CN209413123U - Intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules - Google Patents

Abstract

The utility model belongs to building material technical field, is related to a kind of intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules.It, which is solved, is difficult to stop simultaneously in the prior art the technical issues of visible light and infrared light are injected in extraneous solar radiation.It includes spacer bar, spacer bar side is provided with low-radiation film coated glass, and the other side is provided with temperature-control discoloring energy-saving glass, and low-radiation film coated glass, temperature-control discoloring energy-saving glass and spacer bar are surrounded into seal chamber, several phase-change accumulation energy items are equipped in seal chamber, phase-change accumulation energy item is located on spacer bar.Compared with prior art, the utility model can stop high-temperature field to change light transmittance according to temperature change while radiation to the hot-fluid of low temperature field, to control influence of the solar radiation to room temperature.

Description

Intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules

Technical field

The utility model belongs to building material technical field, more particularly, to a kind of low-emission coated hollow glass of intelligent temperature control Glass energy saving modules.

Background technique

In modern architecture, alien invasion is often used glass curtain wall, and glass curtain wall facade is beautiful, has good daylighting, it is deep by People like.But there is also certain disadvantages for glass curtain wall, such as compared to wall, the heat-insulating capability of simple glass curtain wall is poor, When the outer temperature difference is larger indoors, it is easy to happen heat exchange, influences air-conditioning system cooling or heating effect, the energy is considerably increased and disappears Consumption.Common preparing low-emissivity coated hollow glass, outdoor surface glass often mostly use low radiation coated glass, and indoor surface glass uses Non- coated glass.When constituting hollow glass, coated surface is only applicable in dry hollow cavity, cannot play coated surface completely Heat insulation.With the requirement of low-carbon energy-saving environmental protection, the heat-proof quality requirement of preparing low-emissivity coated hollow glass is also higher and higher, because This, the requirement to the heat transfer coefficient and shading coefficient of preparing low-emissivity coated hollow glass is higher and higher.

Summary of the invention

The purpose of this utility model is in view of the above-mentioned problems, providing a kind of intelligent temperature control preparing low-emissivity coated hollow glass energy conservation Component.

In order to achieve the above objectives, the utility model uses following technical proposal: this intelligent temperature control is low-emission coated hollow Glass energy-saving component, including spacer bar, the spacer bar side are provided with low-radiation film coated glass, and the other side is provided with temperature control change Color energy-saving glass, the low-radiation film coated glass, temperature-control discoloring energy-saving glass and spacer bar are surrounded into seal chamber.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, low-radiation film coated glass is outdoor face glass Glass, temperature-control discoloring energy-saving glass are indoor surface glasses.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, low radiation coated glass is due to silver-colored function The effect of layer, plays heat insulation function；Temperature-control discoloring energy-saving glass, have as the temperature rises and solar energy intake by The characteristic gradually reduced.When in torridity summer, temperature is higher, through first layer low radiation coated glass remaining solar radiant energy into One step is significantly improved by second layer temperature-control discoloring glass barrier, heat-proof quality.In cold winter, temperature is lower, thoroughly The remaining solar radiant energy of first layer low radiation coated glass is crossed completely through second layer temperature-control discoloring glass, enters the room, makes Indoor solar intake is obtained to increase.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, low-radiation film coated glass and temperature-control discoloring section Energy glass is tightly connected with spacer bar respectively, and air is filled between the low-radiation film coated glass and temperature-control discoloring energy-saving glass Or inert gas.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, low-radiation film coated glass includes the first plate Glass and low-radiation film, the low-radiation film close to seal chamber and in seal chamber air or inert gas be in contact.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, low-radiation film coated glass is Silver-based low emissivity Any one in coated glass or non-silver-based low radiation coated glass.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, temperature-control discoloring energy-saving glass includes one piece Second plate glass and temperature-control discoloring film, the temperature-control discoloring film close to seal chamber and with the air or inertia in seal chamber Gas is in contact.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, temperature-control discoloring film is tungsten oxide WOx, oxygen Change vanadium VOx, titanium oxide TiOx, the anorganic thermochromics material such as molybdenum oxide MoOx or temperature sensing color changing material or liquid crystal, Material of Fluoran, Triarylmethane compound, organic thermochromic materials such as spiro-pyrans class seat, husband's bases it is one or more.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, low-radiation film coated glass and temperature-control discoloring section Butyl rubber can be provided between glass and spacer bar.

In above-mentioned intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, spacer bar is set far from the side of seal chamber It is equipped with packing, the packing is tightly attached on spacer bar, low-radiation film coated glass and temperature-control discoloring energy-saving glass.

Compared with prior art, utility model has the advantages that

Low radiation coated glass and temperature-control discoloring energy-saving glass dual-use are guaranteeing that glass assembly heat-proof quality is good Meanwhile glass transmitance is furthermore achieved and increases and reduces with temperature, especially summer, excessive solar radiation can be obstructed It enters the room, influences air-conditioning system work, to reduce energy consumption, play energy-saving effect.

Detailed description of the invention

Fig. 1 is structural schematic diagram provided by the utility model.

Fig. 2 is the structural schematic diagram of embodiment two provided by the utility model.

Fig. 3 is the structural schematic diagram of embodiment three provided by the utility model.

It is spacer bar 1, low-radiation film coated glass 2, temperature-control discoloring energy-saving glass 3, seal chamber 4, the first plate glass 5, low in figure Radiate film 6, the second plate glass 7, temperature-control discoloring film 8, packing 9.

Specific embodiment

The following will be combined with the drawings in the embodiments of the present invention, carries out the technical scheme in the embodiment of the utility model Clearly and completely describe, it is clear that the described embodiments are only a part of the embodiments of the utility model, rather than whole Embodiment.Based on the embodiments of the present invention, those of ordinary skill in the art are without creative efforts Every other embodiment obtained, fall within the protection scope of the utility model.

Embodiment one

As shown in Figure 1, this intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, including spacer bar 1, spacer bar 1 one Side is provided with low-radiation film coated glass 2, and the other side is provided with temperature-control discoloring energy-saving glass 3, the low-radiation film coated glass 2, temperature control Discoloration energy-saving glass 3 and spacer bar 1 are surrounded into seal chamber 4, and the low-radiation film coated glass 2 is set close to the side of seal chamber 4 It is equipped with low-radiation film 6, the temperature-control discoloring energy-saving glass 3 is provided with temperature-control discoloring film 8 close to the side of seal chamber 4.

Low-radiation film coated glass 2 plays heat insulation function due to low-emission coated 6 effect；Temperature-control discoloring energy-saving glass 3, have as the temperature rises and characteristic that solar energy intake gradually decreases.When in torridity summer, temperature is higher, through room The remaining solar radiant energy of outer low-radiation film coated glass 2 is further stopped by indoor temperature control photo chromic glass 3, prevent solar radiation from It enters the room, the heat-proof quality of the utility model is significantly improved.In cold winter, temperature is lower, through Low emissivity The solar radiant energy of film glass 2 is entered the room completely through temperature-control discoloring glass 3, so that indoor solar intake increases, together When room temperature stopped by low-radiation film coated glass, prevent indoor and outdoor from carrying out heat exchange, so that indoor heat loss, reduces air-conditioning system System workload, reduces energy consumption.

Low-radiation film coated glass 2 and temperature-control discoloring energy-saving glass 3 are tightly connected with spacer bar 1 respectively, the low-radiation film Air or inert gas are filled between glass 2 and temperature-control discoloring energy-saving glass 3.The low-radiation film coated glass 2 further includes First plate glass 5, the low-radiation film 6 be covered in the first plate glass 5 close to the side of seal chamber 4 and with seal chamber 4 In air or inert gas be in contact.The temperature-control discoloring energy-saving glass 3 further includes one piece of second plate glass 7, institute The temperature-control discoloring film 8 stated be covered in the second plate glass 7 close to the side of seal chamber 4 and with air in seal chamber 4 or lazy Property gas is in contact.

Low-radiation film 6 and temperature-control discoloring film 8 are respectively carrier with the first plate glass 5 and the second plate glass 7, and are sealed Be in contact in seal chamber 4 with dry air or inert gas, effectively slow down low-radiation film 6 and temperature-control discoloring film 8 because high temperature, The oxidation rate of the extraneous factors such as strong light, extends low-radiation film 6 and 8 service life of temperature-control discoloring film.

Preferably, the low-radiation film coated glass 2 is Silver-based low emissivity coated glass or the low-emission coated glass of non-silver-based One of glass.Preferably, the temperature-control discoloring film 8 is tungsten oxide WOx, vanadium oxide VOx, titanium oxide TiOx, molybdenum oxide The anorganic thermochromics such as MoOx material or temperature sensing color changing material or liquid crystal, Material of Fluoran, triarylmethane compound, spiro-pyrans class seat, husband's alkali Organic thermochromic material such as class it is one or more.

Wherein, in the present embodiment, low-radiation film coated glass 2 is preferably single silver low-radiation coated glass, and preferably second is flat Dielectric layer is provided between glass sheet 7 and low-radiation film 6, dielectric layer includes once being distributed outward by 7 side of the second plate glass SiNx layer and ZnAlOx layers, SiNx layer is directly plated on glass-base, plays the role of bottoming, can stop glass base The migration and diffusion of sodium ion in bottom.Its dielectric layer can also only include SiNx layer, can also be including SiNx layer, ZnSnOx layers and ZnAlOx layers of combination layer.Low radiation coated glass 2 is also possible to double-silver low-emissivity coated glass, Three-silver-layer low-radiation coated glass Equal Silver-based low emissivities coated glass.

Low-radiation film 6 includes functional layer and protective layer, and functional layer can combine for Ag layers or Ag layers with Cu layers, wherein Ag Layer is with a thickness of 6-23nm, and Cu layers with a thickness of 1-5nm.Protective layer includes the combination layer of NiCr layers with AZO layers, wherein NiCr layers can Ag layers of metal are prevented to be oxidized, and AZO layers due to film layer dense uniform, can be improved the combination of metal NiCr layer and dielectric layer Power improves the stability of film layer structure.Protective layer thickness is 3-20nm.

Under the extraneous condition of high temperature low-radiation film coated glass 2 and temperature-control discoloring energy-saving glass 3 stop simultaneously extraneous visible light with Black light reduces interior to extraneous solar radiation intake, avoids influencing indoor temperature change generated in case.And under extraneous low-temperature condition Low-radiation film coated glass 2 prevents indoor heat from leaking, while temperature-control discoloring energy-saving glass 3 is pellucidity, so that extraneous visible light Into interior energy-saving effect can be further functioned as to increase indoor heat by transillumination easily.

Preferably, butyl rubber is provided between low-radiation film coated glass 2 and temperature-control discoloring energy-saving glass 3 and spacer bar 1.Wherein Butyl rubber is isobutene glue.

Preferably, spacer bar 1 is provided with packing 9 far from the side of seal chamber 4, and the packing 9 is tightly attached to interval On item 1, low-radiation film coated glass 2 and temperature-control discoloring energy-saving glass 3.Wherein packing is TR sealant.

Embodiment two

The basic structure of embodiment two is basically the same as the first embodiment, the difference lies in that being provided in the seal chamber 4 Phase-change accumulation energy item 10, under summer day hot weather, phase-change accumulation energy item 10 absorbs solar radiation heat, is further reduced heat It enters the room.And in winter, it absorbs solar radiation heat daytime, is reduced to dusk ambient temperature, phase-change accumulation energy item 10 releases Heat reduces and further decreases indoor heat with the indoor temperature difference, the indoor heat exchanger effectiveness with glass of reduction and leak.

Wherein phase-change accumulation energy item 10 includes shell, is filled with phase-changing energy storage material in shell, the art technology energy should Know, phase-changing energy storage material is made of Sodium acetate trihydrate, anti-cryogen, anti-layering agent and the water-retaining agent crossed.

Preferably, the second plate glass 7 is provided with light collecting part 11 far from the side of seal chamber 4, and the light collecting part 11 is set It sets in the outside of phase-change accumulation energy item 10,11 outwardly convex of light collecting part and is arc-shaped.Sunlight is sent out after penetrating light collecting part 11 Raw refraction effect, gathers on phase-change accumulation energy item 10, so that phase-change accumulation energy item 10 stores rapidly big energy, improves phase-change accumulation energy The difference of item 10 and ambient temperature improves the response speed that phase-change accumulation energy item 10 releases energy.

Embodiment three

The basic structure of embodiment three and the structure of embodiment one are essentially identical, the difference lies in that the temperature-control discoloring Energy-saving glass 3 is provided with third plate glass far from the side of low-radiation film coated glass 2, and third plate glass is in the second plate glass Low-radiation film is provided between 7.In cold winter, temperature is lower, complete through the solar radiant energy of low-radiation film coated glass 2 It through temperature-control discoloring glass 3, enters the room, so that indoor solar intake increases, while room temperature is by flat positioned at second Low-radiation film coated glass of the glass sheet between third plate glass stops, and prevents indoor and outdoor from carrying out heat exchange, so that indoor heat It scatters and disappears, reduces air-conditioning system workload, reduce energy consumption.

The specific embodiments described herein are merely examples of the spirit of the present invention.The utility model institute Belonging to those skilled in the art can make various modifications or additions to the described embodiments or using similar Mode substitute, but without departing from the spirit of the present application or beyond the scope of the appended claims.

Although be used more herein spacer bar 1, low-radiation film coated glass 2, temperature-control discoloring energy-saving glass 3, seal chamber 4, The terms such as the first plate glass 5, low-radiation film 6, the second plate glass 7, temperature-control discoloring film 8, packing 9, but be not precluded and make A possibility that with other terms.The use of these terms is merely for the convenience of describing and explaining the nature of the invention； It is contrary to the spirit of the present invention to interpret them as any one of the additional limitations.

Claims (9)

1. a kind of intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules, including spacer bar (1), the spacer bar (1) one Side is provided with low-radiation film coated glass (2), and the other side is provided with temperature-control discoloring energy-saving glass (3), which is characterized in that the low spoke Film glass (2), temperature-control discoloring energy-saving glass (3) and spacer bar (1) is penetrated to surround into seal chamber (4), the low-radiation film glass Glass (2) is provided with low-radiation film (6) close to the side of seal chamber (4), and the temperature-control discoloring energy-saving glass (3) is close to seal chamber (4) side is provided with temperature-control discoloring film (8), and phase-change accumulation energy item (10), phase-change accumulation energy item are provided in the seal chamber (4) (10) include shell, phase-changing energy storage material is filled in shell, it is outwardly convex that setting is provided on temperature-control discoloring energy-saving glass (3) The light collecting part (11) for rising and being arc-shaped.

2. intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules according to claim 1, which is characterized in that described Low-radiation film coated glass (2) and temperature-control discoloring energy-saving glass (3) are tightly connected with spacer bar (1) respectively, the low-radiation film glass Air or inert gas are filled between glass (2) and temperature-control discoloring energy-saving glass (3).

3. intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules according to claim 2, which is characterized in that described Low-radiation film coated glass (2) further includes the first plate glass (5), and it is close that the low-radiation film (6) is covered in the first plate glass The side of seal chamber (4) and in seal chamber (4) air or inert gas be in contact.

4. intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules according to claim 3, which is characterized in that described Low-radiation film coated glass (2) is Silver-based low emissivity coated glass or non-silver-based low radiation coated glass.

5. intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules according to claim 2, which is characterized in that described Temperature-control discoloring energy-saving glass (3) further includes one piece of second plate glass (7), and it is flat that the temperature-control discoloring film (8) is covered in second Glass sheet (7) close to seal chamber (4) side and in seal chamber (4) air or inert gas be in contact.

6. intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules according to claim 5, which is characterized in that described Temperature-control discoloring film (8) anorganic thermochromic material or temperature sensing color changing material or organic thermochromic material it is one or more.

7. intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules according to claim 2, which is characterized in that described Butyl rubber is provided between low-radiation film coated glass (2) and temperature-control discoloring energy-saving glass (3) and spacer bar (1).

8. intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules according to claim 7, which is characterized in that described Low-radiation film coated glass (2) is outdoor surface glass, and temperature-control discoloring energy-saving glass (3) is indoor surface glass.

9. intelligent temperature control preparing low-emissivity coated hollow glass energy saving modules according to claim 8, which is characterized in that described Spacer bar (1) is provided with packing (9) far from the side of seal chamber (4), and the packing (9) is tightly attached to spacer bar (1), low On radiation film coated glass (2) and temperature-control discoloring energy-saving glass (3).