CN219386914U - Thermal insulation module and house surface structure of heavy steel mill - Google Patents

Abstract

The utility model belongs to the technical field of heat-insulating roofs of steel structure plants, and particularly relates to a heat-insulating module and a house surface structure of a heavy steel plant. According to the utility model, the cavity structure and the water pipe are arranged, and water is filled in the water pipe, so that the heat preservation module is formed, the temperature difference in the factory building can be effectively regulated by utilizing the characteristic of larger specific heat capacity of water, the temperature in the factory building is maintained constant, and the heat preservation performance is improved. Through setting up the waterproof board, cooperation water catch bowl and drain pipe for rivers concentrate and assemble orderly discharge, avoid producing ponding at roofing seam crossing, prevent to appear the infiltration phenomenon of leaking, effectively promote the waterproof performance of steel construction factory building roofing structure. The heat preservation module and the roof are simple in structure, convenient to install and detach, energy-saving and environment-friendly, and beneficial to popularization and application in production practice.

Description

Thermal insulation module and house surface structure of heavy steel mill

Technical Field

The utility model belongs to the technical field of heat-insulating roofs of steel structure plants, and particularly relates to a heat-insulating module and a house surface structure of a heavy steel plant.

Background

The steel structure building has the advantages of high fire resistance, strong corrosion resistance, convenient moving, no pollution in recycling and the like, and is increasingly applied to factory building construction. The steel structure factory building is widely applied to enterprises such as textile industry due to the short construction period, low manufacturing cost, high strength, large workshop column span, convenient arrangement and the like. The roof is used as an enclosure structure, so that the interior of a building can be effectively protected. Conventional roof structures include a plurality of roof beams and a plurality of roof layers stacked on a roof surface to provide insulation or waterproofing properties for protecting a building. The roof of the existing steel structure factory building can not effectively solve the problems of water resistance and poor heat insulation performance of the factory building roof, so that the temperature inside the factory building is dispersed relatively quickly, and energy waste is caused. For this reason, improvements to conventional roofing structures are desired.

The technical scheme in patent CN201821607827.9, including connecting screw, lower heat preservation, last heat preservation, bottom plate, first bolt hole, splice groove and the waterproof cushion of second, maintain the temperature in the factory building through setting up the insulating layer. Simultaneously, lay a plurality of apron on the factory building roof for the rainwater flows down through the runner, can not pile up on the apron, has guaranteed that the inside temperature of factory building can not distribute out, and outside rainwater also can not flow into the factory building inside through the apron. Thereby achieving the effects of energy conservation and environmental protection, and simultaneously having the advantages of material saving, simple processing and firm connection.

In the scheme, the upper and lower heat-insulating layers are used to wrap the heat-insulating layer in the middle, although the heat in the factory building can be prevented from being lost rapidly,

but can cause a significant amount of heat build up inside the plant. So that the temperature in the factory building is too high in the daytime, especially in summer. Further influence the life-span of the equipment in the factory building and the safety of the operators. And when the night comes, the temperature outside the factory building is reduced, especially in winter. The steel structure factory building only adopts the heat-insulating materials made of phenolic foam and glass fiber materials to form the roof structure, the heat conductivity coefficient of the materials is still larger, the heat-insulating effect is poor, and the heat transfer between the inside and the outside of the roof structure is too fast. The temperature change in the steel structure factory building is larger, the roof structure of the steel structure factory building is easy to expand with heat and contract with cold, the roof structure is misplaced, the local cracking is carried out, the waterproof layer is damaged, and the roof leakage is caused.

Disclosure of Invention

The utility model provides a heat preservation module and a house surface structure of a heavy steel factory, which are used for overcoming the defects that the house surface structure of the heavy steel factory in the prior art is poor in heat preservation performance, large in temperature change difference in the factory, inconstant in temperature and unordered in drainage, water accumulation is easy to occur at a roof joint, water seepage and water leakage occur, pedestrian traffic is influenced, and noise is overlarge.

In order to achieve the purpose of the utility model, the utility model is realized by the following technical scheme:

a heat preservation module comprises at least two heat preservation boards, a sealed cavity is formed between every two adjacent heat preservation boards, a water pipe is arranged in each heat preservation board, and water is filled in each water pipe. The heat-insulating plate further comprises heat-insulating side walls, and two ends of the heat-insulating plate are respectively connected with the heat-insulating side walls in series.

The traditional steel structure factory building wall is thin, and the heat insulation effect is relatively poor. The temperature of the steel structure roof can reach 50-60 ℃ under the sun exposure, and the temperature of the steel structure roof can be rapidly reduced to 15-25 ℃ after the rain gusts. Especially in summer or daytime in the north, the temperature in the factory building is too high, and even after taking cooling measures, the proper working temperature is difficult to reach. In winter or at night, the outdoor temperature is low, and the heat transfer of the roof structure is faster, so that the environment temperature in the factory building can be maintained only by continuously supplying heat. The temperature change in the steel structure factory building is great, and is not invariable, influences workman's operation and equipment life in the factory building. Meanwhile, the steel structure roof can generate larger expansion deformation in a short time under a huge temperature difference, and the ridge cover plate and the sealant are extremely easy to break, so that the waterproof function of the roof system is damaged, and the water leakage phenomenon is generated.

The heat preservation module comprises at least two heat preservation boards, and a sealed cavity is formed between two adjacent heat preservation boards. Through setting up the cavity structure between adjacent heated board, block off the hot air, be favorable to improving the heat preservation performance of roof structure. In addition, be provided with the water pipe in the heated board, water is filled in the water pipe. The heat absorption capacity is strong, but the heat conduction capacity is weak due to the fact that the specific heat capacity of water is large. The characteristic of larger specific heat capacity of water is utilized, so that the temperature in the factory building is kept constant. When summer or daytime, the water in the water pipe can absorb more heat, and meanwhile, the temperature is raised slowly, so that the temperature in the factory building cannot be raised rapidly. The water heat conduction capability in the water pipe is weak, so that the temperature of the steel structure roof of the factory building cannot be quickly increased, and meanwhile, the heat transfer with the outdoor environment is not easy to occur, and the water pipe has a good cooling effect. When winter or night, more heat can be released by water in the water pipe, and meanwhile, the temperature is lowered slowly, so that the temperature in the factory building cannot be lowered rapidly. And then, the rapid temperature reduction of the steel structure roof of the factory building is effectively avoided, and meanwhile, the heat transfer with the outdoor environment is not easy to occur, so that the heat preservation effect is good.

Preferably, the heat-insulating plate further comprises heat-insulating side walls, and two ends of the heat-insulating plate are respectively connected with the heat-insulating side walls in series.

Further preferably, the heat-insulating board may be made of phenolic foam or polyurethane foam, polystyrene board, EPS, XPS organic material, or may be made of ceramic fiber blanket, glass wool, rock wool, or foamed cement inorganic material. The cavity structure can be filled with air or nitrogen gas with small heat conductivity coefficient.

The two ends of the heat-insulating plate are provided with heat-insulating side walls for fixed connection, which is beneficial to enhancing the structural strength of the heat-insulating module. Meanwhile, the heat-insulating side wall is matched with the heat-insulating plate to be firmly connected, so that the sealing performance of the cavity is improved. The arrangement of the cavity structure can form a relatively static air layer between adjacent heat insulation boards, so that no heat transfer or little heat transfer is realized between the heat insulation boards, double-layer heat insulation is formed, and the heat insulation effect is effectively improved.

Preferably, the heat insulation plate further comprises struts which are positioned in the cavity and distributed at equal intervals, and two ends of each strut are fixedly connected with the adjacent heat insulation plates respectively.

Preferably, the struts may be distributed in a grid shape formed by combining transverse directions, longitudinal directions or longitudinal directions in the cavity, and the struts may be made of channel steel, I-steel, round steel or square steel.

The struts are arranged in the cavity at equal intervals, so that the pressure bearing capacity of the heat insulation plate is increased, and the support is enhanced.

The utility model provides a house face structure of heavy steel mill, includes heat preservation module, still includes:

the support frame is positioned on the roof of the factory building and is fixedly connected with the roof;

the waterproof assembly is positioned above the heat preservation module, and two ends of the waterproof assembly are fixedly connected with the support frame to guide water to flow downwards;

the photovoltaic module is located above the waterproof module and fixedly connected with the support frame and used for collecting solar energy.

Conventional roofing structural designs are mostly aimed at achieving the goal of extending the life expectancy of the roofing structure by improving the performance of the roofing material. The basic frame structure of the roof structure is not changed, but the waterproof roof structure is still provided. The service life of a conventional roofing structure is therefore dependent on the service life of its materials. The existing roof structure enables rainwater to flow down from the flow channels by arranging two waterproof rubber mats between the cover plates and matching with the water guide protruding blocks, and although the outside rainwater can be prevented from flowing into the factory building through the cover plates, the rainwater flows down along multiple groups of flow channels simultaneously. The water curtain hole is easy to form under the eave, and rainwater flows out in rows. Therefore, rainwater can directly drop to the ground along the eave in rainy days, pedestrian traffic is affected, and excessive noise is generated. Meanwhile, water is easy to be accumulated at the joint of the roof, and water seepage and water leakage occur. Further destroy structures such as roofing, wall body and support column, the water-proof effects worsen, influence factory building life.

The heavy steel factory house surface structure comprises a heat preservation module and a support frame which is positioned on a factory house roof and fixedly connected with the factory house roof. Through set up the support frame on the factory building roofing for insulation module and other roofing structural component can fixed mounting on the support frame, and the installation operation is simpler. Meanwhile, the functional components of each part of the roof structure are convenient to detach, and later maintenance and replacement are convenient. A waterproof assembly is arranged above the heat preservation module, and two ends of the waterproof assembly are fixedly connected with the support frame, so that water is guided to flow downwards. The waterproof assembly is arranged, so that rainwater is concentrated and discharged, the water seepage and water leakage phenomena are effectively avoided, and the drainage efficiency is further improved. And a photovoltaic module is arranged above the waterproof module and is fixedly connected with the support frame for collecting solar energy. The collected solar energy is directly or indirectly converted into electric energy through photoelectric effect or photochemical effect, so that the energy-saving and environment-friendly effects are realized, and the renewable energy utilization rate is improved.

Preferably, the number of the supporting frames is at least two, and the supporting frames comprise supporting legs. The supporting legs are positioned on the roof of the factory building and are fixedly connected with the roof.

As a further preference, the interior of the support frame may be provided with a cavity structure. The cavity structure can be filled with air or nitrogen gas with small heat conductivity coefficient to form a relatively static gas heat insulation layer. The heat transfer in the support frame is not or little, so that double-layer heat preservation is formed, and the heat preservation effect is effectively improved. The support columns distributed at equal intervals can be additionally arranged in the cavity structure, so that the bearing performance of the support frame is improved, the structural strength is improved, and the support stability is enhanced.

Through set up the support frame on the factory building roofing for insulation module and other roofing structural component can fixed mounting on the support frame, and the installation operation is simpler. Meanwhile, the functional components of each part of the roof structure are convenient to detach, and later maintenance and replacement are convenient.

Preferably, the support frame further comprises a first support arm for supporting the waterproof assembly. The second support arm parallel to the first support arm is arranged below the first support arm, and the upper end of the second support arm is provided with a limiting lock catch in parallel. A first caulking groove for embedding the heat preservation module is formed between the second supporting arm and the limiting lock catch, so that two ends of the heat preservation module can be embedded into the first caulking groove, and the heat preservation module is limited.

Through setting up the second support arm and supporting heat preservation module, reuse first caulking groove and spacing hasp cooperation are used to carry out spacing fixedly to heat preservation module, make between heat preservation module and the support frame fixed firm.

Preferably, the waterproof assembly comprises a waterproof plate, and two ends of the waterproof plate extend upwards obliquely to be abutted against the support frame. A plurality of bending parts are arranged on the waterproof board, and drainage grooves are formed between adjacent bending parts.

The two ends of the waterproof board extend upwards obliquely to be abutted against the supporting frame, so that water accumulation at the joint of the roof is effectively avoided. So as to prevent water seepage and water leakage. Further effectively avoiding damaging structures such as roofing, wall body, support column, etc. Is beneficial to enhancing the waterproof effect and prolonging the service life of the factory building. By forming the drainage groove between the adjacent bending parts on the waterproof board, rainwater can flow out along the drainage groove, and the rainwater is prevented from flowing into the factory building. At the same time, the water drainage efficiency is improved.

Preferably, the first support arm is provided with a protrusion, and the protrusion is clamped with the bending part at the side part of the waterproof board.

The first support arm is provided with the bulge and the bending part at the side part of the waterproof board for clamping, so that the waterproof board is limited, and the waterproof board and the support frame are propped firmly.

Preferably, the top edge of the support frame is fixedly connected with a water collecting ditch. The sump is aligned with the drain for directing water from the drain to the sump. The drain pipe is fixedly connected with the lower end of the water collecting ditch, and the other end of the drain pipe extends downwards to the ground.

By arranging the water collecting ditch and the water draining pipe, the rainwater is concentrated and discharged. Effectively avoid forming "water curtain hole" under the eave, prevent that rainwater from directly dripping to ground along the eave when raining day, influence pedestrian traffic and produce the noise too big.

Preferably, the photovoltaic module comprises a solar collecting plate, a fixing lock catch is further arranged at the top of the supporting frame, and a second caulking groove used for embedding the solar collecting plate is formed between the fixing lock catch, so that two ends of the solar collecting plate can be embedded into the second caulking groove, and the solar collecting plate is fixed.

Through the cooperation of second caulking groove and fixed hasp use make fixed connection between solar collecting plate and the support frame, the installation is dismantled conveniently. The problem that the traditional solar roof structure is installed and needs to be drilled on the roof structure is avoided, and the roof structure is damaged. In addition, the collected solar energy is directly or indirectly converted into electric energy through photoelectric effect or photochemical effect, so that the energy-saving and environment-friendly effects are realized, and the renewable energy utilization rate is improved.

Therefore, the utility model has the following beneficial effects:

(1) According to the utility model, the cavity structure and the water pipe are arranged, and water is filled in the water pipe, so that the heat preservation module is formed, the temperature difference in the factory building can be effectively regulated by utilizing the characteristic of larger specific heat capacity of water, the temperature in the factory building is maintained constant, and the heat preservation performance is improved;

(2) According to the utility model, the waterproof board is arranged and matched with the water collecting channel and the water discharging pipe, so that water flow is concentrated and orderly discharged, water accumulation at the joint of the roof is avoided, water seepage and water leakage are prevented, and the waterproof performance of the roof structure of the steel structure factory building is effectively improved;

(3) The heat preservation module and the roof are simple in structure, convenient to install and detach, energy-saving and environment-friendly, and beneficial to popularization and application in production practice.

Drawings

FIG. 1 is a schematic diagram of a thermal insulation module;

FIG. 2 is a top view of a thermal module;

FIG. 3 is an exploded perspective view of a roof structure of a heavy steel plant;

FIG. 4 is a cross-sectional view of a heavy steel mill house face structure;

FIG. 5 is a schematic perspective view of a heavy steel plant;

fig. 6 is an enlarged schematic view of the heavy steel mill housing face structure a of fig. 5.

In the figure: a thermal insulation board 1; a cavity 2; a water pipe 3; a thermal insulation side wall 4; a pillar 5; a support frame 6; a factory building roof 7; a waterproof assembly 8; a photovoltaic module 9; a foot 10; a first support arm 11; a second support arm 12; a limit lock catch 13; a first caulking groove 14; a waterproof board 15; a bending portion 16; a drain tank 17; a protrusion 18; a water collecting channel 19; a drain pipe 20; a solar energy collection plate 21; a fixed latch 22; a second caulking groove 23; a thermal insulation module 24.

Detailed Description

The utility model is further described below with reference to the drawings and specific examples. Those of ordinary skill in the art will be able to implement the utility model based on these descriptions. In addition, the embodiments of the present utility model referred to in the following description are typically only some, but not all, embodiments of the present utility model. Therefore, all other embodiments, which can be made by one of ordinary skill in the art without undue burden, are intended to be within the scope of the present utility model, based on the embodiments of the present utility model.

As shown in fig. 1-6, the insulation module 24 in the present utility model comprises at least two insulation boards 1, and a sealed cavity 2 is formed between two adjacent insulation boards 1. In addition, a water pipe 3 is provided in the heat insulating plate 1. The water pipe 3 is filled with water. As another embodiment, the water pipe 3 may be filled with other liquid having a larger specific heat capacity.

The heat insulation plate further comprises heat insulation side walls 4, and two ends of the heat insulation plate 1 are respectively connected with the heat insulation side walls 4 in series.

As an embodiment, the heat-insulating board 1 may be made of phenolic foam or polyurethane foam, polystyrene board, EPS, XPS organic material, or may be made of ceramic fiber blanket or glass wool, rock wool, foamed cement inorganic material. The cavity 2 can be filled with air or nitrogen gas with small heat conductivity coefficient.

The two ends of the heat insulation board 1 are provided with the heat insulation side walls 4 for fixed connection, which is beneficial to enhancing the structural strength of the heat insulation module 24. Meanwhile, the heat-insulating side wall 4 is matched with the heat-insulating plate 1 to be firmly connected, so that the sealing performance of the cavity 2 is improved. The arrangement of the cavity 2 structure can form a relatively static air layer between the adjacent heat insulation boards 1, so that no heat transfer or little heat transfer is realized between the heat insulation boards 1, double-layer heat insulation is formed, and the heat insulation effect is effectively improved.

The heat insulation plate also comprises struts 5 which are positioned in the cavity 2 and distributed at equal intervals, and two ends of each strut 5 are fixedly connected with the adjacent heat insulation plate 1 respectively.

As an embodiment, the struts 5 may be distributed in a grid shape formed by combining the transverse direction, the longitudinal direction, or the transverse direction and the longitudinal direction in the cavity 2, and the struts 5 may be made of channel steel, i-steel, round steel, or square steel.

The struts 5 are arranged in the cavity 2 at equal intervals, which is beneficial to increasing the bearing capacity of the heat insulation board 1 and reinforcing the support.

The heavy steel factory building roof 7 structure comprises a heat preservation module 24 and a support frame 6 which is positioned on the factory building roof 7 and fixedly connected with the factory building roof 7. A waterproof assembly 8 is arranged above the heat preservation module 24, and two ends of the waterproof assembly 8 are fixedly connected with the support frame 6, so that water is guided to flow downwards. A photovoltaic module 9 is arranged above the waterproof module 8, and the photovoltaic module 9 is fixedly connected with the support frame 6 and is used for collecting solar energy.

The number of support frames 6 is at least two, and the support frames 6 comprise support legs 10. The support legs 10 are positioned on the factory building roof 7 and fixedly connected with the factory building roof 7.

As an embodiment, the interior of the support frame 6 may be configured as a cavity 2. The cavity 2 can be filled with air or nitrogen gas with small heat conductivity coefficient to form a relatively static gas heat insulation layer. So that no heat transfer or little heat transfer is carried out in the support frame 6, thereby forming double-layer heat preservation and effectively improving the heat preservation effect. The equally spaced struts 5 can be added in the cavity 2 structure, which is beneficial to improving the bearing performance of the support frame 6, increasing the structural strength and enhancing the support stability.

Through set up support frame 6 on factory building roofing 7 for thermal insulation module 24 and other roofing structural component can fixed mounting on support frame 6, and the installation operation is simpler. Meanwhile, the functional components of each part of the roof structure are convenient to detach, and later maintenance and replacement are convenient.

The support frame 6 further comprises a first support arm 11 for supporting the waterproof assembly 8. A second supporting arm 12 parallel to the first supporting arm 11 is arranged below the first supporting arm 11, and a limiting lock catch 13 is arranged at the upper end of the second supporting arm 12 in parallel. A first caulking groove 14 for embedding the heat preservation module 24 is formed between the second supporting arm 12 and the limiting lock catch 13, so that two ends of the heat preservation module 24 can be embedded into the first caulking groove 14, and the heat preservation module 24 is limited. So that the heat preservation module 24 and the support frame 6 are firmly fixed.

The flashing assembly 8 comprises a flashing 15. As an embodiment, the waterproof board 15 has a cross section in a folded curved shape, such as a trapezoid or a circular arc. Both ends of the waterproof board 15 extend obliquely upward to abut against the supporting frame 6. Effectively avoid water accumulation at the joint of the roof. So as to prevent water seepage and water leakage. Further effectively avoiding damaging structures such as roofing, wall body, support column, etc. Is beneficial to enhancing the waterproof effect and prolonging the service life of the factory building. The waterproof plate 15 is provided with a plurality of bent portions 16, and a drain groove 17 is formed between adjacent bent portions 16. So that rainwater can flow out along the drainage groove 17, and rainwater is prevented from flowing into the factory building. At the same time, the water drainage efficiency is improved.

The first supporting arm 11 is provided with a protrusion 18, and the protrusion 18 is clamped with the bending part 16 at the side part of the waterproof board 15. Thereby limiting the waterproof board 15, and being beneficial to firm propping between the waterproof board 15 and the supporting frame 6.

The top edge of the support frame 6 is fixedly connected with a water collecting ditch 19. The water collection trough 19 is aligned with the water drain 17 for directing water from the water drain 17 to the water collection trough 19. The lower end of the water collecting channel 19 is fixedly connected with a water discharging pipe 20, and the other end of the water discharging pipe 20 extends downwards to the ground. Thereby enabling rainwater to be concentrated and discharged. Effectively avoid forming "water curtain hole" under the eave, prevent that rainwater from directly dripping to ground along the eave when raining day, influence pedestrian traffic and produce the noise too big.

The photovoltaic module 9 comprises a solar collector plate 21. The top of the support frame 6 is also provided with fixing catches 22, and a second caulking groove 23 for embedding the solar collecting plate 21 is formed between the fixing catches 22. So that both ends of the solar collector plate 21 can be inserted into the second caulking groove 23, thereby playing a fixing role for the solar collector plate 21.

Through the cooperation of second caulking groove 23 and fixed hasp 22, make fixed connection between solar collector plate 21 and the support frame 6, the installation is dismantled conveniently. The problem that the traditional solar roof structure is installed and needs to be drilled on the roof structure is avoided, and the roof structure is damaged. In addition, the collected solar energy is directly or indirectly converted into electric energy through photoelectric effect or photochemical effect, so that the energy-saving and environment-friendly effects are realized, and the renewable energy utilization rate is improved.

The specific working principle of the embodiment is as follows:

the heat preservation module 24 comprises at least two heat preservation boards 1, and a sealed cavity 2 is formed between two adjacent heat preservation boards 1. Thereby the hot air is blocked, and the heat preservation performance of the roof structure is improved. In addition, a water pipe 3 is arranged in the heat insulation board 1, and water is filled in the water pipe 3. The characteristic of large specific heat capacity of water is utilized to adjust the temperature difference in the factory building, and the temperature in the factory building is maintained constant. The heat absorption capacity is strong, but the heat conduction capacity is weak due to the fact that the specific heat capacity of water is large. The characteristic of larger specific heat capacity of water is utilized, so that the temperature in the factory building is kept constant. When summer or daytime, the water in the water pipe 3 can absorb more heat, and meanwhile, the temperature is raised slowly, so that the temperature in the factory building cannot be raised rapidly. The water heat conduction capability in the water pipe 3 is weak, so that the temperature of the steel structure roof of the factory building cannot be quickly increased, and meanwhile, the heat transfer with the outdoor environment is not easy to occur, and the cooling effect is good. When winter or night, more heat can be released by water in the water pipe 3, and meanwhile, the temperature is lowered slowly, so that the temperature in the factory building cannot be lowered rapidly. And then, the rapid temperature reduction of the steel structure roof of the factory building is effectively avoided, and meanwhile, the heat transfer with the outdoor environment is not easy to occur, so that the heat preservation effect is good.

The heavy steel factory house surface structure comprises a heat preservation module 24 and a support frame 6 which is positioned on a factory roof 7 and fixedly connected with the factory roof 7. Through set up support frame 6 on factory building roofing 7 for thermal insulation module 24 and other roofing structural component can fixed mounting on support frame 6, and the installation operation is simpler. Meanwhile, the functional components of each part of the roof structure are convenient to detach, and later maintenance and replacement are convenient. A waterproof assembly 8 is provided above the thermal insulation module 24, the waterproof assembly 8 including a waterproof plate 15. Both ends of the waterproof board 15 extend obliquely upward to abut against the supporting frame 6. Effectively avoid water accumulation at the joint of the roof. So as to prevent water seepage and water leakage. The waterproof plate 15 is provided with a plurality of bent portions 16, and a drain groove 17 is formed between adjacent bent portions 16. So that rainwater can flow out along the drainage groove 17, and rainwater is prevented from flowing into the factory building. The top edge of the support frame 6 is fixedly connected with a water collecting ditch 19. The lower end of the water collecting channel 19 is fixedly connected with a water discharging pipe 20, and the other end of the water discharging pipe 20 extends downwards to the ground. The water collection trough 19 is aligned with the water drain 17 for directing water from the water drain 17 to the water collection trough 19. Thereby enabling rainwater to be concentrated and discharged. A photovoltaic module 9 is arranged above the waterproof module 8, and the photovoltaic module 9 is fixedly connected with the support frame 6 and is used for collecting solar energy. The collected solar energy is directly or indirectly converted into electric energy through photoelectric effect or photochemical effect, so that the energy-saving and environment-friendly effects are realized, and the renewable energy utilization rate is improved.

Claims (9)

1. The heat preservation module is characterized by comprising at least two heat preservation boards (1), wherein a sealed cavity (2) is formed between two adjacent heat preservation boards (1), a water pipe (3) is arranged in each heat preservation board (1), and water is filled in each water pipe; the heat-insulating plate further comprises heat-insulating side walls (4), and two ends of the heat-insulating plate (1) are respectively connected with the heat-insulating side walls (4) in series.

2. A thermal insulation module according to claim 1, further comprising equally spaced struts (5) located in the cavity (2), wherein two ends of the struts (5) are fixedly connected to adjacent thermal insulation panels (1) respectively.

3. A heavy steel mill house face structure, characterized by comprising a thermal insulation module (24) according to any one of claims 1-2, further comprising:

the support frame (6) is positioned on the factory building roof (7) and is fixedly connected with the factory building roof;

the waterproof component (8) is positioned above the heat preservation module (24), and two ends of the waterproof component are fixedly connected with the support frame (6) to guide water to flow downwards;

the photovoltaic module (9) is positioned above the waterproof module (8) and is fixedly connected with the support frame (6) for collecting solar energy.

4. A heavy steel mill house face structure according to claim 3, characterized in that the number of the supporting frames (6) is at least two, the supporting frames (6) comprise supporting feet (10), and the supporting feet (10) are positioned on the house roof (7) and fixedly connected with the house roof.

5. A heavy steel mill house face structure according to claim 3 or 4, characterized in that the supporting frame (6) further comprises a first supporting arm (11) for supporting the waterproof assembly (8), a second supporting arm (12) parallel to the first supporting arm (11) is arranged below the first supporting arm (11), a limit lock catch (13) is arranged at the upper end of the second supporting arm (12) in parallel, a first caulking groove (14) for embedding the heat preservation module (24) is formed between the second supporting arm (12) and the limit lock catch (13), and two ends of the heat preservation module (24) can be embedded into the first caulking groove (14), so that the heat preservation module (24) is limited.

6. The house face structure of heavy steel works according to claim 5, characterized in that the waterproof assembly (8) comprises a waterproof board (15), both ends of the waterproof board (15) extend obliquely upwards to abut against the supporting frame (6), the waterproof board (15)

A plurality of bending parts (16) are arranged on the water draining groove (17) is formed between the adjacent bending parts (16).

7. The house face structure of the heavy steel mill according to claim 6, wherein the first supporting arm (11) is provided with a protrusion (18), and the protrusion (18) is clamped with a bending part (16) at the side part of the waterproof board (15).

8. A heavy steel mill house face structure according to claim 6, characterized in that the top edge of the supporting frame (6) is fixedly connected with a water collecting channel (19), the water collecting channel (19) is aligned with the water draining channel (17) for guiding water to flow from the water draining channel (17) to the water collecting channel (19), the lower end of the water collecting channel (19) is fixedly connected with a water draining pipe (20), and the other end of the water draining pipe (20) extends downwards to the ground.

9. A heavy steel mill house face structure according to claim 3, characterized in that the photovoltaic module (9) comprises solar collector panels (21), the top of the support frame (6) is further provided with fixing catches (22), and second caulking grooves (23) for embedding the solar collector panels (21) are formed between the fixing catches (22), so that two ends of the solar collector panels (21) can be embedded into the second caulking grooves (23), thereby playing a role in fixing the solar collector panels (21).