CN113482195A

CN113482195A - Energy-saving assembled heating wall based on dynamic monitoring

Info

Publication number: CN113482195A
Application number: CN202110853177.6A
Authority: CN
Inventors: 范燕; 王爱莲
Original assignee: Jiangsu Xushi Construction Technology Co ltd
Current assignee: Jiangsu Xushi Construction Technology Co ltd
Priority date: 2021-07-27
Filing date: 2021-07-27
Publication date: 2021-10-08
Anticipated expiration: 2041-07-27
Also published as: CN113482195B

Abstract

The invention discloses an energy-saving assembly type heating wall based on dynamic monitoring, which comprises an embedded wallboard and an outer vertical face panel, wherein the embedded wallboard is installed on the inner wall of the outer vertical face panel, an inorganic titanium magnesium plate is installed on the inner wall of the embedded wallboard, grooves are formed in the top positions of the inner walls on the two sides of the inorganic titanium magnesium plate, strip-shaped dynamic monitoring boxes are installed on the outer surfaces on the two sides of the outer vertical face panel, connecting seats are welded at the four corners of the top of the outer vertical face panel, and central symmetrical connecting and leveling structures are installed at the bottoms of the two groups of bearing wallboards. The invention is provided with the shaft lever, the bearing wall board, the empty groove, the filling frame and the expansion net, under the matching of the shaft lever, the bearing wall board can be assisted to realize the function conversion of the partition, the capping board and the semi-capping board, and in addition, under the matching of the empty groove, the filling frame and the expansion net, the bearing wall board can be ensured to have the characteristics of light weight, sound insulation and high compressive strength, so that the device has better experience when being assembled and used.

Description

Energy-saving assembled heating wall based on dynamic monitoring

Technical Field

The invention relates to the technical field of assembled walls, in particular to an energy-saving assembled heating wall based on dynamic monitoring.

Background

The assembled wall body is prefabricated in a factory, and then the assembled wall body is transported to a construction site to be correspondingly assembled and installed in a concentrated mode and then can be used for quickly installing a building frame, so that the necessity of casting in the construction site is reduced, dust pollution is reduced, a good promoting effect on green construction and efficient construction is achieved, along with the deep humanity of an energy-saving and environment-friendly idea, the requirement of the energy-saving assembled wall body is greatly improved, and the assembled wall body is widely popularized in the assembly market.

The existing assembled wall body has the following defects:

1. the comparison document CN211850352U discloses an assembly wall for heating construction, "including a first outer decorative plate and a second outer decorative plate, a heating plate is arranged between the first outer decorative plate and the second outer decorative plate, a heating pipe is arranged in the heating plate, the heating pipe is communicated with a water inlet pipe, a filtering device is arranged between the water inlet pipe and the heating pipe, the filtering device includes a housing, a filtering layer is arranged in the housing, a water outlet of the housing is communicated with a water inlet of the heating pipe, and a side wall of the filtering layer is abutted to a circumferential inner wall of the heating pipe housing;

2. the comparison document CN110878599A discloses a function-differentiated prefabricated wall, wherein the single-layer wall is composed of cantilever type prefabricated component modules (including standard H-shaped components, corner L-shaped components, T-shaped components and cross-shaped components), light concrete wall panel modules (including solid wall panels, wall panels with windows and door holes) and auxiliary connecting modules (including nuts, filling materials and flexible sealants), wherein the cantilever type prefabricated component modules are connected through built-in connecting pieces to form a bearing structure of the wall, the light concrete wall panel modules and the cantilever type prefabricated component modules are spliced through built-in embedded pieces and the auxiliary connecting modules to form a complete single-layer wall, and then the upper wall and the lower wall realize the overall workability of all walls, floors and roofs of a house through a multi-layer wall vertical connecting mode. The prefabricated wall body is suitable for single-layer and multi-layer houses of various house types, the components are moderate in size, the prefabricated wall body is convenient to transport and install, the integrity after the assembly is finished is good, and the good balance between the assemblability and the overall cooperativity is achieved, but the device realizes the function partition on a single-layer plane through the combination of the solid wall plate, the wall plate with the window hole and the wall plate with the door hole when the function partition is carried out, the function switch between the single-layer partition plate body and the capping plate body cannot be realized, and the device cannot realize the function partition between three-layer layers;

3. the reference document CN212506897U discloses an assembly wall body with good sound insulation effect for construction engineering, which comprises a wall body, wherein one side of the interior of the wall body is filled with silencing cotton, one end of the silencing cotton is fixedly provided with a mesh plate, one side of the wall body is provided with a slot, one side of the wall body, which is far away from the slot, is in interference connection with a connecting structure, the interior of the connecting structure comprises an inserted link, a spring A, a pressing plate, a rubber pad, a spring B and a clamping rod, two sides of the inserted link are provided with inner cavities, the interior of the inner cavities is in sliding connection with the pressing plate, two sides of one end of the inserted link are provided with grooves, the springs B are embedded and connected in the grooves, one end of the springs B is in clearance connection with the clamping rod, through the installed connecting structure, the walls can be rapidly connected and used, and workers can conveniently install and use the assembly wall body with large area, the installation efficiency can be improved, so that the installation and use effects of the assembled wall body are improved, but when the device is subjected to multi-module splicing and stacking treatment, a corresponding protection structure is lacked to enhance the integral shearing resistance of the spliced device, so that the safety of the spliced device is low;

4. reference CN108612231A discloses a building assembly wall body mounting structure, "including mounting bracket and supporting mechanism, the spout has been seted up on a mounting bracket surface, and the locating hole has been seted up to the bottom of spout, and the inside sliding fit of spout has positioning mechanism, and positioning mechanism rotates through cylindric lock and supporting mechanism to be connected one side, and the mounting bracket is double-phase face to face all to be seted up flutedly, and the mounting hole has been seted up to the bottom of mounting bracket, and positioning mechanism includes the slider, and a slider fixed surface has connecting block and spring housing. The wall body with looseness and inclination can be timely adjusted when the device is used for installing the wall body through the installation frame, the supporting mechanism and the positioning mechanism, the installation structure is firm and stable, the installation quality of a light body and the service life of the wall body are guaranteed, the device is convenient to install and remove and can be recycled, damaged parts can be timely replaced, the working efficiency and the economic benefit are improved, but when relevant components are connected, hiding processing of relevant connecting structures cannot be considered, and the leveling degree of the wall surface of the device is influenced.

Disclosure of Invention

The invention aims to provide an energy-saving assembly type heating wall based on dynamic monitoring, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an energy-saving assembly type heating wall based on dynamic monitoring comprises a pre-buried wallboard and an outer vertical face panel, wherein the pre-buried wallboard is installed on the inner wall of the outer vertical face panel, an inorganic titanium magnesium plate is installed on the inner wall of the pre-buried wallboard, grooves are formed in the top positions of the inner walls on the two sides of the inorganic titanium magnesium plate, and strip-shaped dynamic monitoring boxes are installed on the outer surfaces on the two sides of the outer vertical face panel;

the inner wall of recess is connected with the multifunctional plate body through the bearing, the multifunctional plate body is including axostylus axostyle, bearing wallboard, dead slot, packing frame and expansion net, the inner wall of recess is connected with the axostylus axostyle of arranging around two sets of through the bearing, the bearing wallboard is installed to the bottom of axostylus axostyle, the packing frame is installed to the inside gomphosis of bearing wallboard, the expansion net is all installed to the preceding back inner wall of packing frame, the inside of bearing wallboard is cut apart into the dead slot of symmetrical arrangement around through packing the frame, and just two sets of dead slots are located the place ahead and the rear of packing the frame respectively.

Preferably, full glass vacuum tube is installed to the inside equidistance of dynamic monitoring box, the internally mounted of full glass vacuum tube has solar panel, the internally mounted of dynamic monitoring box has a temperature-sensing ware, the both sides inner wall of inorganic titanium magnesium board all is equipped with the insulating heat conduction frame of caving in, the internally mounted of insulating heat conduction frame has the panel, the heating pipe is installed to the top equidistance of panel, heating pipe and panel electric connection, the panel is kept away from one side outer wall of inorganic titanium magnesium board and is installed No. two temperature-sensing wares, and No. two temperature-sensing wares and the wireless electric connection of a temperature-sensing ware.

Preferably, the connecting seat has all been welded in the top four corners of outer facade panel, the connecting seat is semi-open structure, buffer spring and a pressure sensors that the matrix was arranged are all installed to the both sides outer wall of connecting seat, and a pressure sensors is located four buffer spring's of group centre, the both sides of connecting seat are sprained mud and inside all is equipped with the intermediate layer, interbedded internally mounted has a state lamp ring of L type, a state lamp ring and a pressure sensors electric connection, sunken two pressure sensors in the inside diapire of connecting seat is installed, the inside diapire of connecting seat is equipped with hollow layer, the internally mounted on hollow layer has No. two state lamp rings.

Preferentially, it is two sets of central symmetry's connection leveling structure is installed to the inside bottom of bearing wallboard, connect leveling structure including rotating the flat dish, connecting threaded rod, reserve mouthful and No. three and reserve mouthful, the place ahead the inside of bearing wallboard is equipped with reserves mouthful and No. two and reserves mouthful, and the inner wall of reserving mouthful for two is equipped with the screw thread, the rear the inside of bearing wallboard is equipped with No. three and reserves mouthful, and the inside of reserving mouthful for three is equipped with the screw thread, the centre of a circle of reserving mouthful, reserving mouthful and reserving mouthful for two is located same axis, the inside threaded connection of reserving mouthful for two has connecting threaded rod, connecting threaded rod's front is installed and is rotated the flat dish, the diameter of rotating the flat dish is the same with the internal diameter of reserving mouthful for one.

Preferably, a reserve mouthful be the toper structure, and the tail end diameter of reserving mouthful the same with the diameter of reserving mouthful No. two, connecting rod's tail end runs through the inside that extends to reserving mouthful No. three, connecting rod and the comprehensive length of rotating the flat plate are less than the sum of the length of reserving mouthful, reserving mouthful No. two and reserving mouthful No. three.

Preferably, the inside of pre-buried wallboard is equipped with the puigging, the inside packing of puigging has the corn-on-cob, pre-buried pipeline and No. two pre-buried pipelines that the inside of pre-buried wallboard was equipped with run through, arranged from top to bottom, and pre-buried pipeline and No. two pre-buried pipelines all are located the below of puigging.

Preferably, humidity inductor and suggestion lamp strip are installed to one side inner wall of inorganic titanium magnesium board, and the suggestion lamp strip is located humidity inductor's top, suggestion lamp strip and humidity inductor electric connection.

Preferably, the outer vertical face panel body is composed of basalt fiber cloth, organic fiber cloth and a waterproof vapor-permeable plastic film, the organic fiber cloth is installed on the inner wall of the waterproof vapor-permeable plastic film, and the basalt fiber cloth is installed on the inner wall of the organic fiber cloth.

Preferably, the working steps of the wall body are as follows:

s1, when using the wall body to carry out dynamic detection, the first temperature sensor can be used to detect the environment temperature outside the wall body of the device, and the second temperature sensor can be used to detect the environment temperature inside the space formed by enclosing the wall body of the device, when the temperature value detected by the first temperature sensor and the temperature value detected by the second temperature sensor are both in lower level, the environment temperature outside and inside the device can be judged to be lower, at the moment, the heating pipe can be started, so that the wall body can carry out heating operation, when the temperature value detected by the first temperature sensor is obviously higher than the temperature value detected by the second temperature sensor, the indoor environment temperature can be judged to be lower than the environment temperature outside the wall body, at the moment, the heating pipe does not need to be started, the solar panel inside the full glass vacuum pipe can be used for photoelectric conversion, then the electric energy is stored inside the battery panel, and the electric energy is provided for the work of the subsequent heating pipe, thereby realizing energy-saving heating under dynamic monitoring;

s2, when the indoor space formed by enclosing the outer vertical face panel is required to be cut off, two groups of bearing wall panels can be put down to be flush with the inorganic titanium magnesium plate, then the connecting threaded rods are inserted into the first reserved opening, the second reserved opening and the third reserved opening until the front face port of the rotating flat disc is sunken in the first reserved opening, so that the rotating flat disc is prevented from forming a bulge on the surface of the bearing wall panel, the leveling degree of the surface of the bearing wall panel is ensured, and then two groups of bearing wall panels connected through the connecting threaded rods can form a partition wall body structure;

s3, when the indoor space formed by enclosing the outer vertical face panel is not required to be partitioned, the two groups of bearing wall panels can be lifted, the tail ends of the bearing wall panels and the top edge of the inorganic titanium magnesium plate are tapped, and the frame formed by enclosing the outer vertical face panel is subjected to capping treatment, so that the polyphenyl particle foam concrete filled in the filling frame in the bearing wall panel can still keep corresponding strength when the bearing wall panel is used as a wall panel by virtue of the characteristics of light weight and high strength of the polyphenyl particle foam concrete, and the gravity of the device is reduced;

s4, when the assembled unit module formed by enclosing the outer vertical face plate is needed to be stacked in multiple layers, connecting seats can be welded at four corners of the top of the outer vertical face plate, the outer vertical face plate is welded on the surface of the connecting seats immediately, so that a multi-layer stacked combined structure is formed, when the combined structure is used and is subjected to the transverse load of wind power, the transverse wind power load can be relieved through the elastic action of a buffer spring, if the ground foundation of the device is locally settled, the extrusion force values detected by the first pressure sensors on the surfaces of the four groups of connecting seats are different, the first state lamp ring is continuously lightened at the moment, a warning signal is provided for managers, when the second pressure sensor detects that the pressure value exceeds a preset safety threshold value, the second state lamp ring can be continuously lightened, and the multi-layer stacked combined structure and the load inside the multi-layer stacked combined structure are overweight, timely weight reduction is required to ensure the safety of the whole device.

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

1. the multifunctional wall plate comprises a bearing wall plate body, a shaft rod, a bearing wall plate, an empty groove, a filling frame and an expansion net, wherein the bearing wall plate body is arranged on the shaft rod, the shaft rod is connected with the filling frame through a connecting rod, the connecting rod is connected with the expansion net through a connecting rod, and the connecting rod is connected with the bearing wall plate through a connecting rod.

2. According to the invention, the dynamic monitoring box, the first temperature sensor, the battery plate, the heating pipe, the second temperature sensor and the full-glass vacuum pipe are arranged, and the first temperature sensor and the second temperature sensor are used for detecting the internal and external environment temperatures of the device, so that a judgment basis can be provided for whether the device needs to heat, unnecessary heating is avoided, the energy saving performance of the device is improved, and in addition, the battery plate, the heating pipe and the full-glass vacuum pipe are mutually matched, so that the heating pipe can be ensured to stably obtain clean energy, and the energy consumption is reduced.

3. The invention is provided with the connecting seat, the buffer spring, the first pressure sensor, the first state lamp ring, the second pressure sensor and the second state lamp ring, when the device is needed to be used for multilayer superposition treatment, the connecting seat forms a wrapping structure for the outer vertical face panel and the related plate body, when the multilayer superposition structure is acted by transverse wind force, the design of the wrapping structure and the elasticity of the buffer spring can provide buffer protection for the outer vertical face panel with the transverse displacement tendency and the related plate body, so as to strengthen the integral shearing resistance of the multilayer superposition structure, in addition, when the surface of a foundation installed by the device is locally settled or unevenly settled, the related managers can be reminded through the light-on state of the first state lamp ring to cause safety warning, when the second pressure sensor detects that the multilayer superposition structure has overweight load, the second state lamp ring is lighted, reminding relevant managers to lose weight in time, avoiding the collapse accident, and protecting the safety of the device.

4. The wall body structure is provided with the connecting and leveling structure and comprises the rotary flat disc, the connecting threaded rod, the first reserved opening, the second reserved opening and the third reserved opening, the connecting threaded rod is inserted into the first reserved opening, the second reserved opening and the third reserved opening until the front port of the rotary flat disc is sunken in the first reserved opening, so that the rotary flat disc is prevented from forming a bulge on the surface of a bearing wall board, the leveling degree of the surface of the bearing wall board is ensured, and then two groups of bearing wall boards connected through the connecting threaded rod can form a partition wall body structure.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the installation structure of the embedded wallboard and the inorganic titanium magnesium board of the present invention;

FIG. 3 is a schematic view of a local installation structure of the embedded wallboard, the embedded wallboard and the inorganic titanium magnesium board;

FIG. 4 is a schematic view of the installation structure of the load-bearing wall panel and the first reserved opening of the present invention;

FIG. 5 is a schematic view of the assembly structure of the connection leveling structure of the present invention;

FIG. 6 is a schematic view of the dynamic monitoring cartridge and all-glass vacuum tube mounting structure of the present invention;

FIG. 7 is a schematic view of an assembly structure of the outer facade panel of the present invention;

fig. 8 is a schematic view of an assembly structure of the connecting seat of the present invention.

In the figure: 1. pre-burying a wallboard; 101. a sound insulating layer; 102. pre-burying a pipeline; 103. pre-burying a pipeline; 2. a multifunctional plate body; 201. a shaft lever; 202. a load-bearing wall panel; 203. an empty groove; 204. filling the frame; 205. expanding the mesh; 3. a dynamic monitoring box; 301. a first temperature sensor; 302. a battery plate; 303. heating a tube; 304. a second temperature sensor; 305. a full glass vacuum tube; 4. connecting a leveling structure; 401. rotating the flat disc; 402. connecting a threaded rod; 403. a first reserved port; 404. a second reserved port; 405. a third reserved port; 5. an inorganic titanium magnesium board; 501. a groove; 502. an insulating heat-conducting frame; 503. a humidity sensor; 504. a prompt light bar; 6. a facade panel; 601. basalt fiber cloth; 602. organic fiber cloth; 603. waterproof and vapor-permeable plastic film; 7. a connecting seat; 701. a buffer spring; 702. a first pressure sensor; 703. a lamp ring in the first state; 704. a second pressure sensor; 705. and a second state lamp ring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, such as "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The first embodiment is as follows: referring to fig. 1 and 4, an embodiment of the present invention is shown: an energy-saving assembled heating wall based on dynamic monitoring comprises a pre-buried wallboard 1 and an outer vertical face panel 6, wherein the pre-buried wallboard 1 is installed on the inner wall of the outer vertical face panel 6, an inorganic titanium magnesium plate 5 is installed on the inner wall of the pre-buried wallboard 1, and grooves 501 are formed in the top positions of the inner walls on the two sides of the inorganic titanium magnesium plate 5;

specifically, through the outer facade panel 6, corresponding outer wall protection can be provided for the assembled wall body, the purposes of outer wall fireproof and waterproof performance and strength protection are achieved, through the pre-embedded wallboard 1, environment-friendly sound insulation protection and pipeline pre-embedding processing can be achieved for the device, pipeline open-line installation is avoided, the attractiveness of the device in the process of installing an internal pipeline is ensured, in addition, installation parts such as wall surface household appliances can be installed in a self-tapping fixing mode through the beam sea impact resistance and the nail holding force of the inorganic titanium magnesium plate 5, additional fixing materials are not needed, the installation procedure is simplified, the necessity of punching, punching and grooving is avoided, the attractiveness of the surface of the inorganic titanium magnesium plate 5 is protected, and an installation space can be provided for the multifunctional plate body 2 through the groove 501;

the inner wall of recess 501 is connected with multi-functional plate body 2 through the bearing, multi-functional plate body 2 is including axostylus axostyle 201, bearing wallboard 202, dead slot 203, fill frame 204 and expansion net 205, the inner wall of recess 501 is connected with two sets of axostylus axostyles 201 of arranging around through the bearing, bearing wallboard 202 is installed to the bottom of axostylus axostyle 201, fill frame 204 is installed to the inside gomphosis of bearing wallboard 202, expansion net 205 is all installed to the inner wall around filling frame 204, the inside of bearing wallboard 202 is cut apart into the dead slot 203 of symmetrical arrangement around through filling frame 204, and two sets of dead slots 203 are located the place ahead and the rear of filling frame 204 respectively.

Specifically, the multifunctional plate body 2 can be switched between two functional states of a capping plate and a partition wall plate, so that the device can conveniently perform functional partition, full capping and local capping treatment;

when the multifunctional plate body 2 is used as a partition wall plate, the two groups of bearing wall plates 202 can be vertically put down, and then the two groups of bearing wall plates 202 can be connected and locked through the connecting and leveling structure 4, so that the functional partition is realized;

when the multifunctional plate body 2 is used as a full-capping plate body, two groups of bearing walls 202 can be lifted to the top edge of the inorganic titanium magnesium plate 5 under the matching of the shaft rod 201, and then fixed to form a full-capping structure, and then a layer of bottom plate is laid on the top of the inorganic titanium magnesium plate 5, so that the full-capping structure can be realized;

when the multifunctional plate body 2 is used as a local capping plate body, one group of bearing wall plates 202 can be lifted and fixed with the inorganic titanium magnesium plate 5, and the rest group of bearing wall plates 202 can be used as partitions and form a compound structure with a frame structure formed by enclosing the outer vertical face panel 6 on the upper layer, so that diversified installation of an internal structural area of the device is realized.

In addition, the interior of the two layers of empty grooves 203 is subjected to vacuum treatment, a sound insulation design can be formed immediately, the polystyrene particle foam concrete filled in the filling frame 204 can enhance the bearing capacity of the bearing wall board 202 when used as a capping board, and when the expansion net 205 is used as a template for pouring concrete, mortar is soaked to the interface through the grids to form a coarse grain interface, so that the shear resistance of the concrete is enhanced.

Example two: referring to fig. 1-3 and 6, an embodiment of the present invention is shown: an energy-saving assembled heating wall based on dynamic monitoring comprises a dynamic monitoring box 3, wherein the outer surfaces of two sides of an outer vertical surface panel 6 are respectively provided with a strip-shaped dynamic monitoring box 3, the inside of the dynamic monitoring box 3 is equidistantly provided with an all-glass vacuum tube 305, the inside of the all-glass vacuum tube 305 is provided with a solar panel, a first temperature sensor 301 is arranged in the dynamic monitoring box 3, the inner walls of two sides of the inorganic titanium magnesium plate 5 are both provided with an invaginated insulating heat-conducting frame 502, the insulating heat-conducting frame 502 is internally provided with the battery plate 302, the top of the battery plate 302 is equidistantly provided with the heating pipes 303, the heating pipe 303 is electrically connected with the battery board 302, a second temperature sensor 304 is installed on the outer wall of one side of the battery board 302, which is far away from the inorganic titanium magnesium board 5, and the second temperature sensor 304 is wirelessly and electrically connected with the first temperature sensor 301.

Specifically, the insulating heat conducting frame 502 can ensure that heat generated when the heating pipe 303 is electrified can be smoothly transmitted to the inside of the device for heating treatment, the insulating property can also avoid electric leakage damage, the all-glass vacuum tube 305 is designed in a tubular shape, has better pressure resistance, can provide effective pressure resistance protection for an internal solar panel, enables the solar panel to smoothly complete photoelectric conversion, immediately stores electric energy into the battery panel 302, and provides energy for subsequent electrification and heating of the heating pipe 303;

when the device needs to dynamically monitor the wall heating work, the internal and external ambient temperatures of the device can be respectively detected through the first temperature sensor 301 and the second temperature sensor 304, when the temperature value of the first temperature sensor 301 and the temperature value of the second temperature sensor 304 are both in the range of 20-30 ℃, the ambient temperature is more comfortable, and the heating pipe 303 is used for heating;

when the temperature value of the first temperature sensor 301 and the temperature value of the second temperature sensor 304 are both in the range of minus 10 ℃, the environment temperature is relatively cold, and the heating pipe 303 needs to be started to supply heat for the interior of the device;

when the temperature value of the first temperature sensor 301 is higher than 30 ℃, the ambient temperature is hot, the sunshine of the external environment of the device is strong, the open time of the full-glass vacuum tube 305 can be prolonged, and powerful conditions are provided for the energy storage of the battery panel 302.

Example three: referring to fig. 1 and 8, an embodiment of the present invention: the utility model provides an energy-saving assembled heating wall based on dynamic monitoring, includes connecting seat 7, connecting seat 7 has all been welded in the top four corners of outer facade panel 6, connecting seat 7 is semi-open structure, buffer spring 701 and a pressure sensors 702 that the matrix was arranged are all installed to the both sides outer wall of connecting seat 7, and a pressure sensors 702 is located the centre of four group's buffer spring 701, the both sides of connecting seat 7 are sprained mud inside and all are equipped with the intermediate layer, interbedded internally mounted has a state lamp ring 703 of L type, a state lamp ring 703 and a pressure sensors 702 electric connection, No. two pressure sensors 704 of caving in are installed to the inside diapire of connecting seat 7, the inside diapire of connecting seat 7 is equipped with hollow layer, the internally mounted on hollow layer has No. two state lamp rings 705.

Specifically, when the device is required to be used for multilayer stacking treatment, the outer vertical face panel 6 and the related plate bodies can be welded at the top of the connecting seat 7, so that a wrapping structure is formed on the outer vertical face panel 6 and the related plate bodies, and when the multilayer stacking structure is subjected to transverse wind force, the design of the wrapping structure and the elasticity of the buffer spring 701 can provide buffer protection for the outer vertical face panel 6 and the related plate bodies with transverse displacement tendency, so that the integral shear resistance of the multilayer stacking structure is enhanced;

in addition, when local settlement or other uneven settlement occurs on the surface of the foundation on which the device is installed, the pressure values of the first pressure sensors 702 on the surfaces of the four groups of connecting seats 7 have difference values, and the first-state lamp ring 703 keeps a constant lighting state to remind relevant managers to cause safety warning;

influenced by the single-layer loaded weight and the multilayer superposed weight, when the second pressure sensor 704 detects that the multilayer superposed structure has an overweight load, the second-state lamp ring 705 is lightened to remind relevant managers of timely losing weight, so that collapse accidents are avoided, and the safety of the device is protected.

Example four: referring to fig. 1 and 5, an embodiment of the present invention: an energy-saving assembled heating wall based on dynamic monitoring, includes connecting leveling structure 4, and centrosymmetric connecting leveling structure 4 is installed to two sets of the inside bottom of bearing wallboard 202, connect leveling structure 4 including rotating flat disc 401, connecting threaded rod 402, reservation mouth 403, reservation mouth 404 No. two and reservation mouth 405 No. three, the place ahead the inside of bearing wallboard 202 is equipped with reservation mouth 403 No. two and reservation mouth 404 No. two, and the inner wall of reservation mouth 404 No. two is equipped with the screw thread, the rear the inside of bearing wallboard 202 is equipped with reservation mouth 405 No. three, and the inside of reservation mouth 405 No. three is equipped with the screw thread, the centre of a circle of reservation mouth 405 No. three, reservation mouth 404 No. two and reservation mouth 403 No. one is located same axis, the inside threaded connection of reservation mouth 404 No. two has connecting threaded rod 402, connecting threaded rod 402 installs in the front and rotates flat disc 401, the diameter of rotating flat plate 401 is the same with the internal diameter of reserving mouthful 403 for one number, and reserving mouthful 403 for one number is the toper structure, and the tail end diameter of reserving mouthful 403 for one number is the same with the diameter of reserving mouthful 404 for two numbers, the tail end of connecting threaded rod 402 runs through the inside that extends to reserving mouthful 405 for three numbers, connecting threaded rod 402 and rotating flat plate 401's comprehensive length is less than the sum of the length of reserving mouthful 403 for one number, reserving mouthful 404 for two numbers and reserving mouthful 405 for three numbers.

Concretely, inject connecting threaded rod 402 into a reservation mouth 403 and No. two reservation mouths 404 and No. three reservation mouths 405 inside, the front port that until rotates flatbed 401 is sunken in the inside of a reservation mouth 403, and then avoid rotating flatbed 401 and form the arch on the surface of bearing wallboard 202, ensure the levelness of looking for on bearing wallboard 202 surface, later can form the baffle wall structure through two sets of bearing wallboards 202 that connecting threaded rod 402 connects, and rotate the setting of flatbed 401, make things convenient for constructor to take out connecting threaded rod 402 from a reservation mouth 403 and No. two reservation mouths 404 and No. three reservation mouths 405 inside rotations.

Example five: referring to fig. 2, fig. 3 and fig. 7, an embodiment of the present invention: the utility model provides an energy-saving assembled heating wall based on dynamic monitoring, includes pre-buried wallboard 1, inorganic titanium magnesium board 5 and outer facade panel 6, pre-buried wallboard 1's inside is equipped with puigging 101, the inside packing of puigging 101 has the corn-on-cob, pre-buried pipeline 102 and No. two pre-buried pipeline 103 that the inside of pre-buried wallboard 1 was equipped with run through, arranged from top to bottom, and pre-buried pipeline 102 and No. two pre-buried pipeline 103 all are located the below of puigging 101.

Specifically, the corn cob that the puigging 101 is inside to be filled is for peeling off the dry corn cob core behind the kernel of corn, and its loose porous and low price in surface has better syllable-dividing effect and economic advantage, and buried pipeline 102 and No. two buried pipeline 103 are used for follow-up installation water pipe and cable respectively in addition and use, but auxiliary device realizes the concealed wire installation, also reduces the necessity of follow-up excavation, makes things convenient for the installation of corresponding pipeline.

Humidity inductor 503 and suggestion lamp strip 504 are installed to one side inner wall of inorganic titanium magnesium board 5, and suggestion lamp strip 504 is located humidity inductor 503's top, suggestion lamp strip 504 and humidity inductor 503 electric connection.

Specifically, can detect the indoor humidity of device through humidity inductor 503, can send start signal to suggestion lamp strip 504 when indoor humidity index is higher, and then remind indoor personnel in time to dehumidify.

The plate body of the outer facade panel 6 consists of basalt fiber cloth 601, organic fiber cloth 602 and a waterproof vapor-permeable plastic film 603, the organic fiber cloth 602 is installed on the inner wall of the waterproof vapor-permeable plastic film 603, and the basalt fiber cloth 601 is installed on the inner wall of the organic fiber cloth 602.

Specifically, the basalt fiber cloth 601 has high tensile strength, shear strength and elastic modulus, the organic fiber cloth 602 is made of flame-retardant polyester cloth, the waterproof vapor-permeable plastic film 603 is a polytetrafluoroethylene film, and a three-layer composite film-rolling structure is formed, so that the corresponding strength of the outer facade wall can be kept while the self weight of the device is reduced without additionally adding a steel structure, and corresponding fireproof, flame-retardant and waterproof effects can be achieved through the organic fiber cloth 602 and the waterproof vapor-permeable plastic film 603, so that corresponding outer wall protection is provided for the device.

The working steps of the wall body are as follows:

s1, when the wall is used for dynamic detection, the first temperature sensor 301 can be used for detecting the ambient temperature outside the wall, the second temperature sensor 304 is used for detecting the ambient temperature inside the space formed by enclosing the wall, when the temperature value detected by the first temperature sensor 301 and the temperature value detected by the second temperature sensor 304 are both in lower levels, the ambient temperature outside and inside the device can be judged to be lower, the heating pipe 303 can be started at the moment, so that the wall can be heated, when the temperature value detected by the first temperature sensor 301 is obviously higher than the temperature value detected by the second temperature sensor 304, the indoor ambient temperature can be judged to be lower than the ambient temperature outside the wall, the heating pipe 303 does not need to be started at the moment, the solar panel inside the all-glass vacuum pipe 305 can be used for photoelectric conversion, and then the electric energy is stored inside the battery panel 302, providing electric energy for the subsequent work of the heating pipe 303, thereby realizing energy-saving heating under dynamic monitoring;

s2, when the indoor space formed by enclosing the outer facade panel 6 needs to be isolated, two groups of bearing wall panels 202 can be put down to be flush with the inorganic titanium magnesium plate 5, then the connecting threaded rods 402 are inserted into the first reserved port 403, the second reserved port 404 and the third reserved port 405 until the front port of the rotary flat disc 401 is sunken in the first reserved port 403, so that the rotary flat disc 401 is prevented from forming a bulge on the surface of the bearing wall panel 202, the flatness of the surface of the bearing wall panel 202 is ensured, and then the two groups of bearing wall panels 202 connected through the connecting threaded rods 402 can form a partition wall structure;

s3, when the indoor space formed by enclosing the outer vertical face panel 6 is not needed to be isolated, the two groups of bearing wall panels 202 can be lifted, the tail ends of the bearing wall panels 202 and the top edge of the inorganic titanium magnesium plate 5 are tapped, so that the frame formed by enclosing the outer vertical face panel 6 is sealed, and at the moment, the polyphenyl particle foam concrete filled in the filling frame 204 in the bearing wall panels 202 can reduce the self gravity of the device and ensure that the bearing wall panels 202 can still keep corresponding strength when being used as wall panels;

s4, when the assembled unit module formed by enclosing the outer vertical face panel 6 is needed to be stacked in multiple layers, the connecting seats 7 can be welded at four corners of the top of the outer vertical face panel 6, the outer vertical face panel 6 is welded on the surface of the connecting seats 7 immediately, so as to form a multi-layer stacked combined structure, then when the combined structure is used and is subjected to the transverse load of wind power, the transverse wind power load can be relieved through the elastic action of the buffer spring 701, if the ground foundation of the device is locally settled, the extrusion force values detected by the first pressure sensors 702 on the surfaces of the four groups of connecting seats 7 are unequal, at the moment, the first state lamp ring 703 is continuously lightened to provide warning signals for managers, when the second pressure sensor 704 detects that the pressure value exceeds the preset safety threshold value, the second state lamp ring 705 can be continuously lightened, and the multi-layer stacked combined structure and the load in the multi-layer stacked combined structure are overweight, timely weight reduction is required to ensure the safety of the whole device.

The working principle is as follows: when the indoor space formed by enclosing the outer facade panel 6 needs to be subjected to partition treatment, two groups of bearing wall boards 202 can be put down to be flush with the inorganic titanium magnesium plate 5, then the connecting threaded rods 402 are inserted into the first reserved opening 403, the second reserved opening 404 and the third reserved opening 405 until the front port of the rotating flat disc 401 is sunken in the first reserved opening 403, further the rotating flat disc 401 is prevented from forming a bulge on the surface of the bearing wall board 202, the flatness of the surface of the bearing wall board 202 is ensured, then the two groups of bearing wall boards 202 connected through the connecting threaded rods 402 can form a partition wall body structure, when the indoor space formed by enclosing the outer facade panel 6 does not need to be subjected to partition treatment, the two groups of bearing wall boards 202 can be lifted, the tail ends of the two groups of bearing wall boards are subjected to tapping treatment with the top edge of the inorganic titanium magnesium plate 5, and the frame formed by enclosing the outer facade panel 6 is subjected to capping treatment, at this time, the polystyrene particle foam concrete filled in the filling frame 204 in the bearing wallboard 202 can reduce the gravity of the device and ensure that the bearing wallboard 202 can still keep corresponding strength when used as a wallboard by virtue of the characteristics of light weight and high strength;

then when the assembled unit module formed by enclosing the outer vertical face panel 6 needs to be subjected to multilayer superposition processing, the connecting seats 7 can be welded at four corners of the top of the outer vertical face panel 6, the outer vertical face panel 6 is welded on the surface of the connecting seats 7 immediately, so that a multilayer superposition type combined structure is formed, when the combined structure is used and is subjected to the action of the transverse load of wind power, the transverse wind load can be relieved through the elastic action of the buffer spring 701, if the ground foundation of the device is locally settled, the extrusion force values detected by the first pressure sensors 702 on the surfaces of the four groups of connecting seats 7 are unequal, the first state lamp ring 703 is continuously lightened at the moment, a warning signal is provided for a manager, when the second pressure sensor 704 detects that the pressure value exceeds a preset safety threshold value, the second state lamp ring can be continuously lightened, and the multilayer superposition type combined structure 705 and a load in the multilayer superposition type combined structure are overweight, timely weight reduction is needed to ensure the safety of the whole device;

when the device is integrally installed and used, and when the wall is used for dynamic detection, the first temperature sensor 301 can be used for detecting the ambient temperature outside the wall of the device, the second temperature sensor 304 is used for detecting the ambient temperature inside a space enclosed and formed inside the wall of the device, when the temperature value detected by the first temperature sensor 301 and the temperature value detected by the second temperature sensor 304 are both in lower levels, the ambient temperature outside and inside the device can be judged to be lower, the heating pipe 303 can be started at the moment, so that the wall can be used for heating, when the temperature value detected by the first temperature sensor 301 is obviously higher than the temperature value detected by the second temperature sensor 304, the indoor ambient temperature can be judged to be lower than the ambient temperature outside the wall, the heating pipe 303 does not need to be started at the moment, photoelectric conversion can be carried out by virtue of the solar panel inside the all-glass vacuum pipe 305, and then the electric energy is stored in the battery plate 302 to provide electric energy for the subsequent work of the heating pipe 303, so that the energy-saving heating under dynamic monitoring is realized.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides an energy-saving assembled heating wall based on dynamic monitoring, includes pre-buried wallboard (1) and outer facade panel (6), its characterized in that: the inner wall of the outer facade panel (6) is provided with a pre-buried wallboard (1), the inner wall of the pre-buried wallboard (1) is provided with an inorganic titanium magnesium plate (5), the top positions of the inner walls on the two sides of the inorganic titanium magnesium plate (5) are respectively provided with a groove (501), and the outer surfaces on the two sides of the outer facade panel (6) are respectively provided with a strip-shaped dynamic monitoring box (3);

the utility model discloses a wall structure, including recess (501), bearing, expansion net, bearing wallboard (202), dead slot (203), filling frame (204), expansion net, bearing, multifunctional plate body (2), bearing, filling frame (204), expanding net, bearing wallboard (202) are installed to the bottom of axostylus axostyle (201), filling frame (204) are installed to the inside gomphosis of bearing wallboard (202), expanding net (205) are all installed to the front and back inner wall of filling frame (204), the dead slot (203) of symmetrical arrangement around the inside of bearing wallboard (202) is cut apart into through filling frame (204), and two sets of dead slots (203) are located the place ahead and the rear of filling frame (204) respectively.

2. An energy-saving fabricated heating wall based on dynamic monitoring as claimed in claim 1, wherein: full glass vacuum tube (305) are installed to the inside equidistance of dynamic monitoring box (3), the internally mounted of full glass vacuum tube (305) has solar panel, the internally mounted of dynamic monitoring box (3) has temperature-sensing ware (301) No. one, the both sides inner wall of inorganic titanium magnesium board (5) all is equipped with insulating heat conduction frame (502) of caving in, the internally mounted of insulating heat conduction frame (502) has panel (302), heating pipe (303) are installed to the top equidistance of panel (302), heating pipe (303) and panel (302) electric connection, panel (302) are kept away from one side outer wall of inorganic titanium magnesium board (5) and are installed No. two temperature-sensing ware (304), and No. two temperature-sensing ware (304) and temperature-sensing ware (301) wireless electric connection.

3. An energy-saving fabricated heating wall based on dynamic monitoring as claimed in claim 1, wherein: connecting seat (7) have all been welded in the top four corners of outer facade panel (6), connecting seat (7) are semi-open structure, buffer spring (701) and a pressure sensors (702) that the matrix was arranged are all installed to the both sides outer wall of connecting seat (7), and a pressure sensors (702) are located the centre of four group's buffer spring (701), the both sides of connecting seat (7) are sprained mud inside and are all equipped with the intermediate layer, interbedded internally mounted has a status lamp ring (703) of L type, status lamp ring (703) and a pressure sensors (702) electric connection, No. two pressure sensors (704) of caving in are installed to the inside diapire of connecting seat (7), the inside diapire of connecting seat (7) is equipped with hollow layer, the internally mounted on hollow layer has No. two status lamp rings (705).

4. An energy-saving fabricated heating wall based on dynamic monitoring as claimed in claim 1, wherein: the connecting and leveling structure (4) is arranged at the bottom of the interior of the two groups of bearing wallboards (202) and is centrosymmetric, the connecting and leveling structure (4) comprises a rotating flat disc (401), a connecting threaded rod (402), a reserved opening (403), a reserved opening (404) and a reserved opening (405) which are arranged in the front, a reserved opening (403) and a reserved opening (404) which are arranged in the interior of the bearing wallboard (202) are arranged in the front, threads are arranged on the inner wall of the reserved opening (404) which is arranged in the second, a reserved opening (405) which is arranged in the interior of the bearing wallboard (202) is arranged in the rear, threads are arranged in the interior of the reserved opening (405) which is arranged in the third, the centers of the reserved opening (405), the reserved opening (404) which is arranged in the second and the reserved opening (403) are arranged on the same axis, the connecting threaded rod (402) is connected with the connecting threaded rod (402), and the rotating flat disc (401) is arranged in the front of the connecting and leveling structure, the diameter of the rotating flat disc (401) is the same as the inner diameter of the first reserved opening (403).

5. An energy-saving fabricated heating wall based on dynamic monitoring as claimed in claim 4, wherein: reservation mouth (403) are the toper structure, and the tail end diameter of reservation mouth (403) is the same with the diameter of reservation mouth (404) No. two, the tail end of connecting threaded rod (402) runs through the inside that extends to reservation mouth (405) No. three, connecting threaded rod (402) and the comprehensive length of rotating flatbed (401) are less than the length sum of reservation mouth (403), reservation mouth (404) No. two and reservation mouth (405) No. three.

6. An energy-saving fabricated heating wall based on dynamic monitoring as claimed in claim 1, wherein: the inside of pre-buried wallboard (1) is equipped with puigging (101), the inside packing of puigging (101) has the corn-on-cob, the inside of pre-buried wallboard (1) is equipped with a pre-buried pipeline (102) and No. two pre-buried pipeline (103) that run through, arrange from top to bottom, and a pre-buried pipeline (102) and No. two pre-buried pipeline (103) all are located the below of puigging (101).

7. An energy-saving fabricated heating wall based on dynamic monitoring as claimed in claim 1, wherein: humidity inductor (503) and suggestion lamp strip (504) are installed to one side inner wall of inorganic titanium magnesium board (5), and suggestion lamp strip (504) are located the top of humidity inductor (503), suggestion lamp strip (504) and humidity inductor (503) electric connection.

8. An energy-saving fabricated heating wall based on dynamic monitoring as claimed in claim 1, wherein: the plate body of the outer facade panel (6) is composed of basalt fiber cloth (601), organic fiber cloth (602) and a waterproof vapor-permeable plastic film (603), the organic fiber cloth (602) is installed on the inner wall of the waterproof vapor-permeable plastic film (603), and the basalt fiber cloth (601) is installed on the inner wall of the organic fiber cloth (602).

9. An energy-saving fabricated heating wall based on dynamic monitoring as claimed in any one of claims 1 to 8, wherein the wall is operated by the following steps:

s1, when the wall is used for dynamic detection, the first temperature sensor (301) can be used for detecting the ambient temperature outside the wall of the device, the second temperature sensor (304) is used for detecting the ambient temperature inside the space formed by enclosing the wall of the device, when the temperature value detected by the first temperature sensor (301) and the temperature value detected by the second temperature sensor (304) are both in a lower level, the ambient temperature outside and inside the device can be judged to be lower, at the moment, the heating pipe (303) can be started, so that the wall can be heated, when the temperature value detected by the first temperature sensor (301) is obviously higher than the temperature value detected by the second temperature sensor (304), the indoor ambient temperature can be judged to be lower than the ambient temperature outside the wall, at the moment, the heating pipe (303) does not need to be started, and the photoelectric conversion can be carried out by virtue of the solar panel inside the all-glass vacuum pipe (305), then, electric energy is stored in the battery plate (302) to provide electric energy for the subsequent work of the heating pipe (303), so that energy-saving heating under dynamic monitoring is realized;

s2, when the indoor space formed by enclosing the outer facade panel (6) needs to be isolated, two groups of bearing wall panels (202) can be put down to be flush with the inorganic titanium magnesium plate (5), then the connecting threaded rod (402) is inserted into the first reserved port (403), the second reserved port (404) and the third reserved port (405) until the front port of the rotary flat disc (401) is sunken inside the first reserved port (403), further the rotary flat disc (401) is prevented from forming a bulge on the surface of the bearing wall panel (202), the flatness of the surface of the bearing wall panel (202) is ensured, and then the two groups of bearing wall panels (202) connected through the connecting threaded rod (402) can form a partition wall structure;

s3, when the indoor space formed by enclosing the outer vertical face panel (6) is not required to be partitioned, the two groups of bearing wall panels (202) can be lifted, the tail ends of the bearing wall panels and the top edge of the inorganic titanium magnesium plate (5) are subjected to tapping treatment, and therefore a frame formed by enclosing the outer vertical face panel (6) is subjected to capping treatment, and at the moment, the polystyrene particle foam concrete filled in the filling frame (204) in the bearing wall panel (202) can reduce the self gravity of the device and ensure that the bearing wall panel (202) can still keep corresponding strength when being used as a wall panel;

s4, when multilayer overlapping processing is needed to be carried out on an assembled unit module formed by enclosing the outer vertical face panel (6), connecting seats (7) can be welded at four corners of the top of the outer vertical face panel (6), the outer vertical face panel (6) is welded on the surface of the connecting seats (7) along with the welding, so that a multilayer overlapping type combined structure is formed, then when the combined structure is used and is subjected to the action of transverse load of wind power, the transverse wind load can be relieved through the elastic action of a buffer spring (701), if the ground foundation of the device is locally settled, the extrusion force values detected by a first pressure sensor (702) on the surfaces of four groups of connecting seats (7) are unequal, at the moment, a first state lamp ring (703) is continuously lightened, a warning signal is provided for managers, and when a second pressure sensor (704) detects that the pressure value exceeds a preset safety threshold value, a second state lamp ring (705) can be continuously lightened, the multilayer superposed combined structure and the load inside the multilayer superposed combined structure are overweight, and the weight needs to be reduced in time to ensure the safety of the whole device.