RU2733154C1 - Photoelectric thermal module with composite metal-polymer structure of heat absorber - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to solar engineering and is intended for power supply of agricultural and household purposes. Photoelectric thermal module with composite metal-polymer structure comprises translucent protective insulating coating, heat absorber filled with liquid heat carrier, consisting of a polymer housing and a metal receiving panel, hermetically connected to it, according to the invention on the front side of the receiving panel there are photoconverters, wherein heat absorber flow section is made by one solid channel while case is made from non-foamed polymer. Technical result of proposed invention is expansion of functionality due to generation of both heat and electric energy, as well as use of non-foam polymer housing instead of heat insulation from foamed polymers increases service life and increases reliability of collector.

EFFECT: collapsible design makes it possible to conduct full-scale maintenance of the installation, increases repairability of the structure, which also increases service life of the structure.

4 cl, 6 dwg

Description

The invention relates to the field of solar technology and is intended for power supply of agricultural and household facilities.

Known solar collector, which is an absorber with tubes for the flow of the coolant, on the front surface of which photoelectric converters are located (RF patent No. 2485417 IPC F24J2 / 24, publ. 2013).

The disadvantage of the known device is the uneven area of cooling of photoelectric converters and, as a consequence, a decrease in the efficiency of photoconversion. In addition, in the manufacture of such absorbers, it is necessary to use copper or its alloys for efficient cooling of photovoltaic converters, which increases the cost of the solar plant.

The closest in technical essence to the proposed invention (prototype) is a liquid solar collector, the heat exchanger of which consists of a radiation-absorbing panel and a part in the form of thermal insulation with recesses (RF patent No. 2134846 IPC F24J2 / 04, publ. 1999). At the same time, a part of the heat exchanger made of thermal insulation is made of waterproof polymers. The collector is equipped with a translucent insulation located with a gap in relation to the panel.

The disadvantage of the known collector is the fact that such a collector does not use photoelectric converters, which allow the installation to additionally generate electrical energy. The design of the prototype also uses waterproof insulation made of foamed polymers; however, in practice, such materials, as a rule, have a certain degree of water absorption, which is especially undesirable for devices that require freezing in case of conservation in the cold season. The solar collector does not have a collapsible heat exchanger design, which reduces the maintainability of the structure.

The objective of the present invention is the ability to generate both thermal and electrical energy in combination with a high efficiency of removal of thermal energy from photovoltaic converters, in increasing the reliability and maintainability of the proposed photovoltaic thermal module.

The technical result of the proposed invention is the expansion of functionality due to the generation of both thermal and electrical energy, as well as an increase in the efficiency of removal of thermal energy from photovoltaic converters due to the fact that heat is removed evenly from the entire area of the photoconverter due to the execution of the flow path of the thermal absorber one continuous channel. The use of a non-foamed polymer casing instead of foam insulation increases the service life and improves the reliability of the manifold. The collapsible design makes it possible to carry out full maintenance of the unit, increases the maintainability of the structure, which also increases its service life.

The above technical result is achieved in that in the proposed photovoltaic thermal module with a composite metal-polymer structure containing a translucent protective insulating coating, a heat absorber filled with a liquid heat carrier, consisting of a polymer housing and a metal receiving panel hermetically connected to it, according to the invention, on the front side of the receiving panel photoconverters are located, while the flow-through part of the heat absorber is made of one continuous channel, and the body is made of non-foamed polymer.

In another embodiment, the sealing of the metal panel and the polymer body is performed by means of a lock or fastener connection using at least one gasket of elastic material with a number of grooves for it.

In another embodiment, the liquid-filled volume of the absorber is shaped by protrusions or ribs on the metal panel on one side and protrusions and recesses in the polymer body on the other side.

In another embodiment, the sealing of the metal panel and the polymer body is performed by means of a lock or fastener connection using at least one gasket of elastic material with a number of grooves for it.

In another embodiment, the liquid-filled volume of the absorber is shaped by protrusions or ribs on the metal panel on one side and protrusions and recesses in the polymer body on the other side.

In another variant, the back and side surfaces of the module are covered with thermal insulation.

The essence of the invention is illustrated by drawings.

FIG. 1 shows a general diagram of a photovoltaic thermal module, FIG. 2 is a cross-section of a photovoltaic thermal module; FIG. 3 shows a junction of a metal panel and a polymer housing of a photovoltaic thermal module; FIG. 4 shows a cross-section of a photovoltaic thermal module with a metal panel made with heat sink fins; FIG. 5 shows a cross-section of a photovoltaic thermal module with a metal panel with heat sink fins and one of the varieties of the shape of the polymer housing, FIG. 6 is a cross-sectional view of a photovoltaic thermal module with thermal insulation.

The proposed photovoltaic thermal module with a composite metal-polymer structure contains a metal receiving panel 1, a polymer body 2, a photoconverter 3, a translucent protective insulating coating 4, pipes 5, a gasket made of elastic material 6, thermal insulation 7 and a frame 8.

The metal receiving panel 1 and the polymer body 2 form a heat absorber of the photovoltaic thermal module, where photoconverters 3 with a translucent protective insulating coating are located on the front side of the metal receiving panel 1. The metal receiving panel 1 on the rear side can be equipped with ribs of various shapes that increase the rigidity of the structure and the surface area of heat transfer to the liquid. To the rear side of the metal receiving panel 1 adjoins a polymer body 2, in which there are nozzles 5 for supplying and removing the coolant. The metal receiving panel 1 is hermetically sealed to the polymer body 2 in various ways, such as adhesive bonding, locking or fastening, etc. The locking connection or the connection using fasteners is performed using at least one gasket of elastic material 6, located in the grooves intended for it. The inner surface of the polymer body 2 can be made of various shapes to create the required configuration of the space filled with liquid in order to optimize its movement in the absorber and intensify heat transfer. To ensure uniform heat removal from photovoltaic converters, the metal panel 1 and the polymer body 2 form one continuous channel for liquid circulation through the heat absorber. The back and side walls of the heat absorber can have thermal insulation 7, placed in the frame 8. The translucent protective insulating coating 4 can be placed with a certain gap parallel to the photo-absorbing surface of the absorber.

The proposed photovoltaic thermal module operates as follows.

Solar radiation, passing through transparent insulation 4, is absorbed in photovoltaic converters 3. In photovoltaic converters 3, part of the solar energy is converted into electrical energy, the remainder is converted into thermal energy. Heat is transferred by the thermal conductivity of the metal receiving panel 1 to the liquid flowing in the absorber. The movement of liquid in the absorber through the nozzles 5 of the polymer body 2 can occur either due to forced circulation, or due to convective movement in solar thermal systems of the thermosiphon type. Translucent protective insulating coating 4 and thermal insulation 7 reduce the heat loss of the module, ensuring high thermal efficiency of the device. Frame 8 connects the main elements of the module into a single rigid structure, protecting it from various mechanical influences.

In the proposed photovoltaic thermal module, there is no need to use photo-absorbing coatings on the thermal absorber of the solar plant; photoelectric converters act as such a coating.

Claims (4)

1. A photovoltaic thermal module with a composite metal-polymer structure, containing a translucent protective insulating coating, a heat absorber filled with a liquid heat carrier, consisting of a polymer housing and a metal receiving panel hermetically connected to it, characterized in that photoconverters are located on the front side of the receiving panel, while flow-through part of the heat absorber is made of one continuous channel, and the body is made of non-foamed polymer. 2. A photovoltaic thermal module with a composite metal-polymer structure according to claim 1, characterized in that the sealing of the metal panel and the polymer body is made by means of a lock or fastening connection using at least one gasket of elastic material with a number of grooves for it. 3. A photovoltaic thermal module with a composite metal-polymer structure according to claim 1, characterized in that the volume of the absorber filled with liquid has a shape formed by protrusions or ribs on a metal panel on one side and protrusions and recesses in the polymer body on the other side. 4. A photovoltaic thermal module with a composite metal-polymer structure according to claim 1, characterized in that the rear and side surfaces of the module are covered with thermal insulation.

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