CN111811026B

CN111811026B - Heat radiation type bay window capable of realizing hot spring stone plate function

Info

Publication number: CN111811026B
Application number: CN202010613608.7A
Authority: CN
Inventors: 俞学炜; 廖文武
Original assignee: Xiamen Special Economic Zone Real Estate Development Group Co ltd
Current assignee: Xiamen Special Economic Zone Real Estate Development Group Co ltd
Priority date: 2020-06-30
Filing date: 2020-06-30
Publication date: 2021-05-04
Anticipated expiration: 2040-06-30
Also published as: CN111811026A

Abstract

The invention relates to a heat radiation type bay window capable of realizing the function of a hot spring stone slab, which comprises an EPE cushion layer, wherein a plate-shaped heat insulation layer is respectively paved between the periphery of the EPE cushion layer and the side wall of the bay window; a bottom thermal insulation layer; the prefabricated heating plates are formed by covering aluminum foils on a U-shaped steel wire mesh; the heat conduction mechanism comprises a plurality of heat conduction pipes erected at the opening end of the U-shaped steel wire mesh, the adjacent two heat conduction pipes are respectively communicated and connected through communication pipes arranged in a staggered manner, and a layer of heat conduction metal mesh is coated on the peripheries of the heat conduction pipes and the communication pipes; the window panel mechanism that wafts, the window panel mechanism that wafts contains wooden floor layer, and the bottom surface rigid coupling on wooden floor layer has a plurality of supporting beam, and supporting beam contains the cross-section and is the support groove of U shape, and the inside packing in support groove has the heat-retaining material layer. The invention can effectively improve the heat energy transfer amount per unit area in the heating process, and can heat the surface temperature of the bay window to 40 ℃, so that the bay window has the function of a hot spring stone plate.

Description

Heat radiation type bay window capable of realizing hot spring stone plate function

Technical Field

The invention relates to a heat radiation type bay window, in particular to a heat radiation type bay window capable of realizing the function of a hot spring stone slab.

Background

The bay window not only can increase the lighting and ventilation functions of the house type, but also adds architectural charm to the facade of the commercial house, so the bay window is already the standard matching of the house type of the mainstream commercial house at present. As the additional functions of the bay window gradually move toward the leisure area, people have an increasing percentage of time spent on leisure and entertainment on the bay window. In order to improve the thermal comfort of the bay window area, a heating mechanism can be additionally arranged on the bay window to cope with the weather of winter or transition season, so that the leisure function of the bay window is further improved.

The traditional bay window heating mostly adopts electric heating equipment to directly heat, the use safety is relatively low, high-grade energy (electric energy) is directly utilized to convert the high-grade energy into heat energy, and the energy utilization rate is low. Therefore, most of the existing bay windows are heated by transferring a heat exchange medium (low-temperature hot water) through a heat medium pipeline, and the bay windows are effectively heated through heat exchange in the transferring process of the heat exchange medium. Two heat exchange and heating modes are provided through the heat medium pipeline, one mode is that the heat medium pipeline is coated through a concrete filling mode, the integral supporting effect of the bay window can be ensured through the arrangement of the concrete filling layer, and the heat can be effectively stored through the concrete filling layer; the window panel that wafts is heated through the thermal radiation mode to another kind, supports through the supporting beam that sets up side by side, then coils the heat medium pipeline between supporting beam, directly heats the window panel that wafts through the thermal radiation heating mode, reduces the setting of concrete filling layer, has solved the heat inertia problem that the concrete filling layer conducts heat well, has realized the efficient promptly hot, satisfies the life habit of fast rhythm nowadays.

However, the bay window heated by thermal radiation has two significant drawbacks: 1) the heat radiation type floating window has high heat transfer efficiency, namely good heating performance, but has poor heat energy storage effect and high heat dissipation speed, so that the energy consumption is high, and the surface temperature of the floating window cannot be effectively maintained at more than 30 ℃, and the conventional heat radiation type floating window does not have the function of a hot spring stone plate; 2) the heat radiation of the heat medium pipeline arranged in a coiling way is radiated and expanded in a 'line' way, so that the problem of less heat energy transfer in unit area exists in the actual heating process of the heat radiation, and larger ineffective heat loss exists.

Therefore, on the basis of not increasing energy consumption, through structure addition and improvement, a heat transfer rate and heat transfer uniformity can be effectively improved, so that the heat energy transfer amount per unit area in the heating process is effectively improved, and the ineffective heat loss is effectively reduced; the window can effectively form a better energy storage effect on heat energy, so that the surface temperature of the bay window is effectively heated and effectively kept at about 40 ℃ while the energy consumption is reduced, and the thermal radiation type bay window which has the function of the thermal spring stone plate and can realize the function of the thermal spring stone plate is the research object of the invention.

Disclosure of Invention

In view of the problems in the prior art, the present invention is to provide a thermal radiation type bay window capable of implementing a function of a thermal spring stone slab, which can effectively solve the technical problems in the prior art.

The technical scheme of the invention is as follows:

a heat radiation type bay window capable of realizing the function of a hot spring stone slab comprises

The upper surface of the EPE cushion layer is paved with a layer of reflecting film, and a layer of plate-shaped heat insulation layer is respectively paved between the periphery of the EPE cushion layer and the side wall of the bay window;

the bottom heat insulation layer is laid on the lower end surface of the bay window bottom plate;

the prefabricated heating plates are laid above the reflecting film at equal intervals, each prefabricated heating plate is formed by covering an aluminum foil on a U-shaped steel wire mesh, and the opening ends of the U-shaped steel wire meshes are arranged in a mode of being turned outwards;

the heat conduction mechanism comprises a plurality of heat conduction pipes erected at the opening end of the U-shaped steel wire mesh, the adjacent two heat conduction pipes are respectively communicated and connected through communication pipes arranged in a staggered manner, and a layer of heat conduction metal mesh is coated on the peripheries of the heat conduction pipes and the communication pipes;

the window panel mechanism that wafts, the window panel mechanism that wafts contains wooden floor layer, the bottom surface on wooden floor layer has a plurality of corresponding supporting beam according to equidistant downward rigid coupling, supporting beam is located respectively between two adjacent prefabricated heating boards, and supporting beam's bottom is installed in the reflectance coating top, and supporting beam contains the cross-section and is the support groove of U shape, the notch department of supporting groove turns over the setting of turning over to the outside, and supports the inside packing in groove and have the heat-retaining material layer.

The heat storage material layer is formed by stacking granular volcanic rocks.

The first heat pipe of the heat conduction mechanism is outwards connected with an external hot water inlet pipe, and the water outlet end of the last heat pipe of the heat conduction mechanism is outwards connected with an external water outlet pipe.

The external hot water inlet pipe is connected to an external hot water source through a corresponding hot water pump and a three-way temperature control valve, the water outlet end of the external water outlet pipe is connected to an external water return pipe through a corresponding water outlet valve, and a corresponding bypass pipe is communicated and connected between the external water outlet pipe and the water inlet end of the three-way temperature control valve.

The wood floor layer fixing device is provided with a temperature sensor, and the temperature sensor, the hot water pump and the three-way temperature control valve are respectively connected to corresponding electric controllers.

The U-shaped steel wire mesh and the heat-conducting metal mesh are both made of phi 3@50 steel wire mesh sheets.

The plate-shaped heat insulation layer and the bottom heat insulation layer are both made of extruded polystyrene boards, and a layer of single-component polyurethane adhesive is arranged between the plate-shaped heat insulation layer and the side wall of the bay window and between the bottom heat insulation layer and the bottom board of the bay window.

The reflection film is a floor heating reflection film which is formed by compounding and processing a vacuum aluminum-plated film, a polyester film and glass fibers, and a layer of white latex adhesive is arranged between the reflection film and the EPE cushion layer.

The heat conducting pipe and the communicating pipe are made of one of PE-X full plastic pipe, PE-RT full plastic pipe, PB full plastic pipe or PP-R full plastic pipe.

A control method of a heat radiation type bay window capable of realizing the function of a hot spring stone slab is characterized by comprising the following specific control steps:

s1, acquiring the actual temperature T1 of the wood floor layer;

s2, judging whether the actual temperature T1 is higher than the preset high-zone temperature Tmax, if so, closing the hot water pump, otherwise, starting the hot water pump, and entering the step S3;

s3, judging whether the difference value delta T between the actual temperature T1 and the high-zone preset temperature Tmax is within the set temperature difference delta Tmax, if yes, entering the step S4, and if not, entering the step S5;

s4, controlling the three-way temperature control valve to enable the hot water part of the bypass pipe to flow back to the external hot water inlet pipe for recycling;

s5, controlling the three-way temperature control valve to directly feed water from the heat source end;

s6, turning off the hot water pump until the actual temperature T1 reaches the preset high-zone temperature Tmax,

s7, judging whether the actual temperature T1 is higher than the preset temperature Tmin of the low zone, if so, closing the hot water pump, otherwise, starting the hot water pump to continue heating, and entering the step 3.

The invention has the advantages that:

1) the prefabricated heating plate is formed by covering an aluminum foil on a U-shaped steel wire mesh, and the opening end of the U-shaped steel wire mesh is arranged in a mode of being turned outwards. The aluminum foil covers the U-shaped steel wire mesh, so that the heat transfer area of the U-shaped steel wire mesh can be increased, the contact area between the heat-conducting metal mesh on the periphery of the heat-conducting pipe and the aluminum foil is increased, the aluminum foil on the surface of the U-shaped steel wire mesh and the heat-conducting metal mesh on the periphery of the heat-conducting pipe wrap the heat-conducting pipe to form a heat source radiation integral surface, the heat-conducting pipe is effectively and quickly converted into a surface radiation by using the excellent heat transfer performance of the aluminum foil, the ineffective heat loss is reduced to the maximum extent, the heat transfer amount of unit area heat energy in the heating process is effectively improved, and the heat transfer rate and the heat transfer uniformity.

2) Utilize U-shaped wire mesh to erect the heat pipe in U-shaped wire mesh open end, existing installation and the fixing that is favorable to the pipeline, suitably raise the heat pipe again, the heat that makes the heat pipe produce can more add even scattering to reinforcing effective radiant heat upwards, making heat transmission faster, more balanced.

3) The structure of the supporting beam is completely new designed and divided into a supporting groove with a U-shaped section and a heat storage material layer filled in the supporting groove. When heating, the heat-conducting metal net, the U-shaped steel wire net and the aluminum foil covered on the U-shaped steel wire net quickly and cooperatively act to quickly and uniformly radiate heat energy to the wood floor layer and the supporting groove, the heat energy transferred to the wood floor layer can effectively and quickly raise the temperature of the wood floor layer to reach the comfortable temperature of a human body, and at the moment, the heat transfer and the heat dissipation are basically balanced; the heat energy transferred to the supporting groove can be effectively absorbed by the heat storage material layer filled in the supporting groove, and the heating and energy storage are realized. Along with the temperature rise of the heat storage material layer, the heat storage material layer starts to supplement heat energy to the wood floor layer, at the moment, the heat transfer quantity starts to be larger than the heat dissipation quantity, and the temperature of the wood floor layer can be increased again. Not only can effectively reduce energy consumption, but also can effectively heat the surface temperature of the bay window and effectively keep the surface temperature at about 40 ℃, so that the bay window has the function of a hot spring stone plate.

4) The supporting grooves and the heat storage material layer are integrated to support the wood floor layer, and the notches of the supporting grooves are outwards turned, so that the supporting surfaces of the supporting grooves and the heat storage material layer on the wood floor layer are effectively increased, the energy consumption is reduced, and the surface load capacity of the wood floor layer is effectively improved.

5) When the wood floor heating device is used, the temperature of the wood floor layer can be heated to a high-area preset temperature value, then the circulation of the heat-conducting medium can be stopped, and further heat supply is carried out by releasing heat stored by the heat storage material layer until the temperature of the wood floor layer is reduced to a low-area preset temperature value, and then the circulation of the heat-conducting medium is started, so that the energy consumption is effectively and greatly reduced. When the invention is used, the three-way temperature control valve can be controlled by the electric controller, so that the water mixing proportion of water supply and return water can be adjusted in real time according to the change of the actual temperature, the waste heat of the return water can be fully utilized to meet the requirement of heating the bay window, the energy consumption of heat source equipment is further reduced, and the effect of energy conservation is further achieved.

6) The invention also has the advantages of maintainability and environmental protection: the whole body is paved without a backfill mode, and if the problems such as blockage and the like occur, the heat conduction mechanism can be conveniently overhauled; the raw materials and finished products of the bay window panel mechanism and the like have no pollution to the environment and can be recycled.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of a heat pipe installed on a prefabricated heating board.

Fig. 3 is a schematic structural diagram of the heat conducting mechanism.

Fig. 4 is an installation schematic diagram of a temperature sensor, a hot water pump and a three-way temperature control valve.

Fig. 5 is a control flow chart of a thermal comfort type bay window control method.

Detailed Description

To facilitate understanding of those skilled in the art, the structure of the present invention will now be described in further detail by way of examples in conjunction with the accompanying drawings:

referring to fig. 1 to 4, a thermal radiation type bay window capable of performing a function of a thermal spring stone plate includes

The upper surface of the EPE cushion layer 1 is paved with a layer of reflection film 3, and a layer of plate-shaped heat insulation layer 5 is respectively paved between the periphery of the EPE cushion layer 1 and the side wall 4 of the bay window;

the bottom heat insulation layer 6 is laid on the lower end face of the bay window bottom plate 2;

the prefabricated heating plates 7 are laid above the reflecting film 3 at equal intervals, each prefabricated heating plate 7 is formed by covering an aluminum foil 702 on a U-shaped steel wire mesh 701, and the opening end of each U-shaped steel wire mesh 701 is turned outwards;

the heat conduction mechanism 8 comprises a plurality of heat conduction pipes 801 erected at the opening ends of the U-shaped steel wire mesh 701, two adjacent heat conduction pipes 801 are communicated and connected through communication pipes 802 arranged in a staggered mode respectively, and the peripheries of the heat conduction pipes 801 and the communication pipes 802 are coated with a layer of heat conduction metal mesh 9;

window panel mechanism 10 wafts, window panel mechanism 10 wafts contains wooden floor layer 1001, the bottom surface of wooden floor layer 1001 has a plurality of corresponding supporting beam 1002 according to equidistant downward rigid coupling, supporting beam 1002 is located respectively between two adjacent prefabricated heating boards 7, and the bottom of supporting beam 1002 installs in reflectance coating 3 top, and supporting beam 1002 contains the cross-section for the support groove 10021 of U-shaped, the notch department of support groove 10021 turns over the setting outwards, and the inside packing of support groove 10021 has heat-retaining material layer 10022.

The heat storage material layer 10022 is formed by stacking granular volcanic rocks.

The first heat pipe of the heat conducting mechanism 8 is connected with an external hot water inlet pipe 11, and the water outlet end of the last heat pipe of the heat conducting mechanism 8 is connected with an external water outlet pipe 12.

The external hot water inlet pipe 11 is connected to an external hot water source through a corresponding hot water pump 13 and a three-way temperature control valve 14 (the three-way temperature control valve 14 in this embodiment is directly obtained from the market, the three-way temperature control valve 14 can be replaced by a three-way pipe with flow control valves arranged at two water inlet ends), the water outlet end of the external water outlet pipe 12 is connected to an external water return pipe through a corresponding water outlet valve 15, and a corresponding bypass pipe 16 is connected between the water inlet ends of the external water outlet pipe 12 and the three-way temperature control valve 14 in a communicating manner.

The wood floor layer 1001 is fixed with a temperature sensor 17, and the temperature sensor 17, the hot water pump 13 and the three-way temperature control valve 14 are respectively connected to a corresponding electric controller 18.

The U-shaped steel wire mesh 701 and the heat-conducting metal mesh 9 are both made of phi 3@50 steel wire mesh sheets.

The plate-shaped heat insulation layer 5 and the bottom heat insulation layer 6 are made of extruded polystyrene boards, a plastering layer 19 is arranged between the plate-shaped heat insulation layer 5 and the side wall 4 of the bay window and between the bottom heat insulation layer 6 and the bay window bottom plate 2, and a single-component polyurethane adhesive is arranged among the plate-shaped heat insulation layer 5, the bottom heat insulation layer 6 and the plastering layer 19.

The reflection film 3 is a floor heating reflection film which is formed by compounding and processing a vacuum aluminum-plated film, a polyester film and glass fibers, and a layer of white latex adhesive is arranged between the reflection film 3 and the EPE cushion layer 1.

The heat conducting pipe 801 and the communicating pipe 802 are made of PE-X full plastic pipes.

Referring to fig. 4-5, an embodiment of the invention further provides a method for controlling the thermal radiation type bay window capable of implementing the function of the thermal spring slate, comprising:

s1, acquiring the actual temperature T1 of the wood floor layer 1001;

s2, judging whether the actual temperature T1 is higher than the preset high-zone temperature Tmax, if so, closing the hot water pump 13, otherwise, starting the hot water pump 13 and entering the step S3;

s4, controlling the three-way temperature control valve 14 to enable the hot water part of the bypass pipe 16 to flow back to the external hot water inlet pipe 11 for recycling;

s5, controlling the three-way temperature control valve 14 to directly feed water from the heat source end;

s6, turning off the hot water pump 13 until the actual temperature T1 reaches the high-zone preset temperature Tmax,

s7, judging whether the actual temperature T1 is higher than the low-zone preset temperature Tmin or not, if so, closing the hot water pump 13, otherwise, starting the hot water pump 13 to continue heating, and entering the step 3.

The low zone preset temperature Tmin and the high zone preset temperature Tmax can be set according to different actual requirements, and under the conventional condition, Tmin is 20 ℃, Tmax is 27 ℃, and when the hot spring stone slab is used, Tmin is 35 ℃ and Tmax is 42 ℃.

In step S3, Δ Tmax is 5 ℃. When the set temperature difference Δ Tmax is too large, for example, Δ Tmax is 15 ℃, because the temperature of the external water outlet pipe 12 is low, at this time, the hot water portion of the bypass pipe 16 is controlled to flow back to the external hot water inlet pipe 11 for recycling, which is not beneficial to rapidly heating the wood floor layer 1001 to the high zone preset temperature Tmax. When the set temperature difference Δ Tmax is too small, for example, Δ Tmax is 1 ℃, since the water temperature of the external water outlet pipe 12 is high, a part of the water will be lost, which is not favorable for improving the utilization rate of energy.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. The utility model provides a can realize window that wafts of heat radiation type of hot spring slabstone function which characterized in that: comprises that

The upper surface of the bay window bottom plate (2) is paved with an EPE cushion layer (1), the upper surface of the EPE cushion layer (1) is paved with a layer of reflecting film (3), and a layer of plate-shaped heat insulation layer (5) is respectively paved between the periphery of the EPE cushion layer (1) and the side wall (4) of the bay window;

the bottom heat insulation layer (6) is laid on the lower end face of the bay window bottom plate (2);

the prefabricated heating plates (7) are laid above the reflecting film (3) at equal intervals, each prefabricated heating plate (7) is formed by covering an aluminum foil (702) on a U-shaped steel wire mesh (701), and the opening end of each U-shaped steel wire mesh (701) is arranged in a mode that the opening end is turned outwards;

the heat conduction mechanism (8) comprises a plurality of heat conduction pipes (801) erected at the opening ends of the U-shaped steel wire mesh (701), the adjacent two heat conduction pipes (801) are communicated and connected through communication pipes (802) arranged in a staggered mode, and the peripheries of the heat conduction pipes (801) and the communication pipes (802) are coated with a layer of heat conduction metal mesh (9);

the window-floating panel mechanism (10), the window-floating panel mechanism (10) comprises a wood floor layer (1001), the bottom surface of the wood floor layer (1001) is fixedly connected with a plurality of corresponding supporting beams (1002) downwards at equal intervals, the supporting beams (1002) are respectively located between two adjacent prefabricated heating plates (7), the bottoms of the supporting beams (1002) are installed above the reflecting film (3), each supporting beam (1002) comprises a supporting groove (10021) with a U-shaped cross section, the notch of each supporting groove (10021) is arranged in an outward turning mode, and a heat storage material layer (10022) is filled in each supporting groove (10021);

the layer of heat storage material (10022) is formed by a stack of granular volcanic rock;

the first heat pipe of the heat conduction mechanism (8) is outwards connected with an external hot water inlet pipe (11), and the water outlet end of the last heat pipe of the heat conduction mechanism (8) is outwards connected with an external water outlet pipe (12).

2. A thermal radiation type bay window capable of performing a function of a spa plate as claimed in claim 1, wherein: the external hot water inlet pipe (11) is connected to an external hot water source through a corresponding hot water pump (13) and a three-way temperature control valve (14), the water outlet end of the external water outlet pipe (12) is connected to an external water return pipe through a corresponding water outlet valve (15), and a corresponding bypass pipe (16) is communicated and connected between the external water outlet pipe (12) and the water inlet end of the three-way temperature control valve (14).

3. A thermal radiation type bay window capable of performing a function of a spa plate as claimed in claim 2, wherein: a temperature sensor (17) is arranged on the wood floor layer (1001) in a fixing mode, and the temperature sensor (17), the hot water pump (13) and the three-way temperature control valve (14) are connected to corresponding electric controllers (18) respectively.

4. A thermal radiation type bay window capable of performing a function of a spa plate as claimed in claim 1, wherein: the U-shaped steel wire mesh (701) and the heat conducting metal mesh (9) are both made of phi 3@50 steel wire mesh sheets.

5. A thermal radiation type bay window capable of performing a function of a spa plate as claimed in claim 1, wherein: the plate-shaped heat insulation layer (5) and the bottom heat insulation layer (6) are made of extruded polystyrene boards, one plastering layer (19) is arranged between the plate-shaped heat insulation layer (5) and the side wall (4) of the bay window and between the bottom heat insulation layer (6) and the base plate (2) of the bay window, and one single-component polyurethane adhesive is arranged among the plate-shaped heat insulation layer (5), the bottom heat insulation layer (6) and the plastering layer (19).

6. A thermal radiation type bay window capable of performing a function of a spa plate as claimed in claim 1, wherein: the reflection film (3) is a floor heating reflection film which is formed by compounding and processing a vacuum aluminum-plated film, a polyester film and glass fibers, and a layer of white latex adhesive is arranged between the reflection film (3) and the EPE cushion layer (1).

7. A thermal radiation type bay window capable of performing a function of a spa plate as claimed in claim 1, wherein: the heat conducting pipe (801) and the communicating pipe (802) adopt one of PE-X full plastic pipe, PE-RT full plastic pipe, PB full plastic pipe or PP-R full plastic pipe.

8. The method for controlling a thermal radiation type bay window capable of performing a function of a spa plate according to claim 3, wherein the specific steps of the control are as follows:

s1, acquiring the actual temperature T1 of the wood floor layer (1001);

s2, judging whether the actual temperature T1 is higher than the preset high-zone temperature Tmax, if so, closing the hot water pump (13), otherwise, starting the hot water pump (13) and entering the step S3;

s4, controlling the three-way temperature control valve (14) to enable the hot water part of the bypass pipe (16) to flow back to the external hot water inlet pipe (11) for cyclic utilization;

s5, controlling the three-way temperature control valve (14) to directly feed water from the heat source end;

s6, turning off the hot water pump (13) until the actual temperature T1 reaches the preset high-zone temperature Tmax,

s7, judging whether the actual temperature T1 is higher than the preset temperature Tmin of the low zone, if so, closing the hot water pump (13), otherwise, starting the hot water pump (13) to continue heating and entering the step (3).