably, each wall body mechanism comprises a wall body, a reinforcing layer is fixed on the front surface of each wall body, the same surface of each protecting shell movably penetrates through the surface of one reinforcing layer, and the same surface of each protecting shell is slidably embedded in the surface of one wall body.

Preferably, each front surface of the reinforcing layer is fixed with a protective layer, the placing groove is formed in the front surface of one of the protective layers, the rear surfaces of the two wall bodies are fixed with sound insulation layers, and the surfaces of the two sound insulation layers are fixed with heat insulation layers.

Preferably, each surface of the heat preservation is fixed with a fireproof layer, two same sides of the wall body are fixed with four hollow blocks and eight rectangular blocks, each of the top and the bottom of the wall body is provided with an assembly groove, and two inner thread blocks and hollow backing plates are respectively arranged in the assembly grooves.

Preferably, the stopper has been placed at the top of hollow backing plate, the inside activity of hollow backing plate has cup jointed the bolt pole, the one end screw thread of bolt pole cup joints the inside of internal thread piece, two the top of wall body all is fixed with two symmetrical installation pieces, two symmetrical draw-in grooves have all been seted up to the bottom of wall body.

Preferably, the two clamping grooves are respectively matched with the two mounting blocks, two symmetrical limiting holes are formed in the front surfaces of the fireproof layers, the fixing blocks are respectively mounted in the limiting holes, and the fixing blocks are respectively matched with the inner through holes of the mounting blocks.

Preferably, the front surface of each two fixing blocks respectively penetrates through the surface of each sound insulation layer, the surface of the heat insulation layer, the surface of the wall body, the surface of the reinforcing layer and the surface of the protective layer, and a plurality of first mounting grooves and a plurality of second mounting grooves are formed in one side of each wall body.

Preferably, each hollow block and each rectangular block are respectively matched with each second mounting groove and each first mounting groove, one end of each bolt rod penetrates through the bottom of the inner wall of one mounting groove and the bottoms of the inner walls of the plurality of first mounting grooves from top to bottom in a movable mode, and the bolt rods are movably sleeved between the interiors of the four hollow blocks.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, the treatment mechanism is arranged, so that the harmful gas in the house assembled by the assembled building walls can be adsorbed and reacted to be removed when a fire disaster occurs, namely, the inhalation of the harmful gas is reduced by personnel in the house, the environment is prevented from being polluted by the gas discharged into the environment, when the controller and the sensor cooperate to detect the fire disaster of the house, the harmful gas in the ceiling area of the house can be pumped away by firstly utilizing the cooperation of the controller, the fan, the air inlet pipe and the porous plate, and then, the dust or solid particles mixed in the gas can be filtered by utilizing the cooperation of the connecting pipe, the first one-way valve, the air duct, the placing groove, the reinforcing frame, the sealing plate and the L-shaped porous block.

2. The invention can realize that carbon monoxide in harmful gas is removed by utilizing the cooperation of the cylindrical hole, the reinforcing frame, the placing groove, the rectangular plate and the adsorption layer, and simultaneously, part of carbon dioxide, ammonia and sulfur dioxide are removed by adsorption, then, the residual carbon dioxide, sulfur dioxide, ammonia and hydrogen cyanide in the gas can be removed by utilizing the cooperation of the reinforcing frame, the placing groove, the second one-way valve, the vent pipe, the liquid storage box and sodium hydroxide solution in the liquid storage box, and then, the treated gas can be discharged to the environment by utilizing the cooperation of the reinforcing frame, the placing groove, the sealing plate, the cylindrical hole, the exhaust pipe and the pipe cover, and simultaneously, under the cooperation of the connecting frame, the spring, the circular ring block, the circular truncated cone and the connecting block, the foreign matters can be prevented from reaching the air inlet end of the exhaust pipe from the air outlet end of the exhaust pipe.

3. According to the invention, the wall body mechanisms are arranged, so that the two wall body mechanisms can be conveniently and quickly assembled together, when the two wall body mechanisms are required to be quickly assembled together, the two wall body mechanisms can be butted together by utilizing the prepared crane to be matched, then the stability of the butted wall body can be improved by utilizing the matching of the first mounting groove, the second mounting groove, the rectangular block and the hollow block, then the hollow block can be stably fixed in the corresponding second mounting groove by utilizing the matching of the bolt rod, the hollow base plate, the limiting block, the mounting groove and the internal thread block, namely, the two wall body mechanisms are fixed together, and then the use effect of the assembled wall body can be improved by utilizing the matching of the heat insulation layer, the sound insulation layer, the fireproof layer, the reinforcing layer and the protective layer, so that the purpose of green energy conservation is realized.

Drawings

FIG. 1 is a perspective view of an environment-friendly energy-saving fabricated building wall of the present invention;

FIG. 2 is a top view perspective view of a green energy-efficient fabricated building wall according to the present invention;

FIG. 3 is a side view, partially in perspective, of an environmentally friendly energy efficient fabricated building wall of the present invention;

FIG. 4 is an enlarged perspective view of the assembled building wall of FIG. 2A showing green energy conservation in accordance with the present invention;

FIG. 5 is an enlarged perspective view of the assembled building wall of FIG. 3B showing green energy conservation in accordance with the present invention;

FIG. 6 is a perspective view of a treatment mechanism portion of an environmentally friendly energy efficient fabricated building wall of the present invention;

FIG. 7 is another perspective view of an angled portion of an environmentally friendly energy efficient fabricated building wall of the present invention;

FIG. 8 is a bottom perspective view of a green energy-efficient fabricated building wall according to the invention;

FIG. 9 is a perspective view of a wall mechanism portion of an environmentally friendly energy efficient fabricated building wall of the present invention;

FIG. 10 is a perspective view of an air inlet pipe of an environment-friendly and energy-saving fabricated building wall of the invention;

FIG. 11 is a perspective view, partially in section, of an environmentally friendly energy efficient fabricated building wall of the present invention.

In the figure: 1. a wall mechanism; 101. a wall body; 102. a sound insulation layer; 103. a heat preservation layer; 104. a fire-blocking layer; 105. a reinforcing layer; 106. a protective layer; 107. a hollow block; 108. rectangular blocks; 109. an assembly groove; 110. an internal thread block; 111. a hollow backing plate; 112. a limiting block; 113. a bolt rod; 114. a mounting block; 115. a clamping groove; 116. a limiting hole; 117. a fixed block; 118. a first mounting groove; 119. a second mounting groove; 2. a processing mechanism; 201. a placement groove; 202. a sealing plate; 203. a rectangular hole; 204. a protective shell; 205. a blower; 206. a mounting hole; 207. a sensor; 208. an air inlet pipe; 209. a porous plate; 210. a connecting pipe; 211. a first one-way valve; 212. an air duct; 213. an L-shaped porous block; 214. a reinforcing frame; 215. an adsorption layer; 216. a rectangular plate; 217. a cylindrical hole; 218. a liquid storage box; 219. a vent pipe; 220. a second one-way valve; 221. an exhaust pipe; 222. a connecting frame; 223. a spring; 224. round bench; 225. a circular ring block; 226. a connecting block; 227. a tube cover; 228. a controller; 229. a wire guide; 230. a conduit.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 11, the present invention provides a technical solution: the green energy-saving assembled building wall comprises two wall mechanisms 1, wherein a processing mechanism 2 is arranged on one wall mechanism 1;

the processing mechanism 2 comprises a placing groove 201, a sealing plate 202 is installed at the notch of the placing groove 201, two symmetrical rectangular holes 203 are formed in the inner wall of the placing groove 201, a protecting shell 204 is installed between the interiors of the rectangular holes 203, a fan 205 is installed at the bottom of the inner wall of one protecting shell 204, a mounting hole 206 is formed in the front surface of the sealing plate 202, a sensor 207 is installed on the rear surface of the sealing plate 202, an air inlet pipe 208 is movably sleeved in the mounting hole 206, a connecting pipe 210 is installed at the output end of the fan 205, a first one-way valve 211 is installed at the output end of the connecting pipe 210, an air duct 212 is installed at the output end of the first one-way valve 211, a reinforcing frame 214 is fixed in the placing groove 201, an L-shaped porous block 213 is fixed on the upper side of the reinforcing frame 214, an adsorption layer 215 is arranged in one groove of the reinforcing frame 214, a rectangular plate 216 is installed at the inlet of the reinforcing frame 214, a plurality of cylindrical holes 217 are formed in the bottoms of the inner walls of the two grooves of the reinforcing frame 214, a liquid storage box 218 is placed in the interior of the other protecting shell 204, an air inlet end and an air outlet end of the liquid storage box 218 are installed at the air outlet end of the liquid storage box 218, an exhaust pipe 219 is installed at the back end of the air outlet 219, an exhaust pipe 219 is installed at the back end of the air pipe 219, one side of the air pipe is installed at the back end of the air pipe 219 is installed at the back of the air pipe 219, and one side of the air pipe is installed at the air pipe end of the air pipe is close to the top of the air pipe end of the air pipe is arranged at the air pipe, and one side of the air pipe is located at the air pipe, and the air device is located at the air-conditioner, and the air device is located at the air-storage device, and the air device is.

According to fig. 1-6 and 10, the detection end of the sensor 207 movably penetrates through the rear surface of the sealing plate 202, the outlet of the air inlet pipe 208 is mounted with the input end of the blower 205, the input end of the air duct 212 movably penetrates through the outer wall of one of the protecting shells 204, the front surface and the rear surface of the L-shaped porous block 213 are respectively contacted with the surface of the sealing plate 202 and the inner wall of the placing groove 201, the output end of the air duct 212 is positioned at the top of the L-shaped porous block 213, the front surface of the rectangular plate 216 is contacted with the rear surface of the sealing plate 202, the front surface of the reinforcing frame 214 is contacted with the rear surface of the sealing plate 202, the opposite ends of the two air ducts 219 movably penetrate through the inner wall of the reinforcing frame 214, the sensor 207 and the blower 205 are electrically connected with the controller 228, and whether the blower 205 is started or stopped can be controlled under the cooperation of the controller 228 and the sensor 207.

According to the embodiments shown in fig. 1-5, 10 and 11, the porous plate 209 is fixed at the inlet of the air inlet pipe 208, the connecting frame 222 is fixed at the inner part of the air outlet pipe 221 near the inlet, the spring 223 is mounted on the surface of the connecting frame 222, the round table 224 is mounted at one end of the spring 223, the round ring block 225 is fixedly sleeved in the inner part of the air outlet pipe 221, the round table 224 is movably sleeved in the round ring block 225, the connecting block 226 is fixedly mounted on the surface of the round table 224, the connecting block 226 is movably sleeved in the air outlet pipe 221, the pipe cover 227 is mounted at the outlet of the air outlet pipe 221, the wire hole 229 is formed in the bottom of the inner wall of the placing groove 201, the wire pipe 230 is movably penetrated at the upper side of the reinforcing frame 214, the output end of the wire pipe 230 is in butt joint with the input end of the wire hole 229, and the controller 228 can be connected with an external power supply conveniently under the cooperation of the wire pipe 230 and the wire hole 229.

According to the embodiments shown in fig. 1-5 and fig. 7-9, each wall mechanism 1 includes a wall body 101, an air duct 212 is buried in one of the wall bodies 101, the front surface of each wall body 101 is fixed with a reinforcing layer 105, the same surfaces of two protecting shells 204 are movably penetrated through the surface of one of the reinforcing layers 105, and the same surfaces of two protecting shells 204 are slidably embedded in the surface of one of the wall bodies 101, so that the components in the protecting shells 204 can be protected under the action of the protecting shells 204, so as to prolong the service life of the components.

According to the embodiments shown in fig. 1-3 and fig. 7-9, the protection layer 106 is fixed on the front surface of each reinforcement layer 105, the placement groove 201 is formed on the front surface of one of the protection layers 106, the sound insulation layers 102 are fixed on the rear surfaces of the two wall bodies 101, and the heat insulation layers 103 are fixed on the surfaces of the two sound insulation layers 102, so that the heat insulation effect of the wall mechanism 1 can be improved conveniently under the action of the heat insulation layers 103, namely, the heat loss of the interior of a building is reduced by improving the heat insulation effect of the wall mechanism 1, and the energy-saving effect is achieved.

According to the embodiments shown in fig. 1-3 and fig. 7-9, the fireproof layer 104 is fixed on the surface of each heat insulation layer 103, four hollow blocks 107 and eight rectangular blocks 108 are fixed on the same side of two wall bodies 101, and the top and bottom of each wall body 101 are provided with an assembly groove 109, wherein the inner screw blocks 110 and the hollow backing plates 111 are respectively placed in the two assembly grooves 109, and the two wall mechanisms 1 can be stably assembled and fixed together under the cooperation of the inner screw blocks 110, the hollow backing plates 111, the rectangular blocks 108, the hollow blocks 107, the first mounting grooves 118, the second mounting grooves 119 and the bolt rods 113.

According to the embodiment shown in fig. 1-3 and fig. 7-9, the top of the hollow pad 111 is provided with the limiting block 112, the inside of the hollow pad 111 is movably sleeved with the bolt rod 113, one end of the bolt rod 113 is in threaded sleeve connection with the inside of the internal thread block 110, the tops of the two wall bodies 101 are respectively fixed with two symmetrical mounting blocks 114, the bottoms of the two wall bodies 101 are respectively provided with two symmetrical clamping grooves 115, and the two wall bodies 1 can be stacked up and down conveniently in the clamping grooves 115, the fixing blocks 117, the limiting holes 116 and the mounting blocks 114.

According to the embodiments shown in fig. 1-3, 8 and 9, two clamping grooves 115 are respectively matched with two mounting blocks 114, two symmetrical limiting holes 116 are respectively formed in the front surfaces of two fireproof layers 104, fixing blocks 117 are respectively mounted in each limiting hole 116, each fixing block 117 is respectively matched with an inner through hole of each mounting block 114, and the mounting blocks 114 can be prevented from moving out from the inside of the clamping groove 115 conveniently under the matching of the fixing blocks 117 and the limiting holes 116.

According to the embodiments shown in fig. 1 to 3 and fig. 7 to 9, the front surfaces of each two fixing blocks 117 respectively penetrate through the surface of each sound insulation layer 102, the surface of the heat insulation layer 103, the surface of the wall body 101, the surface of the reinforcing layer 105 and the surface of the protective layer 106, and a plurality of first mounting grooves 118 and a plurality of second mounting grooves 119 are formed in one side of each wall body 101, so that the stability of two wall mechanisms 1 assembled together can be improved under the cooperation of the first mounting grooves 118, the hollow blocks 107, the rectangular blocks 108 and the second mounting grooves 119.

According to the embodiments shown in fig. 1-3 and fig. 7-9, each hollow block 107 and each rectangular block 108 are respectively matched with each second mounting groove 119 and each first mounting groove 118, one end of the bolt rod 113 sequentially penetrates through the bottom of the inner wall of one mounting groove 109 and the bottoms of the inner walls of the plurality of first mounting grooves 118 from top to bottom, the bolt rod 113 is movably sleeved between the interiors of the four hollow blocks 107, and the hollow blocks 107 can be prevented from moving out of the interiors of the matched second mounting grooves 119 under the action of the bolt rod 113.

The whole mechanism achieves the following effects: when two wall mechanisms 1 are required to be assembled together, at this time, one of the wall mechanisms 1 is moved to an area where a practical assembled building wall is required by using a crane, then the moved wall mechanism 1 is erected on the ground, then the erected wall mechanism 1 is fixed by using a prepared support frame, then a hollow pad 111 is placed on an upper assembly groove 109 of the erected wall mechanism 1, an internal thread block 110 is placed inside a lower assembly groove 109, and when the hollow pad 111 and the internal thread block 110 complete the placing operation, the other wall mechanism 1 is moved to the side of the erected wall mechanism 1 by using the crane directly, then the position fine adjustment is performed, then each hollow block 107 and each rectangular block 108 on the moved wall mechanism 1 are respectively abutted with each second installation groove 119 and each first installation groove 118 on the erected wall mechanism 1, when each hollow block 107 is respectively butted with each second mounting groove 119, and each rectangular block 108 is respectively butted with each first mounting groove 118, at this time, the bolt rod 113 is directly penetrated from the inside of the hollow base plate 111, then all the butted hollow blocks 107 are sequentially penetrated, when one end of the bolt rod 113 is contacted with the top of the internally threaded block 110, at this time, the bolt rod 113 is directly rotated downwards until one end of the bolt rod 113 is in threaded connection with the inside of the internally threaded block 110, then the sleeved limiting block 112 is placed at the top end of the bolt rod 113, the assembly operation of the two wall mechanisms 1 can be completed, when the assembly type wall body is completed in the mounting operation, the sealing plate 202 is directly removed, then the rectangular plate 216 is removed, then the adsorption layer 215 (composed of 5A molecular sieve particles) is placed inside one groove of the reinforcing frame 214, after the adsorption layer 215 is placed, the rectangular plate 216 is installed back to the initial position, then the two second check valves 220 are respectively removed from the two vent pipes 219, then the two vent pipes 219 are respectively removed from the input end and the output end of the liquid storage box 218, then the liquid storage box 218 is removed from the corresponding protecting shell 204, finally the sealing plug on the liquid storage box 218 is removed, and a proper amount of sodium hydroxide solution is directly injected into the liquid storage box 218 after the sealing plug is removed, when the injection operation of the solution is completed, the sealing plug is directly reset and installed back to the initial position, then the liquid storage box 218, the two vent pipes 219 and the two second check valves 220 are sequentially reset to the initial position, then the controller 228 and an external power supply are connected together by utilizing the cooperation of the lead pipes 230 and the lead holes 229, then the controller 228 is opened, a concentration threshold (concentration of harmful gas in case of fire) and a using program are set, then the sealing plate 202 is installed back to the initial position, when fire occurs in a house assembled by an assembled building wall, a large amount of harmful gas (carbon monoxide, hydrogen cyanide, carbon dioxide and a hydrogen dioxide) is generated in the interior because of the fire is built, the carbon dioxide is directly combusted in the house, the hydrogen dioxide and the oxygen sensor 207 are directly detected in the house area 207, and the sensor 207 is directly in the house area, and the sensor area is directly in the environment where the concentration is detected, the controller 228 will then compare the received concentration data with the concentration threshold value set in advance by the controller 228, when the concentration data received by the controller 228 is higher than the concentration threshold value set in advance by the controller 228, which indicates that a fire has occurred in the house, the controller 228 will directly start the blower 205, the started blower 205 will directly pump away the harmful gas in the ceiling area under the cooperation of the air inlet pipe 208 and the porous plate 209, the pumped away harmful gas will first pass through the through hole of the porous plate 209, then enter the air inlet pipe 208, then be directly conveyed to the inside of the connecting pipe 210 through the cooperation of the blower 205, then be conveyed to the inside of the first check valve 211, then be conveyed to the inside of the air duct 212, when the harmful gas enters the inside of the air duct 212, at this time under the action of the air duct 212, the harmful gas can be directly fed into the space formed by the placing groove 201, the sealing plate 202 and the reinforcing frame 214, in which the L-shaped porous block 213 is placed, then the harmful gas entering the space can be directly filtered under the action of the L-shaped porous block 213, then dust or solid particles in the filtered harmful gas can be directly remained in the space, the filtered gas can directly pass through the cylindrical hole 217 and enter the inside of the adsorption layer 215, when the gas enters the inside of the adsorption layer 215, carbon monoxide in the harmful gas can be completely adsorbed and removed, adsorption to ammonia, carbon dioxide and sulfur dioxide can also occur, then the harmful gas with carbon monoxide removed can be directly conveyed to the second one-way valve 220 near the direction of the adsorption layer 215 through the cooperation of the corresponding cylindrical hole 217, the sealing plate 202, the placing groove 201 and the reinforcing frame 214, the gas entering the second one-way valve 220 is directly conveyed into the breather pipe 219 connected with the second one-way valve, then the gas entering the breather pipe 219 is directly conveyed into the liquid storage box 218, when the gas enters the liquid storage box 218, sulfur dioxide and carbon dioxide in the harmful gas are directly converted into sodium sulfate, sodium carbonate and water under the action of sodium hydroxide solution in the liquid storage box 218, then hydrogen cyanide in the harmful gas can be hydrolyzed into formic acid and ammonia under the action of water, and meanwhile, the ammonia can be dissolved into the water under the action of water to form ammonia monohydrate, then the treated gas is directly discharged from the air outlet end of the liquid storage box 218, enters the breather pipe 219 connected with the liquid storage box, then enters the second one-way valve 220 connected with the liquid storage box, then the gas is conveyed to the input end of the exhaust pipe 221 under the cooperation of the sealing plate 202, the placing groove 201, the residual cylindrical hole 217 and the reinforcing frame 214, then the gas entering the interior of the exhaust pipe 221 directly pushes the round table 224 to move in the circular ring block 225, the round table 224 which moves at the moment also drives the connecting block 226 connected with the round table 224 to move, when the round table 224 moves out of the circular ring block 225, the treated gas entering the interior of the exhaust pipe 221 is conveyed to the direction of the pipe cover 227 directly, then passes through the through hole of the pipe cover 227 and is discharged to the environment, the gas discharged to the environment does not pollute the environment, and meanwhile, the situation of sucking harmful gas is reduced by personnel not leaving the interior of a fire house in time, so that the survival rate is improved, namely the use efficiency of the wall body mechanism 1 is improved, when the concentration data received by the controller 228 is lower than the concentration threshold value set by the controller 228 in advance, the situation of fire disaster is proved to be absent in the house, and when the wall body mechanism 1 is normally used, the sound insulation effect of the house can be improved under the action of the sound insulation layer 102, meanwhile, the heat insulation effect and fire resistance of the house can be improved under the cooperation of the heat insulation layer 103 and the fireproof layer 104, and meanwhile, the strength of the assembled wall body can be improved under the cooperation of the reinforcing layer 105, the protective layer 106 and the reinforcing frame 214.

The wall body 101 (formed by pouring concrete and a reinforcing steel bar frame), the fan 205, the sensor 207, the first check valve 211, the adsorption layer 215, the second check valve 220 and the controller 228 (PLC controller) are all of the prior art, and will not be explained here too much.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims (8)

1. The utility model provides an energy-conserving assembled building wall body of green which characterized in that: comprises two wall mechanisms (1), wherein a processing mechanism (2) is arranged on one wall mechanism (1);

the processing mechanism (2) comprises a placing groove (201), a sealing plate (202) is arranged at the notch of the placing groove (201), two symmetrical rectangular holes (203) are formed in the inner wall of the placing groove (201), a protecting shell (204) is arranged between the interiors of the rectangular holes (203), a fan (205) is arranged at the bottom of the inner wall of one protecting shell (204), a mounting hole (206) is formed in the front surface of the sealing plate (202), a sensor (207) is arranged on the rear surface of the sealing plate (202), an air inlet pipe (208) is movably sleeved in the mounting hole (206), a connecting pipe (210) is arranged at the output end of the fan (205), a first one-way valve (211) is arranged at the output end of the connecting pipe (210), an air duct (212) is arranged at the output end of the first one-way valve (211), a reinforcing frame (214) is fixed in the placing groove (201), an L-shaped porous block (213) is fixed on the upper side of the reinforcing frame (214), a plurality of inner wall (214) is arranged in the inner wall of the reinforcing frame (214), a plurality of cylindrical plates (214) are arranged at the bottom of the two reinforcing frames (214), a plurality of the bottom of the inner wall (214) is provided with a plurality of the inner wall (214), the other protecting shell (204) is internally provided with a liquid storage box (218), the air inlet end and the air outlet end of the liquid storage box (218) are respectively provided with a vent pipe (219), the opposite ends of the two vent pipes (219) are respectively provided with a second one-way valve (220), the inner wall of the placing groove (201) is close to the top and fixedly provided with a vent pipe (221) in a penetrating way, one side of the inner wall of one protecting shell (204) is provided with a controller (228), the detection end of the sensor (207) movably penetrates through the rear surface of the sealing plate (202), the outlet of the air inlet pipe (208) is connected with the input end of the fan (205), the input end of the air guide pipe (212) movably penetrates through the outer wall of one protecting shell (204), the front surface and the rear surface of the L-shaped porous block (213) are respectively contacted with the surface of the sealing plate (202) and the inner wall of the placing groove (201), the output end of the air guide pipe (212) is positioned at the top of the L-shaped porous block (213), the front surface of the sealing plate (216) and the rear surface of the sealing plate (202) are movably penetrated through the rear surface of the sealing plate (202), the front surface of the two reinforcing frames (214) are respectively contacted with the front surface of the air guide pipe (212) and the inner surface of the fan (205) respectively, the utility model discloses a solar cell module, including intake pipe (208), connecting block (226), wire hole (229) are offered to the inside of blast pipe (221), be close to entrance fixed connection frame (222) in intake pipe (208), surface mounting of connecting frame (222) has spring (223), round platform (224) are installed to one end of spring (223), the inside of blast pipe (221) is fixed to have cup jointed ring piece (225), round platform (224) activity cup joints in the inside of ring piece (225), the surface mounting of round platform (224) has connecting block (226), connecting block (226) activity cup joints in the inside of blast pipe (221), tube cap (227) are installed to the exit of blast pipe (221), wire hole (229) have been offered to the inner wall bottom of standing groove (201), the upside activity of strengthening frame (214) is run through and is had conduit (230), the output of conduit (230) is docked with the input of wire hole (229).

2. The green energy-saving fabricated building wall according to claim 1, wherein: every wall body mechanism (1) all includes wall body (101), every the positive surface of wall body (101) all is fixed with enhancement layer (105), and two the coplanar of protecting crust (204) all activity runs through the surface of one of them enhancement layer (105), and two the coplanar of protecting crust (204) all slides and inlays the surface of establishing at one of them wall body (101).

3. The green energy-saving fabricated building wall according to claim 2, wherein: every the front surface of reinforcement layer (105) all is fixed with inoxidizing coating (106), standing groove (201) are seted up in the front surface of one of them inoxidizing coating (106), two the rear surface of wall body (101) all is fixed with puigging (102), two the surface of puigging (102) all is fixed with heat preservation (103).

4. A green energy-saving fabricated building wall according to claim 3, wherein: every the surface of heat preservation (103) all is fixed with flame retardant coating (104), two the same side of wall body (101) all is fixed with four hollow blocks (107) and eight rectangle pieces (108), every the assembly groove (109) has all been seted up to the top and the bottom of wall body (101), and wherein two the inside of assembly groove (109) has placed internal thread piece (110) and hollow backing plate (111) respectively.

5. The green energy-saving fabricated building wall according to claim 4, wherein: stopper (112) have been placed at the top of hollow backing plate (111), bolt shank (113) have been cup jointed in the inside activity of hollow backing plate (111), the inside of internal thread piece (110) is cup jointed to the one end screw thread of bolt shank (113), two all be fixed with two symmetrical installation piece (114) at the top of wall body (101), two symmetrical draw-in groove (115) have all been seted up to the bottom of wall body (101).

6. The green energy-saving fabricated building wall according to claim 5, wherein: two draw-in grooves (115) respectively with two installation piece (114) looks adaptation, two spacing hole (116) of symmetry have all been seted up on the positive surface of flame retardant coating (104), every fixed block (117) are all installed to the inside in spacing hole (116), every fixed block (117) respectively with the inside through-hole looks adaptation of every installation piece (114).

7. The green energy-saving fabricated building wall according to claim 6, wherein: the front surfaces of every two fixed blocks (117) respectively penetrate through the surface of each sound insulation layer (102), the surface of the heat insulation layer (103), the surface of the wall body (101), the surface of the reinforcing layer (105) and the surface of the protective layer (106) in a movable mode, and a plurality of first mounting grooves (118) and a plurality of second mounting grooves (119) are formed in one side of each wall body (101).

8. The green energy-saving fabricated building wall of claim 7, wherein: each hollow block (107) and each rectangular block (108) are respectively matched with each second mounting groove (119) and each first mounting groove (118), one end of each bolt rod (113) sequentially penetrates through the bottom of the inner wall of one assembly groove (109) and the bottom of the inner walls of the plurality of first mounting grooves (118) from top to bottom in a movable mode, and each bolt rod (113) is movably sleeved between the interiors of the four hollow blocks (107).