LT5630B - Planar solar collector - Google Patents

Abstract

The invention relates to energy field and is used for energy coupling from the environment. The purpose of this invention is to adjust the sun collector to work in little light and low temperature conditions. Planar solar collector comprising in oneplane parallely laid pipes system, with a heat pipes inside of it, with circulating heat carrier in it. The collectors' heat taking module (1) is connected with heat collecting module (2) by flowing pipe (7). Inside of the heat pipe is gas flow stopping and speeding guide. The materials in the heat pipe is allowing in one time working in wide temperature diapasons. The heat module (2) is working as united complex and has few heat collecting material capacities: cold capacity (8), cooling capacity (9), refrigeration capacity (10) and hot capacity (11), compensator (13), pump (15), heat carrier capacity (12), few thermo sensors and electrical control part (14). Heat collecting module has few external links (19) and/or inner links (20) for connecting outer h

Description

The invention relates to the field of energy and is intended for the storage of heat from the environment and its further utilization.

Flat-panel solar collectors are most often used to store heat from the environment.

A solar collector usually consists of an absorber, a transparent coating, thermal insulation and a housing. The absorber is one of the more important parts of a solar panel. The most common design for a flat collector is a black absorber plate, under which a copper coil is placed. The heat is removed from the absorber by the heat carrier.

Main absorber structures:

• a single absorber plate underneath with a single coil coil for heat transfer fluid • an absorber plate in the tube itself, patent example DE4007839.

Many absorbers of solid material have been improved by replacing them with thermal tubes. An analog of the invention could be a planar solar collector having a plurality of parallel-connected tubes. Under low sunlight and low temperatures, these collectors are malfunctioning. There are other disadvantages:

• It takes a lot of heat and time to start to have a quantity effect.

• Small amounts of heat and small differences disappear or are difficult to pick up.

• The more the collector accumulates heat and reaches a higher temperature in the tank, the worse its performance.

• Much heat is lost during onward transmission.

• There is no possibility to use other heat accumulated from the environment.

The essence of the invention

The object of the present invention is to adapt a solar panel to work in low light and low temperatures. Be able to absorb even very small amounts of heat.

The solar panel consists of three main modules:

1. A housing with internal thermal insulation of the walls and a transparent glass or plastic cover,

2. Heat extraction module.

3. Heat storage module.

Three modules: housing, heat sink module, heat sink module allow to create autonomous and mobile system. The heat collection and heat storage modules are compactly mounted in the collector itself and connected to each other by a flowing pipe. The heat sink module consists of heat pipes arranged in parallel in the plane of the complex and placed [double glass tubes. The glass tubes are covered with a reflective coating of light and heat. The mixture of materials in the heat pipes transfers heat to the flowing pipe, which connects all the heat pipes into a single system. The heat carrier circulating through the flowing pipe collects the heat and transfers it to the heat storage module. The coolant returns to the new cycle.

The coolant circulates in a closed loop only inside the collector. This makes it possible to significantly speed up the processes and reduce the amount of heat lost. Shorter distances (not meters or dozens of meters instead of millimeters) make it possible to create a very compact autonomous, mobile and easily transferable heat recovery system. Even very small amounts of heat can be recovered. In order to increase the surface area to be absorbed, the heat pipes are collected in several bundles and arranged in parallel, although they are interconnected by a continuous flow pipe. The heat pipe contains a mixture of different materials (ammonia, butane, isobutane, ethyl alcohol, water) that can work successfully in a narrow, wide, lower and higher temperature range, and the optimum composition of the mixture is selected for the most suitable operating temperature regime. The heat tube contains a capillary porous material which collects the working mixture. In the heat pipe, a flow guide is arranged on the asymmetrically arranged flow pipe for speeding up and accelerating the flow of gas.

The heat storage module is made up of a series of heat reservoirs of different temperature materials, compressor, pump - pump, heat carrier capacity, thermocouples and electrical control part. All these parts form an integral complex. Air is drawn between the walls of the double heat tanks. The leaking pipe connecting the system with the circulating heat carrier passes through the warm, cooled and refrigerated parts. The accumulated heat is gradually released to an increasingly lower temperature environment. This way, more heat is taken in one cycle. The compressor, combined with the refrigeration, heat transfer and hot storage, allows the heat from the extra cooling to be transferred to the hot storage. The heat carrier (water) flowing from the environment and passing through the cooling, warm and hot tanks acquires an additional amount of heat: the utilized heat from the environment and the heat from the additional cold portion. Pump - The pump accelerates the outflow of hot coolant.

A series of temperature sensors, which measure the ambient temperature and the internal temperature of different capacities, as well as the electric control unit, with control programs, enable the optimum operation of the collector according to the environmental conditions. The heat storage module has several external and internal connections n

J for connecting external heat sources. In this way, the collector easily and quickly becomes a universal thermal machine. The modular collector can be successfully applied in many areas for heat recovery. Modular design allows you to select from small blocks any size, area and output system you want. By choosing the composition, quantity, concentration, ratio of the mixture of materials, it is possible to rationally and efficiently recover heat under specific conditions. With a compact mobile system, heat can be stored by changing the location, time and medium of heat pickup.

The essential features of the invention are:

• By retaining the main feature of a planar solar collector - the flowing tube circulating the heat carrier and the flat structure - the heat exchanger and the modified heat storage modules are interconnected by a flowing tube in the unit housing. This technical solution allows combining modules with each other and with other systems. The heat collector itself can be made small, self-contained and mobile. If required, small modules can be assembled into a system of desired size and features.

• The heat pickup module consists of a flat-bottomed double-tube heat exchanger, which is arranged in parallel in the plane of the complex, as a more efficient heat transfer unit and as a heat transfer unit to the heat transfer tube. The solar panel also gets the features of a vacuum collector. The unit becomes more sensitive and can operate over a wider and lower temperature range.

• In order to increase the surface area to be absorbed, the heat pipes are collected in several bundles and arranged in parallel, although they are interconnected by a continuous flow pipe. Heat is absorbed in a spatial, volumetric way, more efficient than planar conventional heat absorption. Therefore, the problem of beam reflection is less relevant. The length of the passing tube increases several times, and the amount of heat transfer medium increases.

• The heat pipe contains a mixture of salts, liquids and gases, each time selected for the desired temperature regime. The collector starts up much earlier and longer. Proposed solution options - 30 ° C --- + 100 ° C and above, i.e. the unit can work even in cold weather. Contrary to the usual use of a single material, mixtures of salts, liquids and gases make it possible to prepare each heat collector to operate under very different conditions. The scope of application of such equipment is greatly expanded.

• In the heat pipe, a flow guide is installed on the asymmetrically arranged flow pipe to speed up and accelerate the flow of gas. The heat pipe provided the ability to control and accelerate the flow of gas, and thus the entire process. Possibility of bypassing the heat transfer tube 5 to 6 times faster while transferring more heat, there is no element controlling the gas flow in conventional heat pipes • The solar collector, at the bottom, has a compactly integrated heat storage module. Multiple internal tanks of different temperatures, arranged so that the heat transfer medium runs from warm to cold, each time delivering an extra amount of extra heat to the colder environment than before.

The refrigerated part absorbs the heat and the best stored heat is stored in the hot part. Possibility to get extra energy not only from the sun but also from the refrigerated cooling medium. The storage module has internal and external connections for utilizing external ambient heat. A pump - a pump - is used to speed up the process. Heat tanks contain different concentrations of heat storage materials, which increases their heat capacity. In the collector heat storage module, three different heat transfer media circulate and three heat transfer fluids overlap: heat is transferred from the heat recovery module; the heat is taken from the refrigerated part and accumulated in the hot part; Externally flowing heat transfer medium delivers heat for consumption. The entire process can be optimized and accelerated as a series of thermocouples and electrical control program create optimum operating conditions.

• It is advisable to call a solar collector a thermal collector as it can work and accumulate the heat of very different heat sources. It is a heat storage machine. Without the protective glass or plastic cover and the glass tubes, the heat sink can act as a heat utilizer for domestic heat (generated by various devices and mechanisms). The collector can be used indoors where there is no sun.

All of the above features give the flat panel solar panel an added advantage.

The invention is illustrated by the following drawings:

Fig. 1 is a general view of the heat collector

Fig.2 - Schematic diagram of connection of heat collection and heat storage modules Flg.3 - Arrangement of heat pipes placed in glass pipes Fig.4 - Section of heat pipe and gas flow circulating in it Fig.5 - Schematic layout of thermocouples

Fig.6 - Flow rates of different heat carriers

Solar panel solar panel with insulated inner housing, protective transparent cover (3), transparent vacuum system, parallel to the plane tube (4), with internal heat tubes (23) circulating heat carrier with reflection of sunlight under glass tubular coating (not shown) having a heat carrier inlet connector (16) and an outlet connector (17), the heat pickup module (1) at the top of the manifold housing being connected to the heat storage module (2) compactly at the bottom of the manifold housing . The heat sink module (1) is made up of a series of transparent (two glass, superimposed tubes with air extracted in them - Figures 3 to 21 and 22) glass, parallel-planar, tubes (4) arranged in series, in series. the heat pipes (23) are connected to one another by a passing pipe (7) and are arranged side by side in the space adjacent to one another. The glass tubes are connected by a flow tube (7) and a cold heat transfer manifold (5) and a warm heat transfer manifold (6).

The collector works in this way: solar or other external heat passes through the glass tubes to heat the walls of the heat tubes (23). When heated, the gas mixture in these tubes begins to accumulate and penetrate through the guide slot (24), where this gas stream (26) is screwed and accelerated to bypass the flow tube (7) inside the heat pipe. After cooling, the gas is absorbed by the capillary material (25). The heat carrier inside the passing tube heats up and starts to move with the heat passing tube towards the warm heat-collecting manifold (6) and the heat storage module (2), where it gradually passes the warm tank (8), cooling tank (9), cooling tank (10) the carrier returns to the heat pick-up module (Fig. 6a variant) and fed to the cold heat carrier distribution manifold (5). This heat carrier circulates in a closed loop. The other heat carrier circulates in a closed loop between the cooling vessel (10) and the hot vessel (11), the heat carrier vessel (12), the compressor (13) (Fig.6b variant). The third flow of external heat carrier (water) flows externally through the inlet connection (16), the cooling vessel (9), the warm vessel (8), and the hot vessel (11), the pump-pump (15), and the outlet connection (17) ( Fig.6 variant c). All these flows are intertwined and can be controlled by the electrical control part (14). In different cycles the heat carrier can be selected by the circulating heat carrier (eg different freons, freezers, etc.), and it is expedient to use water as an external circulating carrier. The collector is capable not only of collecting heat extracted from the environment directly through the heat pipes, but also indirectly through several external connections (18) and / or internal connections (19) for connecting external heat sources. Part of the heat may be accumulated in the hot vessel (11), by cooling with a compressor (13), and in the cooling vessel (10). In this way, the manifold becomes a universal heat machine. The electrical plug 20 connects to an external electrical source.

The proposed heat collector can be widely applied as a solar heat accumulator; as a heat accumulator; as a universal thermal machine for the storage and transfer of heat from various environmental sources; combinations with various other heat devices; as separate modules in home construction and so on ..

Claims (10)

DEFINITION OF INVENTION 1. Solar panel solar panel with insulated inside housing, protective transparent cover, system of transparent vacuum, in-plane tubes, with heat transfer medium inside, heat-reflecting solar radiation under glass tubes and heat transfer medium an outflow connection, characterized in that the heat acquisition module in the upper part of the collector body is connected by a flowing tube to the heat storage module compact in the lower part of the collector body. 2. A solar flat panel according to claim 1, characterized in that the heat pickup module comprises a plurality of smaller heat pipes interconnected by a series of smaller, successively flowing tubes, and adjacent to one another in space adjacent to one another. 3. A planar solar collector according to claim 1,2, characterized in that a guide tube for winding and accelerating the flow of gas is mounted on the asymmetrically arranged flow tube. 4. A solar flat panel according to claim 1,2,3, wherein the mixture of salts, liquids and gases in the heat pipe acts as a heat carrier for heat from the heat pipe walls to the passing pipe. 5. A solar flat panel according to claim 1,2,3,4, characterized in that the types, quantities, concentrations and ratios of materials selected in the heat pipe permit simultaneous operation in a narrow, wider, lower and higher temperature range and the optimum composition of the mixture is selected. according to the most appropriate operating temperature regime. 6. A solar flat panel according to claim 1, characterized in that the heat storage module is a single unit and has a plurality of double-walled, air-withdrawing, heat storage, cooling, refrigerating and hot storage tanks of different temperatures and concentrations; compressor, pump-pump, heat carrier tank, multiple thermodetectors and an electric control unit. 7. A solar flat panel according to claim 1.6, characterized in that it comprises a plurality of tubes extending through space in different heat carriers: the tube passing through the main heat carrier interconnects the heat pickup module and sequentially the warm, cooled, refrigerating receptacles of the ever lower temperature heat storage module; a refrigerant coolant leaking tube connects the coolant, refrigerant, hot tanks, compressor; the heat transfer tube from the environment connects the inlet connection, the sequentially higher temperature cooled Warm, hot tanks, the pump - pump and the outlet connection. 8. A solar panel as claimed in claim 1,6,7, wherein the heat storage module has a plurality of external and / or internal connections for connecting external heat sources. 9. A solar flat panel according to claim 1,6,7,8, characterized in that a plurality of thermocouples measuring the ambient temperature and the internal temperature of different capacitances connected to the electrical control unit, according to control programs, enable the optimum operation of the collector depending on environmental conditions. 10. A solar panel according to claim 1,2,3,4,5,6,7,8, characterized in that, in addition to the protective glass cover and the glass tubes in the heat-collecting module, the solar panel may function as a variety of devices, mechanisms, heat utilizer from sources.