CN215220742U - Novel photovoltaic module - Google Patents

Abstract

The utility model provides a novel photovoltaic module, which comprises a photovoltaic cell and a first combined film structure, wherein the first combined film structure is arranged on the back surface of the photovoltaic cell, the first combined film structure comprises a multilayer transparent film layer, and at least two first reflecting interfaces are formed on the multilayer transparent film layer; the ultraviolet light is reflected by the two first reflection interfaces to form a first reflection light and a second reflection light which depart from the photovoltaic cell piece, and the first reflection light and the second reflection light can constructively interfere with each other to selectively improve the reflection of the ultraviolet light. The first combined film structure provided by the application has good ultraviolet resistance and low cost. Therefore, the novel photovoltaic module using the first combined membrane structure has the advantages of good ultraviolet resistance, low cost, good flexibility and wide application range, and can be applied to automobiles, ships, color steel tile roofs, building curtain walls and the like.

Description

Novel photovoltaic module

Technical Field

The utility model relates to a solar photovoltaic power generation field, in particular to novel photovoltaic module.

Background

The solar backboard is an important component of a solar photovoltaic cell structure and plays roles in insulating and protecting a solar photovoltaic cell. The mainstream solar back panel in the world is a composite back panel material made of a fluorine-containing material. The back plates used by domestic component manufacturers mostly depend on import, the market price is high, and the technology is monopolized by foreign enterprises. The scheme of the low-cost solar backboard is that an anti-ultraviolet agent is utilized, and a coating modified PET (polyethylene terephthalate) film is used for replacing a fluorine-containing material, but the anti-ultraviolet coating modified PET material has limited anti-ultraviolet capability and poor weather resistance, and the manufacturing process is a non-environment-friendly chemical coating process.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a novel photovoltaic module that ultraviolet resistance can be good and the cost is lower.

In order to achieve the above object, the utility model provides a novel photovoltaic module, include:

a photovoltaic cell sheet having a front surface for facing sunlight and a back surface opposite to the front surface; and the number of the first and second groups,

the first combined film structure is arranged on the back surface of the photovoltaic cell piece and comprises a plurality of layers of transparent films, and at least two first reflecting interfaces are formed on the plurality of layers of transparent films;

object light rays are reflected from the two first reflection interfaces to form first reflection light rays and second reflection light rays which are deviated from the photovoltaic cell piece, the first reflection light rays and the second reflection light rays can be subjected to constructive interference, and the object light rays are ultraviolet light rays and/or infrared light rays.

Optionally, the novel photovoltaic module further includes a second combined film structure, the second combined film structure is disposed on the front side of the photovoltaic cell, and at least two second reflective interfaces are formed on the second combined film structure;

and object light rays are reflected by the two second reflection interfaces to form third reflection light rays and fourth reflection light rays which deviate from the photovoltaic cell piece, the third reflection light rays and the fourth reflection light rays can constructively interfere, and the object light rays are ultraviolet light rays and/or infrared light rays.

Optionally, the multilayer transparent film layer includes a first transparent film layer and a second transparent film layer which are stacked on each other, the first transparent film layer is located on one side, away from the photovoltaic cell, of the second transparent film layer, the first transparent film layer and the second transparent film layer form a plurality of reflecting film groups, and the reflecting film groups are stacked on each other;

wherein the refractive index of the first transparent film layer is greater than the refractive index of the second transparent film layer to form the first reflective interface at both end faces of at least part of the first transparent film layer; or the like, or, alternatively,

the refractive index of the second transparent film layer is greater than the refractive index of the first transparent film layer to form the first reflective interface at least a portion of both end faces of the second transparent film layer.

Optionally, the plurality of reflective film groups include a first reflective film group and a second reflective film group, and refractive indexes and/or thicknesses of the first transparent film layers and refractive indexes and/or thicknesses of the second transparent film layers corresponding to the first reflective film group and the second reflective film group are different from each other, so that wavelengths of the second object light reflected by the second reflective film group and the first object light reflected by the first reflective film group are different from each other.

Optionally, the total thickness of the transparent film layers of the plurality of first reflecting film groups is D₁The total thickness of the transparent film layers of the second reflecting film groups is D₂Wherein D is₁：D₂＝(51～49)： (49～51)。

Optionally, the thickness of the first transparent film layer in the first reflective film group is d₁And d is₁D is less than or equal to 40nm₁≤70nm；

The thickness of the second transparent film layer in the first reflecting film group is d₂And d is₂D is less than or equal to 40nm₂≤70nm。

Optionally, the thickness of the first transparent film layer in the second reflective film group is d₃And d is₃D is not less than 140nm₃≤420nm；

The thickness of the second transparent film layer in the second reflecting film group is d₄And d is₄D is not less than 140nm₄≤420nm。

Optionally, one of the first transparent film layer and the second transparent film layer is made of polymethyl methacrylate, and the other is made of at least one of polyethylene naphthalate, polyethylene terephthalate, polycarbonate, and polystyrene.

Optionally, an adhesive layer is arranged between the photovoltaic cell and the first combined film structure.

Optionally, the total number of the transparent film layers is Q, and Q is equal to or greater than 250 and equal to or less than 1100.

The utility model provides a first combination membranous layer structure includes the transparent rete of multilayer, and the refracting index difference of adjacent two-layer transparent rete forms the interface in order to meet department at adjacent two-layer transparent rete, and the transparent rete of multilayer forms a plurality of interfaces. At least two first reflection interfaces exist in the interfaces and two surfaces of the first combined film structure, and ultraviolet rays are subjected to constructive interference between first reflection rays and second reflection rays formed by the two first reflection interfaces, so that the reflection of the ultraviolet rays is selectively improved. By increasing the number of the first reflecting interfaces, the reflection of ultraviolet rays can be continuously improved, so that the first combined film structure has good ultraviolet resistance. The first combined film structure is designed based on the physical optical interference principle, has good spectral selectivity, can selectively reflect ultraviolet rays with high reflectivity, and has small influence on the transmissivity of visible light. And, the material of the multilayer transparent film layer in the first combined film structure may not be a fluorine-containing material, so as to reduce the cost. In summary, the first composite film structure provided by the present application has good ultraviolet resistance and low cost. Therefore, the novel photovoltaic module using the first combined membrane structure has the advantages of good ultraviolet resistance, low cost, good flexibility and wide application range, and can be applied to automobiles, ships, color steel tile roofs, building curtain walls and the like.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an embodiment of the novel photovoltaic module provided by the present invention;

FIG. 2 is a schematic structural diagram of one embodiment of the composite membrane structure of FIG. 1;

FIG. 3 is a schematic structural view of yet another embodiment of the composite membrane structure of FIG. 1;

fig. 4 is a schematic structural diagram of another embodiment of the novel photovoltaic module provided by the present invention.

The reference numbers illustrate:

the objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if directional indications (such as upper, lower, left, right, front, back, outer and inner … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" appearing throughout includes three juxtapositions, exemplified by "A and/or B" including either A or B or both A and B. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

In the existing photovoltaic module, the solar back plate is mainly made of a composite back plate material containing a fluorine material, but the composite back plate material mainly depends on import and has higher market price, and the technology is monopolized by foreign enterprises. The low-cost solar back panel uses the coated and modified PET polyester film to replace a fluorine-containing material, but the PET material coated and modified by the ultraviolet resistant agent has limited ultraviolet resistance and poor weather resistance, and the manufacturing process is a non-environment-friendly chemical coating process.

In order to solve the above problem, the utility model provides a novel photovoltaic module 100, this novel photovoltaic module 100's backplate adopts the combined film structure, and this combined film structure has characteristics with low costs, that ultraviolet resistance is good, flexibility is good, but the cost of greatly reduced novel photovoltaic module 100 to enlarge novel photovoltaic module 100's range of application.

Fig. 1 is a schematic structural diagram of an embodiment of a novel photovoltaic module 100 provided by the present invention, referring to fig. 1, the novel photovoltaic module 100 includes a photovoltaic cell sheet 2 and a first combined film structure 3, the photovoltaic cell sheet 2 has a front side for facing sunlight and a back side opposite to the front side; the first combined film structure 3 is arranged on the back surface of the photovoltaic cell 2, the first combined film structure 3 comprises a plurality of layers of transparent films, and at least two first reflecting interfaces are formed on the plurality of layers of transparent films; the object light rays are reflected by the two first reflection interfaces to form first reflection light rays and second reflection light rays which deviate from the photovoltaic cell piece 2, the first reflection light rays and the second reflection light rays can constructively interfere, and the object light rays are ultraviolet light rays and/or infrared light rays.

The utility model provides a first combination membranous layer structure 3 includes the transparent rete of multilayer, and the refracting index difference of adjacent two-layer transparent rete forms the interface in order to meet department at adjacent two-layer transparent rete, and the transparent rete of multilayer forms a plurality of interfaces. At least two first reflection interfaces exist in the interfaces and two surfaces of the first combined film structure 3, and ultraviolet rays are subjected to constructive interference between first reflection rays and second reflection rays formed by the two first reflection interfaces, so that the reflection of the ultraviolet rays is selectively improved. By increasing the number of the first reflective interfaces, the reflection of ultraviolet rays can be continuously improved, so that the first combined film structure 3 has good ultraviolet resistance. The first combined film structure is designed based on the physical optical interference principle, has good spectral selectivity, can selectively reflect ultraviolet rays with high reflectivity, and has small influence on the transmissivity of visible light. And, the material of the multiple transparent film layers in the first combined film structure 3 may not be a fluorine-containing material, so as to reduce the cost. In summary, the first combined film structure 3 provided by the present application has good ultraviolet resistance and low cost. Therefore, the novel photovoltaic module 100 using the first combined membrane structure 3 has good ultraviolet resistance, low cost, good flexibility and wide application range, and can be applied to automobiles, ships, color steel tile roofs, building curtain walls and the like.

Further, be equipped with adhesive linkage 4 between photovoltaic cell piece 2 and the first combination membrane structure 3, adhesive linkage 4's material is the adhesive that photovoltaic cell field was commonly used, including EVA, POE, PVB etc..

Novel photovoltaic module 100 still includes apron 1, and the front of photovoltaic cell piece 2 is located to the apron, is equipped with adhesive linkage 4 between photovoltaic cell piece 2 and the apron 1, and adhesive linkage 4's material is the adhesive that photovoltaic cell field is commonly used, including EVA, POE, PVB etc..

For forming a first reflection interface, the multilayer transparent film layer includes a first transparent film layer 311, a second transparent film layer 312 and an adjusting film layer which are stacked mutually, the first transparent film layer 311 is positioned on one side of the second transparent film layer 312 far away from the photovoltaic cell piece 2, the adjusting film layer is positioned on one side of the first transparent film layer 311 far away from the photovoltaic cell, the refractive index of the first transparent film layer 311 is greater than that of the second transparent film layer 312, the refractive index of the adjusting film layer is smaller than that of the first transparent film layer 311, and two end faces of the first transparent film layer 311 form two first reflection interfaces.

According to the principle of physical and optical interference, the conditions for constructive interference of the first reflected light and the second reflected light formed by the object light passing through the two end faces of the first transparent film layer 311 are as follows:

the refractive index of the first transparent film layer 311 is n₁The thickness of the first transparent film layer 311 is d₁Wavelength λ of object light, where n₁×d₁＝m₁λ/4, wherein m₁Is odd; and

the refractive index of the adjusting film layer is smaller than that of the first transparent film layer 311, and the refractive index of the first transparent film layer 311 is larger than that of the second transparent film layer 312.

When the above conditions are satisfied, after the object light is emitted from the adjustment film to the first transparent film 311, the optical path difference between the first reflected light and the second reflected light formed by the two end surfaces of the first transparent film 311 is the same, and thus the first reflected light and the second reflected light formed by the two end surfaces of the first transparent film 311 constructively interfere with each other.

The first combined film structure 3 includes at least one combination of the above, that is, the refractive indexes of the three transparent film layers stacked in sequence are distributed in a low-high-low manner, so that the object light can be selectively reflected highly. As the number of the above combinations increases, the reflection of the subject light by the first combined film structure 3 increases.

When the refractive index of the first transparent film layer 311 is n₁The thickness of the first transparent film layer 311 is d₁Wavelength λ of object light, where n₁×d₁＝m₁λ/4, the reflection effect on the object light of wavelength λ is best.

It should be further noted that, for the first combined film structure 3 having only two transparent film layers, since the refractive index of light in air is the minimum, when the refractive index of the first transparent film layer 311 is greater than that of the second transparent film layer 312, two end surfaces of the first transparent film layer 311 form two first reflection interfaces, and the first reflected light and the second reflected light reflected by the two end surfaces of the first transparent film layer 311 of the object light constructively interfere with each other.

To obtain better ultraviolet resistance and improve processability. Preferably, the reflecting film group having two transparent film layers, three transparent film layers, or a plurality of transparent film layers is formed using two, three, or more polymer materials having different refractive indexes, and the plurality of reflecting film groups are stacked one on another to form a combined film structure. The reflectivity of the object light is controlled by regulating the number of the reflecting film groups.

In the embodiment of the utility model, see fig. 2, the transparent rete of multilayer includes first transparent rete 311 and the transparent rete 312 of second that establish each other, and first transparent rete 311 is in the one side that photovoltaic cell piece 2 was kept away from to the transparent rete 312 of second, and the refracting index of first transparent rete 311 and the transparent rete 312 of second is different, and first transparent rete 311 and the transparent rete 312 of second form the reflectance coating group, and the reflectance coating group sets up a plurality ofly, and establishes each other overlapping.

The refractive index of the first transparent film layer 311 is n₁The thickness of the first transparent film layer 311 is d₁The wavelength of the object light is lambda, where n₁×d₁＝m₁λ/4，m₁Is odd; the refractive index of the second transparent film layer 312 is n₂A second transparent film layer 312Has a thickness of d₂Wavelength λ of object light, where n₂×d₂＝m₂λ/4，m₂Under the condition of odd number, when the refractive index of the first transparent film layer 311 is greater than that of the second transparent film layer 312, the refractive index distribution of the multiple transparent film layers is "photovoltaic cell sheet 2/low, high, low, high and low … …, high, low and high", then there are multiple sets of refractive index combinations of "low, high and low", so that the first combined film structure 3 can selectively reflect object light highly, and two end faces of the first transparent film layer 311 form a first reflective interface, that is, in the first combined film structure 3, when the refractive index of the first transparent film layer 311 is greater than that of the second transparent film layer 312, a first reflective interface is formed at two end faces of at least part of the first transparent film layer 311; when the refractive index of the second transparent film layer 312 is greater than the refractive index of the first transparent film layer 311, the refractive index distribution of the multiple transparent film layers is "photovoltaic cell 2/high, low, high, and low … …, high and low", and there are multiple sets of refractive index combinations of "low, high, and low", so that the first combined film structure 3 can selectively reflect object light highly, and two end faces of the second transparent film layer 312 form a first reflection interface, that is, in the first combined film structure 3, when the refractive index of the second transparent film layer 312 is greater than the refractive index of the first transparent film layer 311, a first reflection interface is formed at two end faces of at least part of the second transparent film layer 312.

In another embodiment of the present invention, referring to fig. 3, the multi-layer transparent film layer includes a first transparent film layer 311, a second transparent film layer 312 and a third transparent film layer 313 stacked on each other, and the refractive indexes of the first transparent film layer 311, the second transparent film layer 312 and the third transparent film layer 313 are different from each other, the first transparent film layer 311, the second transparent film layer 312 and the third transparent film layer 313 form a reflective film group, and the reflective film group is provided in a plurality of numbers and stacked on each other. When three transparent film layers are included in the reflective film group, regardless of the refractive index distribution of the three transparent film layers, for example, "high, medium, low, medium, and low … …" or "high, medium, low, medium, … …" is at least combined with "low, medium, high, medium, and low" so as to form first reflective interfaces at both end faces of the transparent film layers having a high refractive index. Of course, the three layers are transparentOf the film layers, the refractive index n of each transparent film layer_aThickness d of each transparent film layer_aAnd the wavelength lambda of the object light satisfies n_a×d_a＝m_aλ/4，m_aIs an odd number, and a is 1, 2 or 3.

From this analogize, when a plurality of transparent rete form the reflection membrane group, the reflection membrane group is provided with a plurality ofly and overlaps mutually and establish and form first combination membrane structure 3, as long as satisfy the refractive index difference of two adjacent transparent rete in the multilayer transparent rete, the refractive index n of each transparent rete_aThickness d of each transparent film layer_aAnd the wavelength lambda of the object light satisfies n_a×d_a＝m_aλ/4，m_aAnd when the number is odd and a is a natural number, the first combined film structure 3 selectively reflects object light with a high wavelength lambda. Preferably, the refractive indices of the plurality of transparent film layers forming the reflective film group are different from each other. Preferably, the refractive index n of each transparent film layer_aThickness d of each transparent film layer_aAnd the wavelength lambda of the object light satisfies n_a×d_aAnd a is a natural number.

The material (such as EVA) of the bonding layer 4 in the photovoltaic module is a high polymer material, and the bonding layer is subjected to illumination and temperature and humidity change for a long time when being used outdoors, and undergoes chemical reaction under the action of factors such as ultraviolet, temperature and humidity, so that the optical loss of the photovoltaic cell 2 can be caused, and the attenuation of the performance of the photovoltaic module is also influenced to a certain extent; in addition, the adhesive layer 4 is yellowed, which affects the adhesion effect and light transmittance. Light in the infrared wavelength region is a main factor for generating heat, and the temperature rise of the photovoltaic module absorbing infrared rays also causes chemical reaction of the adhesive layer 4, so that the performance of the photovoltaic module is attenuated, and the spectral response efficiency of the photovoltaic cell 2 is reduced.

In order to solve the above problem, in the embodiment of the present invention, the plurality of reflective film sets include the first reflective film set 31 and the second reflective film set 32, and the refractive index and/or the thickness of the corresponding first transparent film 311 and the refractive index and/or the thickness of the corresponding second transparent film 312 in the first reflective film set 31 and the second reflective film set 32 are different from each other, so that the wavelength of the second object light reflected by the second reflective film set 32 is different from the wavelength of the first object light reflected by the first reflective film set 31.

Specifically, in the first reflection film group 31, the refractive index of the first transparent film layer 311 is n₁The thickness of the first transparent film layer 311 is d₁Wavelength bit λ of first object light₁Satisfy n₁×d₁＝m₁λ₁/4，m₁Is odd; the refractive index of the second transparent film layer 312 is n₂The thickness of the second transparent film layer 312 is d₂The wavelength of the first object light is lambda₁Satisfy n₂×d₂＝m₂λ₁/4，m₂Is an odd number. In the second reflective film group 32, the refractive index of the first transparent film layer 311 is n₃The thickness of the first transparent film layer 311 is d₃Wavelength λ of the second object light₂Satisfy n₃×d₃＝m₃λ₂/4，m₃Is odd; the refractive index of the second transparent film layer 312 is n₄The thickness of the second transparent film layer 312 is d₄Wavelength λ of the second object light₂And satisfies the following conditions: n is₄×d₄＝m₄λ₂/4，m₄Is an odd number.

The plurality of reflecting film groups are divided into a first reflecting film group 31 and a second reflecting film group 32, which can selectively reflect the first object light and the second object light. When one of first object light and second object light is ultraviolet light, when another is infrared light, the first combination membrane structure 3 of this application can selective reflection ultraviolet light and infrared light simultaneously, reduces the ultraviolet light and the loss of infrared light to novel photovoltaic module 100, reduces novel photovoltaic module 100's temperature to promote novel photovoltaic module 100's generating efficiency, and prolong novel photovoltaic module 100's life. When the first object light and the second object light are ultraviolet rays with different wavelengths, the first combined film structure 3 can simultaneously reflect the ultraviolet rays with two wavelengths selectively and highly, and the ultraviolet resistance of the novel photovoltaic module 100 is improved.

It should be noted that the plurality of reflecting film groups may, but are not limited to, include the first reflecting film group 31 and the second reflecting film group 32. In another embodiment of the present invention, the plurality of reflective film sets include a first reflective film set 31, a second reflective film set 32 and a third reflective film set, wherein the refractive index and/or thickness of the corresponding first transparent film 311 and the refractive index and/or thickness of the corresponding second transparent film 312 in the first reflective film set 31, the second reflective film set 32 and the third reflective film set are different from each other, so that the wavelengths of the third object light reflected by the third reflective film set, the second object light reflected by the second reflective film set 32 and the first object light reflected by the first reflective film set 31 are different from each other. The utility model discloses an in other embodiments, a plurality of reflectance coating groups include first reflectance coating group 31, second reflectance coating group 32, third reflectance coating group, … … Nth reflectance coating group to make a plurality of object light of first combination membrane structure 3 selective reflection, obtain better ultraviolet resistance performance and anti infrared ray performance.

It should be noted that the refractive index n of the first transparent film layer 311 of the first reflective film group 31₁And the refractive index n of the first transparent film layer 311 of the second reflective film group 32₃May be the same or different; refractive index n of the second transparent film layer 312 of the first reflective film group 31₂And the refractive index n of the second transparent film layer 312 of the second reflective film group 32₄Can be the same or different, the utility model discloses do not do the restriction. In the embodiment of the present invention, two polymer materials with different refractive indexes are used, and the selective reflection of the first object light and the second object light is realized by adjusting the thickness of the film layer, so the refractive index n of the first transparent film layer 311 of the first reflective film group 31₁And the refractive index n of the first transparent film layer 311 of the second reflective film group 32₃Similarly, the thickness d of the first transparent film layer 311 of the first reflective film set 31₁And the thickness d of the first transparent film layer 311 of the second reflective film group 32₃Different; refractive index n of the second transparent film layer 312 of the first reflective film group 31₂And the refractive index n of the second transparent film layer 312 of the second reflective film group 32₄Similarly, the thickness d of the second transparent film layer 312 of the first reflective film group 31₂And a thickness d of the second transparent film layer 312 of the second reflective film group 32₄Different. The membrane system is designed, convenient to regulate and control and high in processing efficiency.

In addition, the present invention is not limited to the number of the first reflective film set 31 and the second reflective film set 32. The number of the first reflecting film group 31 and the second reflecting film group 32 may be the same or different. When the first combined film structure 3 is prepared by adopting a polymer multilayer co-extrusion process, the number of the first reflecting film groups 31 is generally the same as that of the second reflecting film groups 32; or, the number of the first reflection film groups 31 is an integral multiple of the number of the second reflection film groups 32; or, the number of the second reflection film groups 32 is an integral multiple of the number of the first reflection film groups 31.

It should be noted that, the present invention is not limited to the arrangement of the plurality of first reflective film sets 31 and the plurality of second reflective film sets 32. The first reflective film group 31 and the second reflective film group 32 may be alternately stacked; alternatively, the first reflective film groups 31 partially stacked on each other and the second reflective film groups 32 partially stacked on each other may be alternately stacked. Preferably, in the embodiment of the present invention, the plurality of first reflective film sets 31 stacked on each other are disposed on one side of the plurality of second reflective film sets 32 stacked on each other, so as to facilitate the multi-layer co-extrusion processing.

It should be noted that, in the reflectance spectrum of the first combined film structure 3 with respect to the solar spectrum, the wavelength λ of the object light is₁Where a reflectance peak is shown. To widen lambda₁Width of the reflectivity peak, i.e. at wavelength λ₁To obtain a wide reflection bandwidth, typically at λ₁Near λ₂Obtaining a reflectivity peak and making lambda₁Reflectance peak and lambda of₁The reflectivity peaks of (a) overlap to obtain a wider reflection bandwidth. According to the theory of physical-optical interference, when the wavelength is lambda₁And wavelength lambda₂Satisfies the following conditions: 0.97 lambda₁≤λ₂≤1.03λ₁Time, wavelength lambda₁And wavelength lambda₂The reflectivity peaks of (a) may be partially coincident to obtain a wider reflectivity peak. Therefore, when the material of the multi-layer transparent film of the first reflective film group is the same as the material of the multi-layer transparent film of the second reflective film group, the total thickness D of the multi-layer transparent film of the first reflective film group 31 is the same as the total thickness D of the multi-layer transparent film of the second reflective film group₁And the total thickness D of the plurality of transparent film layers in the second reflecting film group 32₂The ratio of the components satisfies: d₁：D₂(51-49): (49-51) to obtain the first combined film structure 3 with wider reflection bandwidth.

To the material of transparent rete, the utility model discloses do not do the restriction, as long as its refracting index satisfies above-mentioned requirement can. However, in consideration of processing and cost, the material of the transparent film layer preferably includes at least one of polymethyl methacrylate, polyethylene naphthalate, polyethylene terephthalate, polycarbonate, and polystyrene. The polymer materials have low cost, any two polymer materials are directly and partially mutually soluble, the polymer composite material is suitable for being prepared by adopting a polymer multi-layer co-extrusion process, and the multi-layer transparent film layers are not layered after extrusion molding, so that the structure is stable. The polymer multilayer co-extrusion process is high in production efficiency and low in production cost, the cost of the novel photovoltaic module 100 can be reduced, and the pollution to the environment is less.

In the present embodiment, according to the principle of physical optical interference, the larger the difference between the refractive indexes of the first transparent film layer 311 and the second transparent film layer 312 is, the higher the reflectivity of the first combined film structure 3 to the object light is. Among the polymers, polymethyl methacrylate (PMMA) has a small refractive index of about 1.49, Polycarbonate (PC) has a refractive index of about 1.584 to 1.586, Polystyrene (PS) has a refractive index of about 1.59 to 1.602, polyethylene naphthalate (PEN) has a refractive index of about 1.757 to 1.759, and polyethylene terephthalate (PET) has a refractive index of about 1.661 to 1.665, and thus one of the first transparent film layer 311 and the second transparent film layer 312 is polymethyl methacrylate, and the other is at least one of polyethylene naphthalate, polyethylene terephthalate, polycarbonate, and polystyrene.

Considering that the wavelength of ultraviolet rays mainly affecting the photovoltaic module is in the range of 300nm to 400nm and the wavelength of infrared rays is in the range of 1000nm to 2500nm, that is, the wavelength λ of the object light satisfies: lambda is more than or equal to 300nm and less than or equal to 400 nm; and/or the wavelength λ of the object light satisfies: lambda is more than or equal to 1000nm and less than or equal to 2500 nm.

Correspondingly, when the first reflection film group 31 is used for selectively highly reflecting the ultraviolet rays, the first reflection film groupThe thickness of the first transparent film layer 311 in the group 31 is d₁And d is₁D is less than or equal to 40nm₁Less than or equal to 70nm, the thickness of the second transparent film layer 312 in the first reflection film group 31 is d₂And d is₂D is less than or equal to 40nm₂Less than or equal to 70 nm; alternatively, the first and second electrodes may be,

when the first reflective film set 31 is used for selectively reflecting infrared rays highly, the thickness of the first transparent film 311 in the first reflective film set 31 is d₁And d is₁D is not less than 140nm₁Is less than or equal to 420nm, the thickness of the second transparent film layer 312 in the first reflecting film group 31 is d₂And d is₂D is not less than 140nm₂≤420nm。

When the second reflective module 32 is used for selectively reflecting infrared light, the thickness of the first transparent film 311 in the second reflective film 32 is d₃And d is₃D is not less than 140nm₃Is less than or equal to 420nm, the thickness of the second transparent film layer 312 in the second reflecting film group 32 is d₄And d is₄D is not less than 140nm₄Less than or equal to 420 nm; alternatively, the first and second electrodes may be,

when the second reflective film group 32 is used for selectively reflecting ultraviolet light with high reflectivity, the thickness of the first transparent film layer 311 in the second reflective film group 32 is d3, and d3 satisfies that d3 is greater than or equal to 40nm and is less than or equal to 70nm, the thickness of the second transparent film layer 312 in the second reflective film group 32 is d4, and d4 satisfies that d4 is greater than or equal to 40nm and is less than or equal to 70 nm.

To the total number of piles Q of the transparent rete of multilayer in the first combination membranous structure 3, the utility model discloses do not do the restriction. Preferably, the total number Q of the transparent film layers satisfies: q is more than or equal to 250 and less than or equal to 1100. The total layer number Q is too small, and the reflectivity cannot meet the requirement; but the total number of layers Q is too large, the reflectance of the object light decreases in the combined film structure due to the increase in absorption and scattering losses.

For the total thickness D of the multilayer transparent film layer in the first combined film structure 3₀The utility model discloses do not do the restriction. Preferably, the total thickness D of the multilayer transparent film layer₀Satisfies the following conditions: d₀Not less than 10 μm. Total thickness D₀Too small, the reflectance to the subject light is low, and the first combined film structure 3 is inferior in strength and is easily broken.

In this embodiment, the material and thickness of the first transparent film layer 311 and the second transparent film layer 312, and the number of the first reflective film group 31 and the second reflective film group 32 can be adjusted to selectively reflect the first object light and the second object light, and to control the total number and total thickness of the multiple transparent film layers in the first combined film structure 3.

The technical solution of the present invention will be described in detail with reference to the following embodiments, which should be understood as the following embodiments are only for explaining the present invention and are not intended to limit the present invention.

Example one

Taking the example of designing the first combined film structure with excellent ultraviolet resistance by using PMMA and PC materials, in order to obtain a wider emission bandwidth at a wavelength of 365nm, the first reflecting film group 31 is designed for selectively reflecting a high wavelength lambda₁A second reflecting film group 32 for selectively reflecting ultraviolet rays having a wavelength of 365nm at a high reflection wavelength₂Is ultraviolet ray of 354 nm. In the first reflection film group 31, the thickness of the PMMA layer was 61.2nm and the thickness of the PC layer was 57.6nm, as obtained from n × d ═ λ/4; in the second reflective film group 32, the thickness of the PMMA layer was 59.4nm, and the thickness of the PC layer was 55.8 nm.

In actual operation, the set temperature ranges of the extruder were set at 280 ℃, 275 ℃, 270 ℃, 265 ℃ and 260 ℃, the temperatures of the multiplier and the extrusion die were set at 260 ℃ and 220 ℃, respectively, and the set temperature of the casting cooling roll was set at 120 ℃. First, a quadruple equal-component multiplier is used for stacking to obtain 128 groups of reflecting film groups with equal thickness, and then a double unequal-component multiplier is used for obtaining 128 groups of first reflecting film groups 31 and 128 groups of second reflecting film groups 32, wherein the ratio of the total thickness of the 128 groups of first reflecting film groups 31 to the total thickness of the 128 groups of second reflecting film groups 32 is 50.8: 49.2.

in the obtained first reflecting film group 31, the thickness of the PMMA layer was 61.2nm, and the thickness of the PC layer was 57.6 nm; in the second reflective film group 32, the thickness of the PMMA layer was 59.4nm, and the thickness of the PC layer was 55.8 nm. Thus, the total thickness D of the transparent film layers of the first reflective film groups 31 can be obtained₁15.2 μm, the total thickness D of the transparent film layers of the plurality of second reflection film groups 32₂It was 14.7 μm. The total thickness of the multilayer transparent film layer of the first combined film structure 3 was 29.9 μm. In bookThe first combination film structure 3 of the embodiment shows a broad reflectance peak at a wavelength of 354nm to 365nm in the reflectance spectrum of the solar spectrum.

Example two

Taking the example of designing the first combination film structure with excellent ultraviolet resistance by using PMMA and PC materials, the first reflection film set 31 is designed for selectively reflecting the wavelength λ with high reflection₁A second reflecting film group 32 for selectively reflecting ultraviolet rays having a wavelength of 365nm at a high reflection wavelength₂Is 1100nm ultraviolet ray. In the first reflection film group 31, the thickness of the PMMA layer was 61.2nm and the thickness of the PC layer was 57.6nm, as obtained from n × d ═ λ/4; in the second reflective film group 32, the thickness of the PMMA layer was 184.6nm, and the thickness of the PC layer was 173.5 nm.

In actual operation, the set temperature ranges of the extruder were set at 280 ℃, 275 ℃, 270 ℃, 265 ℃ and 260 ℃, the temperatures of the multiplier and the extrusion die were set at 260 ℃ and 220 ℃, respectively, and the set temperature of the casting cooling roll was set at 120 ℃. First, 128 sets of reflecting film groups with the same thickness are obtained by using a quadruple equal component multiplier in a stacking mode, and then 128 sets of first reflecting film groups 31 and 128 sets of second reflecting film groups 32 are obtained by using a double unequal component multiplier in a stacking mode.

In the obtained first reflecting film group 31, the thickness of the PMMA layer was 61.2nm, and the thickness of the PC layer was 57.6 nm; in the second reflective film group 32, the thickness of the PMMA layer was 184.6nm, and the thickness of the PC layer was 173.5 nm. Thus, the total thickness D of the transparent film layers of the first reflective film groups 31 can be obtained₁15.2 μm, the total thickness D of the transparent film layers of the plurality of second reflection film groups 32₂And 45.8 μm. The total thickness of the multilayer transparent film layer of the first combined film structure 3 was 61 μm. In the reflectance spectrum of the first combined film structure 3 of the present embodiment to the solar spectrum, reflectance peaks are shown at the wavelength of 365nm and the wavelength of 1100 nm.

In addition, in the existing photovoltaic module, the material of the cover plate 1 is commonly glass, fluorine material (such as ETFE, PVD) and PET polyester film modified by coating with an anti-ultraviolet agent. However, the glass has a large weight, which limits the application range of the photovoltaic module; the fluorine material is expensive and cannot be popularized and applied; the PET polyester film modified by coating has limited ultraviolet resistance, and the manufacturing process is a non-environment-friendly chemical coating process.

In view of this, in another embodiment of the present invention, referring to fig. 4, the novel photovoltaic module 100 further includes a second combined film structure 5, the second combined film structure 5 is disposed on the front surface of the photovoltaic cell 2, and at least two second reflective interfaces are formed on the second combined film structure 5; and the object light rays are reflected by the two second reflection interfaces to form third reflection light rays and fourth reflection light rays which deviate from the photovoltaic cell piece 2, and the third reflection light rays and the fourth reflection light rays can constructively interfere with each other, wherein the object light rays are ultraviolet light rays and/or infrared light rays.

The utility model provides a second combined film structure 5 includes the transparent rete of multilayer, and the refracting index difference of adjacent two-layer transparent rete forms the interface in order to meet department at adjacent two-layer transparent rete, and the transparent rete of multilayer forms a plurality of interfaces. At least two second reflection interfaces exist in the interfaces and two surfaces of the second combined film structure 5, and ultraviolet rays constructively interfere with fourth reflection rays through third reflection rays and fourth reflection rays formed by the two second reflection interfaces, so that reflection of the ultraviolet rays is selectively improved. By increasing the number of second reflective interfaces, the reflection of ultraviolet rays can be continuously improved, so that the second combined film structure 5 has good ultraviolet resistance. The second combined film structure 5 is designed based on the physical optical interference principle, has good spectral selectivity, can selectively reflect ultraviolet rays with high reflectivity, and has small influence on the transmissivity of visible light. And, the total thickness of the second combined film structure 5 is small and light. In addition, the material of the multiple transparent film layers in the second combined film structure 5 may not be a fluorine-containing material, so as to reduce the cost. In summary, the second composite film structure 5 provided by the present application has good ultraviolet resistance and low cost. Therefore, the novel photovoltaic module 100 using the second combined membrane structure 5 has good ultraviolet resistance, low cost, good flexibility and wide application range, and can be applied to automobiles, ships, color steel tile roofs, building curtain walls and the like.

The utility model discloses second combination membrane structure 5 of embodiment includes first combination membrane structure 3 the above-mentioned all technical scheme of embodiment consequently have all beneficial effects that the technical scheme of above-mentioned embodiment brought at least, no longer give unnecessary details here.

Further, be equipped with adhesive linkage 4 between photovoltaic cell piece 2 and the second combined film structure 5, adhesive linkage 4's material is the adhesive that photovoltaic cell field was commonly used, including EVA, POE, PVB etc..

In addition, the photovoltaic cell 2 of the present invention includes but is not limited to a crystalline silicon cell, a copper indium gallium selenide cell, a cadmium telluride cell, and an amorphous silicon cell. When the second combined film structure 5 is used for replacing the existing cover plate 1, the use requirement of the novel photovoltaic assembly 100 with double-sided power generation can be met, the power generation efficiency of the novel photovoltaic assembly 100 is improved, the weight of the novel photovoltaic assembly 100 is reduced, and the cost is reduced.

The above only be the preferred embodiment of the utility model discloses a not consequently restriction the utility model discloses a patent range, all are in the utility model discloses a conceive, utilize the equivalent structure transform of what the content was done in the description and the attached drawing, or direct/indirect application all is included in other relevant technical field the utility model discloses a patent protection within range.

Claims (9)

1. A novel photovoltaic module, comprising:

a photovoltaic cell sheet having a front surface for facing sunlight and a back surface opposite to the front surface; and the number of the first and second groups,

the first combined film structure is arranged on the back surface of the photovoltaic cell piece and comprises a plurality of layers of transparent films, and at least two first reflecting interfaces are formed on the plurality of layers of transparent films;

object light rays are reflected from the two first reflection interfaces to form first reflection light rays and second reflection light rays which are deviated from the photovoltaic cell piece, the first reflection light rays and the second reflection light rays can be subjected to constructive interference, and the object light rays are ultraviolet light rays and/or infrared light rays.

2. The novel photovoltaic module according to claim 1, further comprising a second combined film structure disposed on the front surface of the photovoltaic cell sheet, wherein the second combined film structure has at least two second reflective interfaces formed thereon;

and object light rays are reflected by the two second reflection interfaces to form third reflection light rays and fourth reflection light rays which deviate from the photovoltaic cell piece, the third reflection light rays and the fourth reflection light rays can constructively interfere, and the object light rays are ultraviolet light rays and/or infrared light rays.

3. The novel photovoltaic module according to claim 1, wherein the plurality of transparent film layers include a first transparent film layer and a second transparent film layer stacked on each other, the first transparent film layer is located on a side of the second transparent film layer away from the photovoltaic cell, the first transparent film layer and the second transparent film layer form a plurality of reflecting film groups, and the reflecting film groups are stacked on each other;

wherein the refractive index of the first transparent film layer is greater than the refractive index of the second transparent film layer to form the first reflective interface at both end faces of at least part of the first transparent film layer; or the like, or, alternatively,

the refractive index of the second transparent film layer is greater than the refractive index of the first transparent film layer to form the first reflective interface at least a portion of both end faces of the second transparent film layer.

4. The novel photovoltaic module according to claim 3, wherein the plurality of the reflective film groups include a first reflective film group and a second reflective film group, and refractive indexes and/or thicknesses of the corresponding first transparent film layer and the corresponding second transparent film layer in the first reflective film group and the second reflective film group are different from each other, so that the second object light reflected by the second reflective film group and the first object light reflected by the first reflective film group have different wavelengths.

5. The novel photovoltaic module according to claim 4, characterized in that a plurality of said first reflecting film groupsThe total thickness of the transparent film layer is D₁The total thickness of the transparent film layers of the second reflecting film groups is D₂Wherein D is₁：D₂＝(51～49)：(49～51)。

6. The novel photovoltaic module according to claim 4, wherein the thickness of the first transparent film layer in the first reflecting film group is d₁And d is₁D is less than or equal to 40nm₁≤70nm；

The thickness of the second transparent film layer in the first reflecting film group is d₂And d is₂D is less than or equal to 40nm₂≤70nm。

7. The novel photovoltaic module according to claim 4, wherein the thickness of the first transparent film layer in the second reflecting film group is d₃And d is₃D is not less than 140nm₃≤420nm；

The thickness of the second transparent film layer in the second reflecting film group is d₄And d is₄D is not less than 140nm₄≤420nm。

8. The novel photovoltaic module of claim 1 wherein an adhesive layer is disposed between said photovoltaic cell sheet and said first composite film structure.

9. The novel photovoltaic module as claimed in claim 1, wherein the total number of the transparent film layers is Q, and Q is 250. ltoreq. Q.ltoreq.1100.

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