CN115897846A

CN115897846A - Energy-saving thermal insulation wall structure

Info

Publication number: CN115897846A
Application number: CN202211645446.0A
Authority: CN
Inventors: 张泰永
Original assignee: Zibo Urban And Rural Planning Development Center Zibo Urban And Rural Planning Exhibition Hall
Current assignee: Zibo Urban And Rural Planning Development Center Zibo Urban And Rural Planning Exhibition Hall
Priority date: 2022-12-21
Filing date: 2022-12-21
Publication date: 2023-04-04
Anticipated expiration: 2042-12-21
Also published as: CN115897846B

Abstract

The invention discloses an energy-saving heat-insulating wall structure; a heat insulation component is connected between the two first connecting plates; the front side of the third connecting plate is connected with an energy-saving component; when using in winter, shelter from the cold air through the shielding plate, make the cold air can not flow to heat insulating board and wall body, thereby avoid being used for wind power generation's cold air to take away the heat on the wall body, and keep warm to the wall body through closely arranged heat insulating board, the problem that the heat preservation effect that leads to is low in order to compromise wind power generation when having avoided current wall body to use in winter, and simultaneously, carry out the shutoff to adjacent heat insulating board clearance department through the heat insulating strip, in order to improve sealing performance, thereby improve the wall body heat preservation effect, when using in summer, through the ninety degrees of first linkage board linkage heat insulating board rotation, thereby make a plurality of heat insulating board separate each other, stop providing the heat preservation effect to the wall body, thereby improve the radiating effect of wall body self.

Description

Energy-saving thermal insulation wall structure

Technical Field

The invention relates to the technical field of building walls. More particularly, the invention relates to an energy-saving heat-insulating wall structure.

Background

The existing Chinese patent: energy-saving wall structure (CN 206570992U), it has good heat preservation effect through the insulating cotton realization inside and outside air isolation, can effectively dispel the heat through the combination of heating panel heat dissipation post and play good cooling effect, realize the utilization of the energy through wind energy component at last and play energy-concerving and environment-protective effect, however it does not consider the influence that its heat radiation structure produced when using winter when providing heat dissipation function in summer yet, it is when using in winter, this energy-saving wall structure is used for radiating heat dissipation post in summer also can take the heat of wall body out, thereby lead to the thermal insulation performance of wall body to reduce, lead to indoor temperature to descend too fast and be difficult for keeping the heat, increase indoor heating load, be unfavorable for energy saving and emission reduction.

Disclosure of Invention

The invention provides an energy-saving heat-insulating wall structure, and aims to overcome the defect that when the existing energy-saving wall structure is used in winter, a heat dissipation column used for heat dissipation in summer on the energy-saving wall structure can bring out heat of a wall body, so that the heat-insulating property of the wall body is reduced.

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

an energy-saving heat-insulating wall structure comprises a wall body, a first connecting plate, a second connecting plate, a third connecting plate, a heat-insulating plate, a baffle plate, a heat-insulating strip, a heat-insulating assembly and an energy-saving assembly; the left part and the right part of the front side of the wall body are fixedly connected with a first connecting plate; a plurality of third round holes are formed in the upper sides of the two first connecting plates; a second connecting plate is fixedly connected between the upper side and the lower side of each of the two first connecting plates; the two second connecting plates are fixedly connected with the wall body; a third connecting plate is fixedly connected between the front sides of the two first connecting plates; the two second connecting plates are fixedly connected with a third connecting plate; a plurality of first round holes which are through from front to back are formed in the third connecting plate; a plurality of first channels are formed in the third connecting plate and communicated with the adjacent first round holes; a heat insulation component is connected between the two first connecting plates; the middle part of the heat insulation component is transversely connected with a plurality of heat insulation plates in an array manner; every two adjacent heat insulation plates on the left and the right are contacted; the front side of the heat preservation component is connected with a baffle plate; the baffle plate slides on the inner side of the third connecting plate; the heat insulation component is switched into a heat insulation or heat dissipation mode through the heat insulation plate; the airflow path is switched through the shielding plate, and the shielding plate is also used for shielding rainwater; the rear side of the heat insulation component is transversely connected with a plurality of heat insulation strips in an array manner, and the plurality of heat insulation strips and the plurality of heat insulation plates are arranged in a crossed manner; plugging gaps between the closed heat insulation plates through the heat insulation strips; the front side of the third connecting plate is connected with a plurality of energy-saving components for converting wind energy into electric energy.

As an improvement of the scheme, the heat insulation assembly comprises a round rod, a telescopic cylinder, a first linkage plate, a first linkage block, a second linkage block, a first switching unit, a second switching unit, a third switching unit, a sealing unit and a drainage unit; a plurality of round rods are rotatably connected between the two second connecting plates and are respectively and fixedly connected with the adjacent heat insulation plates; the back parts of the upper side phases of the two first connecting plates are fixedly connected with a telescopic cylinder, and the back parts of the lower side phases of the two first connecting plates are also fixedly connected with a telescopic cylinder; a first linkage plate is fixedly connected between the telescopic ends of every two adjacent telescopic cylinders; the rear sides of the two first linkage plates are transversely and fixedly connected with a plurality of first linkage blocks in a row; a second linkage block is rotatably connected to the first linkage blocks; the left sides of the plurality of second linkage blocks are rotatably connected with the left sides of the adjacent heat insulation plates; the middle part of the third connecting plate is connected with a first switching unit; the third connecting plate is connected with a second switching unit, and the second switching unit is positioned outside the first switching unit; the two first connecting plates are connected with a third switching unit; the two first connecting plates are connected with sealing units, and the sealing units are positioned behind the first linkage plates; the middle part of the lower side of the third connecting plate is connected with a drainage unit.

As an improvement of the above scheme, the first switching unit comprises a first elastic telescopic rod, a third linkage block and a fourth linkage block; the shielding plate is provided with a plurality of second round holes; a plurality of first elastic telescopic rods are fixedly connected to the lower side of the shielding plate in a transverse array; the telescopic ends of the plurality of first elastic telescopic rods are fixedly connected with the third connecting plate; two third linkage blocks are fixedly connected to the upper side of the baffle plate; the two third connecting blocks are connected with the third connecting plate in a sliding manner; a fourth linkage block is fixedly connected to the left side and the right side of the first linkage plate above the first linkage plate; the two fourth linkage blocks are respectively contacted with the adjacent third linkage blocks; and one sides of the two fourth linkage blocks, which are close to the adjacent third linkage blocks, are inclined planes.

As an improvement of the above scheme, the second switching unit comprises a second elastic telescopic rod, a second linkage plate and a fifth linkage block; a second elastic telescopic rod is fixedly connected to the lower part of the left side and the lower part of the right side of the third connecting plate; the telescopic ends of the two second elastic telescopic rods are fixedly connected with a second linkage plate; the upper sides of the two second linkage plates are both provided with a through hole; the two second linkage plates are both connected with the third connecting plate in a sliding manner; the first linkage plate positioned above is fixedly connected with two fifth linkage blocks, and the two fifth linkage blocks are positioned on the outer sides of the two third linkage blocks; and one sides of the two fifth linkage blocks, which are close to the adjacent second linkage plates, are inclined planes.

As an improvement of the above scheme, the third switching unit comprises a third elastic telescopic rod and a third linkage plate; a third elastic telescopic rod is fixedly connected to the upper parts of the inner sides of the two first connecting plates; the telescopic ends of the two third elastic telescopic rods are fixedly connected with a third linkage plate; a plurality of fourth round holes are formed in the upper sides of the two third linkage plates; the two third linkage plates are respectively connected with the adjacent first connecting plates in a sliding manner; the upper side surfaces of the two third linkage plates are inclined surfaces.

As an improvement of the scheme, the sealing unit comprises a sliding sleeve block, a linkage frame, a first rack, a straight gear and a second rack; two sliding sleeve blocks are fixedly connected to the upper part and the lower part of the inner side of the wall body; a linkage frame is connected between every two left and right adjacent sliding sleeve blocks in a sliding manner; the plurality of heat insulation strips are fixedly connected with the two linked frames; two first racks are fixedly connected to the rear sides of the two first linkage plates; the middle parts of the upper sides of the two first connecting plates are respectively and rotatably connected with a straight gear, and the middle parts of the lower sides of the two first connecting plates are also respectively and rotatably connected with a straight gear; the four straight gears are respectively meshed with the adjacent first racks; the left sides and the rear sides of the two linkage frames are fixedly connected with a second rack; the four second racks are respectively meshed with the adjacent straight gears.

As the improvement of the scheme, the drainage unit comprises a square pipe and a first dust screen; a square pipe is fixedly connected to the lower part of the front side of the third connecting plate; the front side of the square pipe is fixedly connected with a first dustproof net.

As an improvement of the scheme, the lower part of the front side and the upper part of the front side of the third connecting plate are both provided with a second channel, and the second channel positioned below is V-shaped; the two second channels are respectively communicated with the plurality of first channels; the second channel positioned below is communicated with the square pipe; the through hole is communicated with the second channel positioned above.

As an improvement of the scheme, the energy-saving component positioned in the middle of the lower side comprises a connecting frame, a generator, an impeller, a second dust screen and a cleaning unit; a connecting frame is fixedly connected to the middle part of the lower side of the third connecting plate; the middle part of the connecting frame is fixedly connected with a generator; an input shaft of the generator is fixedly connected with an impeller; a second dustproof net is fixedly connected to the third connecting plate and is positioned in front of the impeller; the front side of the impeller is connected with a cleaning unit.

As an improvement of the scheme, the cleaning unit comprises a fourth elastic telescopic rod and a scraping rod; the front side of the impeller is fixedly connected with a fourth elastic telescopic rod; the telescopic end of the fourth elastic telescopic rod penetrates through the second dust screen; the telescopic end of the fourth elastic telescopic rod is fixedly connected with a scraping rod; the rear side of the scraping rod is contacted with the front side of the second dust screen.

Has the advantages that: by adopting the technical scheme, when the wall body is used in winter, cold air is shielded by the shielding plate and does not flow to the heat insulation plate and the wall body, so that the cold air for wind power generation is prevented from bringing out heat on the wall body, the wall body is insulated by the closely arranged heat insulation plates, the problem that the existing wall body is low in heat insulation effect due to wind power generation in winter is solved, and meanwhile, the gaps between the adjacent heat insulation plates are plugged by the heat insulation strips so as to improve the sealing performance and improve the heat insulation effect of the wall body;

when the heat insulation plate is used in summer, the first linkage plate is linked with the heat insulation plates to rotate ninety degrees, so that the heat insulation plates are spaced from each other, the heat insulation effect on the wall body is stopped, the heat radiation effect of the wall body is improved, the first linkage plate is used for simultaneously linking the shielding plate, the second linkage plate and the third linkage plate to move, namely, the air flow path is automatically switched while the heat insulation plates are unfolded, so that the air flow flows into the front cavity of the wall body through the first round hole and then flows out from the third round hole and the fourth round hole to form a new air flow path, the heat in the front cavity of the wall body is taken out through the air flow, and the heat radiation effect of the wall body is further improved;

in rainy days, the shielding plate is also used for shielding rainwater, so that the rainwater is prevented from splashing into the heat insulation plate and the front cavity of the wall body from the first round hole to influence the heat insulation effect, and meanwhile, the rainwater is automatically discharged through the square pipe, so that the use is more convenient;

wind energy is converted into electric energy through the impeller and the generator, energy conservation and emission reduction are realized, the impeller drives the scraping rod to scrape impurities on the front side of the second dust screen, the second dust screen is prevented from being blocked, the fourth elastic telescopic rod provides tension for the scraping rod, the scraping rod is enabled to be always compressed to the front side of the second dust screen, and the cleaning efficiency is improved.

Drawings

The contents of the drawings and the reference numbers in the drawings are briefly described as follows:

FIG. 1 is a first schematic structural view of an energy-saving thermal insulation wall structure according to the present invention;

FIG. 2 is a second schematic structural view of the energy-saving thermal insulation wall structure of the present invention;

FIG. 3 shows a schematic structural view of the insulating assembly of the present invention;

FIG. 4 is a schematic view of a first partial construction of the insulation assembly of the present invention;

FIG. 5 is a schematic view of a second partial construction of the insulating assembly of the present invention;

FIG. 6 is an enlarged view of the energy-saving thermal insulation wall structure A according to the present invention;

FIG. 7 shows a first cross-sectional view of a third web of the present invention;

FIG. 8 shows a second cross-sectional view of a third web of the present invention;

fig. 9 shows a schematic structural view of a first switching unit of the present invention;

fig. 10 shows a schematic structural diagram of a second switching unit of the present invention;

fig. 11 shows a schematic structural diagram of a third switching unit of the present invention;

fig. 12 shows a schematic structural diagram of the energy saving assembly of the present invention.

Labeled as:

1-a wall body, 2-a first connecting plate, 3-a second connecting plate, 4-a third connecting plate, 201-a round rod, 202-a heat insulation plate, 203-a telescopic cylinder, 204-a first linkage plate, 205-a first linkage block, 206-a second linkage block, 207-a first elastic telescopic rod, 208-a shielding plate, 209-a third linkage block, 2010-a fourth linkage block, 2011-a second elastic telescopic rod, 2012-a second linkage plate, 2013-a fifth linkage block, 2014-a third elastic telescopic rod, 2015-a third linkage plate, 2016-a sliding sleeve block, 2017-a linkage frame, 2018-a heat insulation strip, 2019-a first rack, 2020-a straight gear, 2021-a second rack, 2022-a square pipe, 2023-a first dustproof net, 301-a connecting frame, 302-a generator, 303-an impeller, 304-a second dustproof net, 305-a fourth elastic telescopic rod, 306-a scraping rod, 91-a first round hole, 92-a first round hole, 93-a second round hole, 94-a fourth through hole, and a third through hole.

Detailed Description

The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Embodiment 1

An energy-saving heat-insulating wall structure is shown in figures 1-11 and comprises a wall body 1, a first connecting plate 2, a second connecting plate 3, a third connecting plate 4, a heat-insulating plate 202, a shielding plate 208, a heat-insulating strip 2018, a heat-insulating assembly and an energy-saving assembly; the left part and the right part of the front side of the wall body 1 are both connected with a first connecting plate 2 through bolts; the upper sides of the two first connecting plates 2 are provided with a plurality of third round holes 96; a second connecting plate 3 is connected between the upper side and the lower side of each of the two first connecting plates 2 through bolts; the two second connecting plates 3 are fixedly connected with the wall body 1; a third connecting plate 4 is connected between the front sides of the two first connecting plates 2 through bolts; the two second connecting plates 3 are fixedly connected with a third connecting plate 4; a plurality of front and back through first round holes 91 are formed in the third connecting plate 4; a plurality of first channels 92 are transversely arranged on the third connecting plate 4 in an array, and the first channels 92 are communicated with the adjacent first round holes 91; a heat insulation component is connected between the two first connecting plates 2; the middle part of the heat insulation component is connected with a plurality of heat insulation plates 202; every two adjacent left and right heat insulation plates 202 are contacted; the front side of the heat preservation component is connected with a shielding plate 208; the shutter 208 slides inside the third connecting plate 4; the rear side of the heat insulation component is transversely connected with a plurality of heat insulation strips 2018 in an array manner, and the heat insulation strips 2018 and the heat insulation plates 202 are arranged in a crossed manner; the front side of the third connecting plate 4 is connected with a plurality of energy-saving components.

The heat preservation assembly comprises a round rod 201, a telescopic cylinder 203, a first linkage plate 204, a first linkage block 205, a second linkage block 206, a first switching unit, a second switching unit, a third switching unit, a sealing unit and a drainage unit; a plurality of round rods 201 are rotatably connected between the two second connecting plates 3, and the round rods 201 are fixedly connected with adjacent heat insulation plates 202 respectively; the back parts of the upper side phases of the two first connecting plates 2 are fixedly connected with a telescopic cylinder 203, and the back parts of the lower side phases of the two first connecting plates 2 are also fixedly connected with a telescopic cylinder 203; a first linkage plate 204 is fixedly connected between the telescopic ends of every two telescopic cylinders 203 adjacent to each other on the left and right; the rear sides of the two first linkage plates 204 are welded with a plurality of first linkage blocks 205 in a transverse alignment manner; a second linkage block 206 is rotatably connected to the first linkage blocks 205; the left sides of the plurality of second linkage blocks 206 are rotatably connected with the left sides of the adjacent heat insulation plates 202; the middle part of the third connecting plate 4 is connected with a first switching unit; the third connecting plate 4 is connected with a second switching unit which is positioned outside the first switching unit; the two first connecting plates 2 are connected with a third switching unit; the two first connecting plates 2 are connected with sealing units, and the sealing units are positioned behind the first linkage plates 204; the middle of the lower side of the third connecting plate 4 is connected with a drainage unit.

The first switching unit comprises a first elastic telescopic rod 207, a third linkage block 209 and a fourth linkage block 2010; the shielding plate 208 is provided with a plurality of second round holes 94; a plurality of first elastic telescopic rods 207 are fixedly connected to the lower side of the shielding plate 208 in a transverse array; the telescopic ends of the first elastic telescopic rods 207 are fixedly connected with the third connecting plate 4; two third coupling blocks 209 are welded on the upper side of the shielding plate 208; the two third connecting blocks 209 are connected with the third connecting plate 4 in a sliding manner; a fourth linkage block 2010 is connected to the left side and the right side of the first linkage plate 204 positioned above through bolts; two fourth linkage blocks 2010 are respectively in contact with the adjacent third linkage blocks 209; the sides of the two fourth link blocks 2010 near the adjacent third link block 209 are both inclined surfaces.

The second switching unit comprises a second elastic telescopic rod 2011, a second linkage plate 2012 and a fifth linkage block 2013; a second elastic telescopic rod 2011 is fixedly connected with the lower part of the left side and the lower part of the right side of the third connecting plate 4; the telescopic ends of the two second elastic telescopic rods 2011 are fixedly connected with a second linkage plate 2012; the upper sides of the two second linkage plates 2012 are respectively provided with a through hole 95; both second linkage plates 2012 are slidably connected to the third link plate 4; two fifth linkage blocks 2013 are fixedly connected to the first linkage plate 204 located above, and the two fifth linkage blocks 2013 are located on the outer sides of the two third linkage blocks 209; the sides of the two fifth link blocks 2013 adjacent to the adjacent second link plates 2012 are both sloped.

The third switching unit comprises a third elastic telescopic rod 2014 and a third connecting plate 2015; a third elastic telescopic link 2014 is fixedly connected to the upper parts of the inner sides of the two first connecting plates 2; the telescopic ends of the two third elastic telescopic rods 2014 are fixedly connected with a third linkage plate 2015; a plurality of fourth circular holes 97 are formed in the upper sides of the two third connecting plates 2015; the two third link plates 2015 are respectively slidably connected to the adjacent first link plates 2; the upper sides of the two third linkage plates 2015 are both inclined.

The sealing unit comprises a sliding sleeve block 2016, a linkage frame 2017, a first rack 2019, a straight gear 2020 and a second rack 2021; two sliding sleeve blocks 2016 are fixedly connected to the upper portion and the lower portion of the inner side of the wall body 1; a linkage frame 2017 is connected between every two left and right adjacent sliding sleeve blocks 2016 in a sliding mode; the heat insulation strips 2018 are fixedly connected with the two link frames 2017; two first racks 2019 are connected to the rear sides of the two first linkage plates 204 through bolts; the middle parts of the upper sides of the two first connecting plates 2 are respectively and rotatably connected with a straight gear 2020, and the middle parts of the lower sides of the two first connecting plates 2 are also respectively and rotatably connected with a straight gear 2020; the four spur gears 2020 are respectively meshed with the adjacent first racks 2019; the left side and the rear side of the two link frames 2017 are both connected with a second rack 2021 through bolts; the four second racks 2021 are engaged with the adjacent spur gears 2020, respectively.

The drainage unit comprises a square pipe 2022 and a first dust screen 2023; a square pipe 2022 is fixedly connected to the lower part of the front side of the third connecting plate 4; a first dust screen 2023 is fixedly connected to the front side of the square tube 2022; the lower part of the front side and the upper part of the front side of the third connecting plate 4 are both provided with a second channel 93, and the second channel 93 positioned below is V-shaped; the two second channels 93 are respectively communicated with the plurality of first channels 92; the second channel 93 positioned at the lower part is communicated with the square pipe 2022; the through hole 95 communicates with the second passage 93 located above.

When the wall body is used in winter, external cold air flows into the first channel 92 through the first round hole 91, then flows into the second channel 93 from the first channel 92, and is discharged from the second channel 93, the cold air flowing in the process passes through the energy-saving assembly, the energy-saving assembly converts wind energy into electric energy so as to achieve an energy-saving effect, the cold air is shielded by the shielding plate 208 and does not flow to the heat insulation plate 202 and the wall body 1, so that the cold air for wind power generation is prevented from bringing heat out of the wall body 1, the wall body 1 is insulated by the closely arranged heat insulation plates 202, and the problem that the heat insulation effect is low due to the fact that the existing wall body is used in winter for considering wind power generation is solved;

when the wall body 1 is insulated by the closely arranged heat insulation boards 202, the sealing performance of the gaps between the adjacent heat insulation boards 202 is poor because the heat insulation boards 202 are rotating pieces, and the gaps between the adjacent heat insulation boards 202 are plugged by the heat insulation strips 2018 to improve the sealing performance, so that the heat insulation effect of the wall body 1 is improved;

when the heat insulation plate is used in summer, the telescopic cylinder 203 drives the first linkage plate 204 to move forwards, the first linkage plate 204 drives the first linkage block 205 to move forwards, the first linkage block 205 drives the second linkage block 206 to move, the second linkage block 206 drives the heat insulation plate 202 to rotate ninety degrees, meanwhile, the first linkage plate 204 drives the first rack 2019 to move forwards, the first rack 2019 drives the spur gear 2020 to rotate, the spur gear 2020 drives the second rack 2021 to move backwards, the second rack 2021 drives the linkage frame 2017 to slide backwards in the sliding sleeve 2016, the linkage frame 2017 drives the heat insulation strip 2018 to be far away from the heat insulation plate 202, a plurality of heat insulation plates 202 are spaced after the heat insulation plate 202 rotates ninety degrees, the heat insulation effect is stopped to be provided for the wall body 1, and therefore the heat dissipation effect of the wall body 1 is improved;

in the unfolding process of the heat insulation board 202, the first linkage plate 204 drives the fourth linkage block 2010 to move forwards, because one side of the fourth linkage block 2010, which is close to the third linkage block 209, is an inclined surface, the fourth linkage block 2010 pushes the third linkage block 209 to move downwards, the third linkage block 209 drives the shielding plate 208 to move downwards, and simultaneously the first elastic expansion rod 207 is compressed, so that the second round hole 94 on the shielding plate 208 is communicated with the first round hole 91, meanwhile, the first linkage plate 204 drives the fifth linkage block 2013 to move forwards, because one side of the fifth linkage block 2013, which is close to the second linkage plate 2012, is an inclined surface, the fifth linkage block 2013 pushes the second linkage plate 2012 to move downwards and compress the second elastic expansion rod 2011 to block the two second channels 93, meanwhile, the first linkage plate 204 is linked with the linkage frame 2017 to move backwards, the linkage frame 2017 moves backwards to contact with an upper side inclined plane of the third linkage plate 2015 and compress the third elastic expansion rod 2014, so that the linkage frame 2017 pushes the third linkage plate 2015 to move downwards, the third round hole 96 and the fourth round hole 97 on the third linkage plate 2015 are communicated, the second channel 93 is blocked, the first round hole 91 is communicated with the front side cavity of the wall body 1, air flows into the front side cavity of the wall body 1 through the first round hole 91 and then flows out of the third round hole 96 and the fourth round hole 97 to form a new air flow path, heat in the front side cavity of the wall body 1 is brought out through air flow, and the heat dissipation effect of the wall body 1 is further improved;

in rainy days, telescopic cylinder 203 drives first linkage board 204 and moves back to the normal position, first linkage board 204 drives fourth linkage block 2010 and moves back to the normal position, thereby make first elasticity telescopic link 207 kick-back drive shielding plate 208 and move back to the normal position, cut off first round hole 91 again, thereby avoid the rainwater to splash to the front side cavity of heat insulating board 202 and wall body 1 from first round hole 91, thereby avoid influencing the heat preservation effect, simultaneously, the rainwater is hit and is beaten in shielding plate 208 front side backward downward flow to the second passageway 93 of below, because second passageway 93 is the V-arrangement structure, thereby make wherein rainwater collect to square pipe 2022, then discharge from square pipe 2022, reach automatic drainage effect, thereby improve the convenience, first dust screen 2023 is arranged in preventing that impurity from getting into square pipe 2022.

Embodiment 2

On the basis of embodiment 1, as shown in fig. 1, fig. 2, fig. 6 and fig. 12, the energy-saving assembly located at the lower middle part comprises a connecting frame 301, a generator 302, an impeller 303, a second dust screen 304 and a cleaning unit; the middle part of the lower side of the third connecting plate 4 is fixedly connected with a connecting frame 301; the middle part of the connecting frame 301 is fixedly connected with a generator 302; an input shaft of the generator 302 is fixedly connected with an impeller 303; a second dustproof net 304 is fixedly connected to the third connecting plate 4, and the second dustproof net 304 is positioned in front of the impeller 303; the front side of the impeller 303 is connected with a cleaning unit.

The cleaning unit comprises a fourth elastic telescopic rod 305 and a scraping rod 306; a fourth elastic telescopic rod 305 is fixedly connected to the front side of the impeller 303; the telescopic end of the fourth elastic telescopic rod 305 passes through the second dust screen 304; the telescopic end of the fourth elastic telescopic rod 305 is fixedly connected with a scraping rod 306; the rear side of the scraping bar 306 is in contact with the front side of the second dust screen 304.

The specific operation of wind power generation by the energy-saving component in the embodiment 1 is as follows: air flows into the first circular hole 91, passes through the impeller 303, so that the impeller 303 rotates, the impeller 303 drives the input shaft of the generator 302 to rotate, the generator 302 generates electricity, and the effects of energy conservation and emission reduction are achieved; impeller 303 rotates the in-process, and impeller 303 drives fourth elasticity telescopic link 305 and rotates, and fourth elasticity telescopic link 305 drives scrapes pole 306 and rotates to make and scrape the impurity of pole 306 with second dust screen 304 front side and strike off, avoid second dust screen 304 blocking phenomenon to appear, and provide pulling force to scraping pole 306 through fourth elasticity telescopic link 305, make and scrape pole 306 and compress tightly to second dust screen 304 front side all the time, improve and clear away efficiency.

It should be understood by those skilled in the art that the above embodiments do not limit the present invention in any way, and all technical solutions obtained by using equivalent alternatives or equivalent variations fall within the scope of the present invention.

Claims

1. An energy-saving heat-insulating wall structure comprises a wall body (1), a first connecting plate (2), a second connecting plate (3) and a third connecting plate (4); the left part and the right part of the front side of the wall body (1) are fixedly connected with a first connecting plate (2); a second connecting plate (3) is fixedly connected between the upper side and the lower side of each of the two first connecting plates (2); the two second connecting plates (3) are fixedly connected with the wall body (1); a third connecting plate (4) is fixedly connected between the front sides of the two first connecting plates (2); the two second connecting plates (3) are fixedly connected with the third connecting plate (4); the energy-saving heat-insulation board is characterized by also comprising a heat-insulation board (202), a shielding board (208), a heat-insulation strip (2018), a heat-insulation component and an energy-saving component; a plurality of third round holes (96) are formed in the upper sides of the two first connecting plates (2); a plurality of first round holes (91) which are through from front to back are formed in the third connecting plate (4); a plurality of first channels (92) are formed in the third connecting plate (4), and the first channels (92) are communicated with the adjacent first round holes (91); a heat insulation component is connected between the two first connecting plates (2); the middle part of the heat insulation component is connected with a plurality of heat insulation plates (202) in a transverse array; every two adjacent left and right heat insulation plates (202) are contacted; the front side of the heat preservation component is connected with a shielding plate (208); the shielding plate (208) slides inside the third connecting plate (4); the heat insulation component is switched into a heat insulation mode or a heat dissipation mode through a heat insulation plate (202); the airflow path is switched through the shielding plate (208), and the shielding plate (208) is also used for shielding rainwater; the rear side of the heat insulation component is transversely connected with a plurality of heat insulation strips (2018) in an array manner, and the heat insulation strips (2018) and the heat insulation plates (202) are arranged in a crossed manner; the gaps between the closed heat insulation plates (202) are sealed through the heat insulation strips (2018); the front side of the third connecting plate (4) is connected with a plurality of energy-saving components for converting wind energy into electric energy.

2. The energy-saving heat-insulating wall structure as claimed in claim 1, wherein the heat-insulating assembly comprises a round bar (201), a telescopic cylinder (203), a first linkage plate (204), a first linkage block (205), a second linkage block (206), a first switching unit, a second switching unit, a third switching unit, a sealing unit and a drainage unit; a plurality of round rods (201) are rotatably connected between the two second connecting plates (3), and the round rods (201) are fixedly connected with adjacent heat insulation plates (202) respectively; the back parts of the upper sides of the two first connecting plates (2) are fixedly connected with a telescopic cylinder (203), and the back parts of the lower sides of the two first connecting plates (2) are also fixedly connected with a telescopic cylinder (203); a first linkage plate (204) is fixedly connected between the telescopic ends of every two telescopic cylinders (203) which are adjacent left and right; a plurality of first linkage blocks (205) are fixedly connected to the rear sides of the two first linkage plates (204) in a transverse alignment manner; a second linkage block (206) is rotatably connected to the first linkage blocks (205); the left sides of the second linkage blocks (206) are rotatably connected with the left sides of the adjacent heat insulation plates (202); the middle part of the third connecting plate (4) is connected with a first switching unit; the third connecting plate (4) is connected with a second switching unit, and the second switching unit is positioned outside the first switching unit; the two first connecting plates (2) are connected with a third switching unit; the two first connecting plates (2) are connected with sealing units, and the sealing units are positioned behind the first linkage plates (204); the middle part of the lower side of the third connecting plate (4) is connected with a drainage unit.

3. The energy-saving heat-insulating wall structure as claimed in claim 2, wherein the first switching unit comprises a first elastic telescopic rod (207), a third linkage block (209) and a fourth linkage block (2010); a plurality of second round holes (94) are formed in the shielding plate (208); a plurality of first elastic telescopic rods (207) are fixedly connected to the lower side of the shielding plate (208) in a transverse array; the telescopic ends of the first elastic telescopic rods (207) are fixedly connected with the third connecting plate (4); two third coupling blocks (209) are fixedly connected to the upper side of the shielding plate (208); the two third connecting blocks (209) are connected with the third connecting plate (4) in a sliding manner; a fourth linkage block (2010) is fixedly connected to the left side and the right side of the first linkage plate (204) above; the two fourth linkage blocks (2010) are respectively contacted with the adjacent third linkage blocks (209); one side of each of the two fourth linkage blocks (2010) close to the adjacent third linkage block (209) is an inclined surface.

4. The energy-saving heat-insulating wall structure as claimed in claim 3, wherein the second switching unit comprises a second elastic telescopic rod (2011), a second linkage plate (2012) and a fifth linkage block (2013); a second elastic telescopic rod (2011) is fixedly connected with the lower part of the left side and the lower part of the right side of the third connecting plate (4); the telescopic ends of the two second elastic telescopic rods (2011) are fixedly connected with a second linkage plate (2012); the upper sides of the two second linkage plates (2012) are respectively provided with a through hole (95); the two second linkage plates (2012) are both connected with the third connecting plate (4) in a sliding manner; two fifth linkage blocks (2013) are fixedly connected to the first linkage plate (204) positioned above the first linkage plate, and the two fifth linkage blocks (2013) are positioned on the outer sides of the two third linkage blocks (209); one side of each fifth linkage block (2013) close to the adjacent second linkage plate (2012) is an inclined surface.

5. The energy-saving thermal insulation wall structure according to claim 4, wherein the third switching unit comprises a third elastic expansion link (2014) and a third linkage plate (2015); a third elastic telescopic rod (2014) is fixedly connected to the upper parts of the inner sides of the two first connecting plates (2); the telescopic ends of the two third elastic telescopic rods (2014) are fixedly connected with a third linkage plate (2015); a plurality of fourth round holes (97) are formed in the upper sides of the two third connecting plates (2015); the two third linkage plates (2015) are respectively connected with the adjacent first connecting plates (2) in a sliding manner; the upper sides of the two third linkage plates (2015) are both inclined.

6. The energy-saving heat-insulating wall structure according to claim 5, wherein the sealing unit comprises a sliding sleeve block (2016), a linkage frame (2017), a first rack (2019), a straight gear (2020) and a second rack (2021); two sliding sleeve blocks (2016) are fixedly connected to the upper portion and the lower portion of the inner side of the wall body (1); a linkage frame (2017) is connected between every two left and right adjacent sliding sleeve blocks (2016) in a sliding mode; the heat insulation strips (2018) are fixedly connected with the two linkage frames (2017); two first racks (2019) are fixedly connected to the rear sides of the two first linkage plates (204); the middle parts of the upper sides of the two first connecting plates (2) are respectively and rotatably connected with a straight gear (2020), and the middle parts of the lower sides of the two first connecting plates (2) are respectively and rotatably connected with a straight gear (2020); the four straight gears (2020) are respectively meshed with the adjacent first racks (2019); a second rack (2021) is fixedly connected to the left side and the rear side of each of the two linkage frames (2017); the four second racks (2021) are respectively meshed with the adjacent straight gears (2020).

7. The energy-saving heat-insulating wall structure as claimed in claim 6, wherein the drainage unit comprises a square pipe (2022) and a first dust screen (2023); a square pipe (2022) is fixedly connected to the lower part of the front side of the third connecting plate (4); the front side of the square pipe (2022) is fixedly connected with a first dust screen (2023).

8. The energy-saving heat-insulating wall structure according to claim 7, wherein the lower part of the front side and the upper part of the front side of the third connecting plate (4) are provided with a second channel (93), and the lower second channel (93) is V-shaped; the two second channels (93) are respectively communicated with the plurality of first channels (92); the second channel (93) positioned below is communicated with the square pipe (2022); the through hole (95) communicates with the second passage (93) located above.

9. The energy-saving heat-insulating wall structure is characterized in that the energy-saving assembly positioned in the middle of the lower side comprises a connecting frame (301), a generator (302), an impeller (303), a second dust screen (304) and a cleaning unit; the middle part of the lower side of the third connecting plate (4) is fixedly connected with a connecting frame (301); the middle part of the connecting frame (301) is fixedly connected with a generator (302); an impeller (303) is fixedly connected to an input shaft of the generator (302); a second dustproof net (304) is fixedly connected to the third connecting plate (4), and the second dustproof net (304) is positioned in front of the impeller (303); the front side of the impeller (303) is connected with a cleaning unit.

10. The energy-saving heat-insulating wall structure as claimed in claim 9, wherein the cleaning unit comprises a fourth elastic telescopic rod (305) and a scraping rod (306); a fourth elastic telescopic rod (305) is fixedly connected to the front side of the impeller (303); the telescopic end of the fourth elastic telescopic rod (305) penetrates through the second dust screen (304); the telescopic end of the fourth elastic telescopic rod (305) is fixedly connected with a scraping rod (306); the rear side of the scraping rod (306) is contacted with the front side of the second dust screen (304).