GR1009246B - SOLAR SOLAR CONCENTRATOR SYSTEM FOR 3 SOLAR PRODUCTION FOR ELECTRIC, AIR CONDITIONING AND THERMAL ENERGY FOR BUILDINGS - Google Patents

Abstract

The invention offers the possibility of producing solar electricity, heat and cooling energy for buildings with conventional PV cells of polycrystalline silicon, which operate under concentration of three Suns, with the same electrical losses and the same operating temperstures with the conventional ones and produce for the same nominal power triple electricity to one third of the cost of the conventional PV generators and workong with flat mirrors ans a simple mounting system that can suffice to seasonal only tilt to follow the sun or with a continuous tilt adjustment or full sun tracking they can give lower cost per installed kilowatt and kilowatt-hour produced, compared to the current state of the art, while the existing production facilities of PV modules can triple their production in MW of PV modules at one third of the specific cost of the PV modules with no need for additional investment.

Description

SOLAR CONCENTRATION SYSTEM OF 3 SUNS FOR THE SIMULTANEOUS PRODUCTION OF ELECTRICITY. AIR CONDITIONING AND HEAT ENERGY FOR BUILDINGS

A'1. GENERALLY

The exploitation of Solar Energy for the production of electrical, thermal and cooling energy is now imperative, in order to avoid climate change.

Solar energy is the only abundant sustainable and globally equitably distributed renewable energy source. To date, however, the operating costs of solar thermal, photovoltaic and solar thermal/cooling applications remain high compared to conventional energy sources. As a result, the electricity produced must be supported with subsidized prices for periods of up to 20 years (feed-in tarrifs) or with tax credits (tax credits) and other means of support, while solar space heating and cooling remain expensive and are still in the research and development stage.

It is therefore necessary to reduce both the investment cost (Capex) of the PV panel production technology and the specific cost of the PV panels as well as the solar electricity, heating and air conditioning energy production so that its application becomes competitive and sustainable.

A'2. THE COGNITIVE FIELD TODAY

PV technology has seen a remarkable reduction in prices, but it needs even more reduction both in its production investment cost (Capex) and in the specific cost of PV Panels and the cost per installed KW, with the parallel possibility of exploiting the multiple discarded thermal energy for use in the production of cold energy for air conditioning, as well as the possibility of alternative storage to that of batteries, which is an order of magnitude more expensive and is still in the research and development stage.

The main obstacle to the use of solar thermal energy mainly for the production of air conditioning energy is the cost of producing hot and superheated water for the operation of absorption heat pumps.

Existing vacuum tube solar technologies, although mass-produced to produce solar water heaters up to 90°C, are still an order of magnitude more expensive than the price level that would make solar air conditioning energy competitive.

Also, for both solar air conditioning and thermal energy production technologies, the need to store energy to cover the corresponding load curve at night remains imperative, a field where the cost is still very high and is also in the research and development stage.

B. ADVANTAGES OF THE PRESENT INVENTION

The main advantages of the present invention of 3 Suns for the solar production of electrical, thermal and air-conditioning energy for buildings are the following:

- The technology of the present invention for solar production of electricity, cooling and thermal energy for buildings, while it does not necessarily require full monitoring of the Sun to achieve the required concentration of 3 Suns of solar radiation, where it consists of PV Generators Concentration of 3 Suns placed in front of mirrors placed in a suitable position oriented with a slope to the South, or SE or SW, able to take advantage of all the solar radiation, direct and diffused with an amplification of 2.0-3.0 times (or even more) for 6-8 months in time without change of inclination in the winter months, with a reduction of the amplification to 1.0-2.0 times, in the summer months, where by adjusting the angle of inclination indicatively every 2-3 months a return to an amplification of 2.0-3.0 times is achieved and in the summer months, while continuous regulation or full tracking achieves maximum concentration all year round.

-     Because the photovoltaic generators with the innovation of the present invention operate under a concentration of three Suns with the same electrical losses and the same operating temperatures as the conventional ones and produce for the same nominal power three times the electricity with one third of the specific cost of the corresponding conventional ones photovoltaic generators, allow the existing PV Panel Production Units to triple their production in equivalent nominal PV Power, without any need for additional production investments (Capex itself) or any other additional production costs, while at the same time they will be able to have the producing them more than twice as cheaply per nominal KW of equivalent PV Power with an increased and sustainable profit margin.

C. DESIGNS

- Drawing No 1 shows the general arrangement of the System (A.1) with four rows of the Mirror (A.1.1) with the Support and Tilt Change System (A.1.2) of the Mirror (A.1.1) and the underlying Production System of Electric Energy (A.2) in conjunction with the System (A.1.2) of the Mirror (A.1.1) with the Tilt Change Linear Motor and the Torque Balancing Counterweights.

- Drawing No. 2 shows in an axometric view the arrangement of a typical series of the System (A.1) with the Mirror (A.1.1) and the underlying Power Generation System (A.2) in conjunction with the Support and Tilt Change System (A.1.2) of the Mirror (A.1.1) with the Tilt Change Linear Motor and the Torque Balancing Counterweights.

- Drawing No. 3 shows in side view the arrangement of the System (A.1) with the Mirror (A.1.1), the Support and Tilt Change System (A.1.2) of the Mirror (A.1.1) and the underlying System ( A.2) Electricity Production at various tilt angles for various elevation angles of the Sun on the horizon.

- Drawing No. 4 shows the general arrangement of the System (A.1) with the Electric Energy Production System from 3 Solar Concentration PV Generators (A.2), the Thermal Energy Production System (A.3), the Storage System heat (A.4) and the Cooling Energy Production System with Heat Pumps (A.5) and the connection to the Network (D) through the Inverter (2.9) and the Electrical Panel (2.10).

- Drawing No. 5 shows the layout detail of the PV Generators (A.2.1) or (A.2.1a), with the PV Cells (2.1) or (2.1a) each divided into three sections connected in series and the structure of the back Heat Dissipation Surface (A.2.2) in mechanical contact on the back of the PV Generators (A.2.1) or (A.2.1a), with the Lamination (20), on the back surface of PV Generators (A.2.1) or (A.2.1a), with retention in the final contact position by the Lips (20.2) of the Perimeter Aluminum Profile (20.1).

- Drawing No. 6 shows the layout detail of the structure of the rear Heat Dissipation Surface (A.2. 6) with the Heat Dissipation Tubes (2.3.a'), in mechanical contact on the back of the PV Generators ( A.2.1) or (A.2.1a), with the Lamination (20. a) on the rear surface of the PV Generators (A.2.1) or (A.2. 1a), with retention by the Lips (20.2a ) of the Perimeter Aluminum Profile (20.1a).

- Drawing No. 7 shows in an axonometric view the arrangement of the System (A.1) with the Support Surface (22) of the Mirror (A.1.1) and the Mirror (A.1. 1a) with the System (A.2) or the System (A.3), in conjunction with the Support and Tilt Change System (A.1.2).

- Drawing No. 8 shows in an axometric view and enlargement the layout of the System (A.1) with the Support Surface (22) of the Mirror (A.1.1) and the Mirror (A.1. 1a) with the System (A. 2) and the System (A.3), in conjunction with the Support and Tilt Change System.

D. DESCRIPTION OF THE SOLAR CONCENTRATION SYSTEM OF 3 SUNS FOR THE SIMULTANEOUS PRODUCTION OF ELECTRICITY. AIR CONDITIONING AND HEAT ENERGY FOR BUILDINGS

The Solar Concentrating System of 3 Suns for the Simultaneous Production of Electric, Cooling and Thermal Energy of Buildings, or for short Solar System (A), is characterized by the fact that it consists of the following parts, in their entirety or a combination of some of them:

1. The 3 Sun Concentration System (A.1) (System (A.1)),

2. The System (A.2) of Electricity Production from 3 Solar Concentration PV Generators (System (A.2)),

3. The Thermal Energy Production System (A.3) from the rejected thermal energy from the PV Generators and from the Thermal Energy Production from the parallel Double Vacuum Tube Solar Collectors (System (A.3)),

4. The (A.4) Heat Storage System (System (A.4)),

5. The System (A.5) of Cooling Energy Production with Heat Pumps (System (A.5)),

where the System (A.1) is characterized by the fact that it consists of the Mirror System (A.1.1) of Concentration of 3 Suns (Mirror (A.1.1)) and the Support and Tilt Change System (A.1.2) of the Mirror (A .1.1) (System (A.1.2)),

where the Mirror System (A.1.1) of Concentration of 3 Suns (Mirror (A.1.1)) is characterized by the fact that by adding it to the System (A.2), with an Angle of Inclination (αi) of the Mirror (A.1.1) towards the vertical indicatively between -45° and 30° or any other deemed appropriate and with Angle (a2) between the Mirror (A.1.1) and the incident Sun Rays (1a) indicatively between 22.5° and 45° or any other deemed appropriate suitable, with the System of Electricity Production from PV Generators of Concentration of 3 Suns (A.2) indicatively placed vertically towards the level of the Mirror (A.1.1) or in a horizontal position or with a slight inclination towards the horizon and the Mirror (A .1.1) in a vertical position plus Angle (a1) indicatively between -45° and 30°, for south orientation, indicatively with a ratio of width (A.1.1) / (A.2) = 4 to 6 and length of the Mirror (A .1.1) equal to or slightly greater than the length of the System (A.2), the incident solar radiation on the System (A.2) is multiplied by a factor of 1.0 to 3.3, with μ maximum for Angle α2=45° even without tracking the Sun, where due to this characteristic the Solar System (A) is characterized by the fact that it can also be implemented as a constant inclination system with a change of the inclination angle indicatively every 2-3 months, on the contrary from Reference [1], which concerns fixed solar facades of buildings with a fixed mirror inclination equal to -15°, and a maximum concentration value of 2.54 for a sun inclination angle of 30° while the concentration factor for a sun inclination angle above 60 ° drops to almost 1.0 (ie there is no concentration but only the radiation of a sun), where the present invention is characterized by the fact that through the Support and Tilt Change System (A.1.2) or complete tracking, it changes the Tilt Angle ( a1) of the Reflector (A.1.1) from -45° to 30° or any other deemed appropriate and increases the maximum value of the concentration factor to 3.0 or even greater in all months and especially in the summer months where there is also the need to conduction and air-conditioning energy from the extracted heat of PV Cells.

The System (A.1) is also characterized by the fact that the Mirror System (A.1.1) is manufactured as a plane mirror or multiple prismatic plane or parabolic or other form, indicatively flat, with a high degree of reflection, which is placed with a suitable angle of inclination indicatively 60° - 135° or any other deemed appropriate, between the Mirror (A.1.1) and the horizontal plane, with a reflection surface on the south side of the Mirror (A.1.1), where the System (A.2) is preferably arranged together with the Mirror (A.1.1) facing south, with the possibility of east or west or intermediate orientations and other inclinations, so that the solar radiation incident on the Mirror (A.1.1) is reflected and directed to the surface of the System ( A'2),

where the System (A.1) is also characterized by the fact that the Mirror (A.1.1) in its flat version, is made indicatively of a sheet of mirrored stainless steel or mirrored aluminum with a reflection coefficient of more than 0.84 or from a reflective film with a support substrate indicative of 3M or SKY FUEL or of glass plate indicatively 3-4 mm thick with back silvering with anti-reflective coatings and a final layer of protection for exposure to the environment, as is the current state of the art, with a reflection coefficient of more than 92% and a life time without degradation of their reflectivity over 25 years,

where the System (A.1) is also characterized by the fact that, in addition to the Mirror (A.1.1), it alternatively carries a second Mirror (A.1.1a), opposite the Mirror (A.1.1), with an equal or different height from the height of the Reflector (A.1.1), and with an indicative Inclination Angle (a4)=120° to the level of PV Generators (A.2.1) in its horizontal position or for an Inclination Angle (a5) of the Reflector ( A.1.1a) equal to -30° to the vertical, which through the Hinges (10a) and (10a') and the Parallel or Independent Tilt Arms (10d) can monitor the movement of the Mirror (A.1.1) , with a change in its angle relative to the vertical indicatively the same as the change in the angle of the Mirror (A.1.1), so as to maximize the concentration of solar radiation on the PV Generators (A.2.1), with an indicative increase in degree of concentration 2.54 by at least 0.76, for the corresponding optimal value of the Inclination Angle (α2)=45° between the Mirror (A.1.1) and the approaching Solar Coasts fibers (1a), indicatively at the value 2.54+0.7=3.30, for a height of the Mirror (A.1.1a) equal to the height of the Mirror (A.1.1), degree of reflection of the Mirror (A.1.1 a) equal to 0.9 and a percentage of direct radiation of 80%, and a corresponding smaller increase for the remaining Angles of Inclination (a2),

where the System (A.1) is also characterized by the fact that the Mirror System (A.1.1) and the Mirror (A.1.1a) amplify indicatively by 2.54-3.3 times the incident solar radiation on the System (A .2) for an adjustable Angle of Inclination (a2) between the Mirror (A.1.1) and the Solar Rays (1a), so as to obtain a maximum concentration factor with an adjustable Angle of Inclination (a2) of 45° and additionally during the day adjustment of the Angle of Inclination (a2) from 15° in the morning to indicatively 22.5° from morning to noon or any other deemed appropriate and again similarly 22.5° to 15° from noon to sunset in the afternoon with reference to west at the level of the Mirror (A.1.1), with the System (A.2) fixed in a horizontal position or fixed with a slight inclination towards the horizon or alternatively fixedly attached to the Mirror (A.1.1) and the Mirror (A .1.1a) or with another slightly different inclination towards the Reflector (A.1.1) and southern orientation of the Reflector (A. 1.1),

where the Mirror (A.1.1) and the Mirror (A.1.1a) are also characterized by having the Support Frame (12) and (12a) made of an aluminum profile or hollow beam or a circumferential folding of the stainless steel or aluminum sheet, which on its lower side it carries the Rotation Hinges (10a) and (10a') respectively, which allow them to change their angle of inclination towards the vertical plane with the help of the Rear Push-Pull Beam (11), the Push-Pull Arms Pull (13), the Hinges (10a) and (10a'), the Parallel Tilt Arms (10d), the Supports (13b) and the Coupling Beam (14) of the Support and Tilt Change System (A.1.2) of the Mirror ( A.1.1) and the Mirror (A.1.1a), all made indicatively of aluminum profiles or hollow beams and the Linear Motor Mechanism (14a), which through the Electrical Panel (15) and a suitable Sun Monitoring System (16), gives the movement and driving to change the inclination of the Mirror (A.1.1) and of the Mirror (A.1.1a),

wherein the System (A.1) is also characterized in that the Support and Tilt Change System (A.1.2) supports the Mirror (A.1.1) and the Mirror (A.1.1a) and drives them to change tilt so as to achieve the desired concentration of solar radiation on the underlying System (A.2) on a seasonal and daily basis as above to achieve and maintain the maximum concentration factor,

where the System (A.1) is also characterized by having under the Axis (10e) of the Rotation Hinges (10a) and on the Thrust Arms (13) the Counterweights (13a) made indicatively of cast iron, the center of gravity of which is located antidiametrically to the center of gravity of the Mirror (A.1.1), the Mirror (A.1.1a) and the Systems (A.2) and (A.3), with respect to the Axis (10e) and with a weight such that the its moment with respect to the Axis (10e) to compensate for the moment of the center of gravity of the Mirror (A.1.1) of the Mirror (A.1.1a) and Systems (A.2) and (A.3) with respect to the Axis ( 10e) and thus the rotation of the Mirror (A.1.1) and the Mirror (A.1.1a) with respect to the Axis (10e) is done without difficulty by the Support and Tilt Change System (A.1.2) of the Mirror (A. 1.1) and of the Mirror (A.1.1a).

Also, the Support and Tilt Change System (A.1.2) is characterized by the fact that instead of the Linear Motor Mechanism (14a), the Electrical Panel (15) and the Sun Monitoring System (16), it can carry a simple Mechanical Tilt Change System ( 17), consisting indicatively of the Arched Plate (18) with consecutive Holes (19) on a suitable Arc for Rotation (19a) around the Axis (10e) of the Rotation Hinges (10a), where by changing the position of the Support Screws ( 21) indicatively every 2-3 months the necessary slope change is achieved manually. The System (A.1) is also characterized by having the Overheating Avoidance System (27) which consists in changing the inclination of the overlying Mirror (A.1.1) until leveling or resting on the underlying System (A.2), so that shade the PV Cells (2.1) for protection from overheating, as well as from hail, dust accumulation, protection from snow load or wind pressure load in case of strong winds, etc., with corresponding activation of the Linear Motor Mechanism (14a) for tilt change, through suitable sensors and activation software.

The Solar System (A) is also characterized by the fact that it carries the Electricity Production System from PV Generators of Concentration of 3 Suns (A.2), which is characterized by the fact that it consists of the following structural elements, i.e. the PV Generators (A.2.1), the Heat Dissipation Surface (A.2.2), the Support System (2.8), the Inverter (2.9) and the Electrical Panel (2.10), where the PV Generators (A.2.1) are characterized by the fact that they are indicatively composed of one or two or more series of standardized PV Cells (2.1) of monocrystalline or polycrystalline silicon with dimensions indicatively 156 x 156mm or of other PV material with dimensions and number of rows such that their width to be preferably equal to a quarter or a sixth of the width of the Mirror A.1.1, which are however characterized by the fact that each PV Cell (2.1) is divided into two, three or even more PV Cells (2.1 .1), (2.1.2), (2.1.3) etc., which are connected to each other in series, so that the current flowing through the PV Cells (2.1.1), (2.1.2), (2.1.3) etc. remains the same under two or three or more suns respectively with the current flowing the entire undivided PV Cells (2.1) under one sun, and then connected in series with the next PV Cells (2.1.1), (2.1.2), (2.1.3) etc within the frames of each PV Generator (A.2.1), and then connecting each PV Generator (A.2.1) in series with the Cables (2.7) to the next PV Generator (A.2.1), so as to create independent one from the other, one or two (or more depending on the width of the Generator (A.2.1)) parallel series (strings) of PV Generators (A.2.1), until the desired voltage is reached, at which point the generation starts again of a new series (string) of PV Generators (A.2.1), and where the rest of the PV Generators (A.2.1) are manufactured like conventional monocrystalline or polycrystalline silicon PV Generators.

The PV Generators (A.2.1) are also characterized by having the Heat Dissipation Surface (A.2.2) welded or affixed or in mechanical contact on their rear surface, which is characterized by the fact that it consists indicatively from a curved Lamina (20) of Thin Elastic Steel or Aluminum Sheet with a thin wall, indicatively 0.2-0.3mm, which with elastic deformation due to its outwardly curved structure is forced to be pressed mechanically (or glued) on the Tedlar/Aluminium Sheet (2.1.c) that covers the back surface of the PV Generators (A.2.1) with retention in the final contact position by the Lips (20.2) of the Perimeter Aluminum Profile (20.1) and thus come to full thermal contact with them to remove the heat rejected by the PV Cells (2.1), alternatively by adding to the contact surface between the Laminate (20) and the Tedlar / Aluminum Sheet (2.1.c) a thin thermally conductive semi- fluidized bed Material (20.c) to facilitate heat dissipation and or facilitate sliding between the Laminate (20) and the Tedlar / Aluminum Sheet (2.1.c) during the small differential displacements due to unequal thermal expansions of the two above materials, indicatively thick thermally conductive, electrically insulating grease, where the Lamination (20) has glued on its outer surface the Cooling Fins (2a') made of Thin Aluminum Sheet (2a") with a thin wall, indicatively 0.1-0.2mm, which creates the parallel Cooling Fins (2a') with a P-shaped folding in a direction perpendicular to the longitudinal axis of the PV Generator (A.2.1), with side legs of a height indicative of three times the width of the folding and a width of the folding equal to 5-10 mm approximately and width of the head of Π indicatively equal to one third of the width of the fold,

it is also characterized by the fact that alternatively the Heat Dissipation Surface becomes (A.2.2a), which is characterized by the fact that alternatively the Lamination (20) has the Support Surface (22) of the System (A.) glued or pressed mechanically on its outer surface. 2) or (A.3), which can protrude to the right and left of the surfaces of Systems (A.2) and (A.3) by such a width (22e), indicatively equal to the width (a) of PV Generator (A.2.1) or (A.2. 1a), so that the total surface area for dissipating the heat rejected by the PV Cells (2.1) is indicatively 9 times larger than the surface of the PV Generators ( A.2.1) or (A.2.1a), (with equivalent width 2 x a 2 x π/2 x a 2 x 2xa = 9.14xa or approximately 9xa) or 9/2=4.5 times greater than the surface of heat dissipation of the PV Generators (A.2.1) or (A.2. 1a), (with a width equal to 2xa) under 3 suns or 4.5/3=1.5 times greater than the heat dissipation surface of PV Generators (A.2.1) or (A.2.1a), approx under 1 sun, which leads to a lower operating temperature of the PV Generators (A.2.1) or (A.2. 1a), under 3 suns,

where the Solar System (A) is also characterized by the fact that it alternatively carries the System (A.2a), which is characterized by the fact that it consists of PV Generators (A.2. 1a), and PV Cells (2.1a ) suitable for operation at high temperatures, which indicatively have the same structure as the "DESERT PV Panel" of the German Company J. n. G. Thoma GmbH, where the PV Generators (A .2.1a), and PV Cells (2.1a) can operate continuously indicatively at temperatures up to 125°C with a maximum of 145°C [2] and with better performance than conventional PV Generators, where the Systems ( A.2) and (A.2a) are also characterized by the fact that they alternatively carry the System (A.3) Production and Thermal Energy from the PV Generators of Concentration of 3 Suns (System (A.3)), which is characterized by that it carries in front of the PV Generators (A.2.1) or (A.2. 1a), the Front Glass Cover (A.2.5) and at the back of the PV Generators (A.2.1) or (A .2. Ia), the Surface Heat Dissipation (A.2. 6) and the Thermal Insulation Surface (A.2.7),

where the Front Glass Cover (A.2.5) is characterized by the fact that it consists of at least one additional front Glass Cover (2.5), constructed like the double glass cover of solar water heaters, in order to increase the degree of thermal efficiency at higher operating temperatures , where it is also characterized by the fact that alternatively in the space between the two front glass covers (i.e. the Glass Cover (2.5) and the Glass Surface (2.1d) of the PV Generators (A.2.1) or (A.2. 1a) ,) also carries Transparent Airgel Insulation (2.6) or Cellular Transparent Insulation (2.6') (Transparent Honeycomb Insulation), like that of the Israeli company TIGI Ltd (TIGI Honeycomb Collector) [3], for an even greater increase in the degree of thermal efficiency at higher operating temperatures,

where the Heat Dissipation Surface (A.2.6) is characterized by the fact that it consists indicatively of a curved Lamina (20a) of construction and placement/operation like the Lamina (20) in cooperation with the Material (20.c) above, which is however characterized by that it consists of a Thin Elastic Steel or Aluminum Sheet with a thin wall, indicatively 0.2-0.3mm, which by elastic deformation from its outwardly curved structure is forced to be mechanically pressed (even glued) onto the Tedlar Sheet / Aluminum (2.1.c) covering the rear surface of the PV Generators (A.2.1) or (A.2.1a), with retention in the final contact position by the Lips (20.2) or (20.2a) of the Perimeter Profile Aluminum (20.1) or (20.1a) and thus come into complete thermal contact with them for the removal of the heat rejected by them, where the Lamination (20a) is characterized by having attached the Cooling Laminations (2.1.a') from Thin Steel or Aluminum Sheet (2.1.a”) with a thin wall, indicative 0 ,2-0, 3mm, which creates for each series of PV Cells (2.1) or (2.1a) two cylindrical Folds (2.2.a') with an axis parallel to the longitudinal axis of the series of PV Cells (2.1) or (2.1a), which Folds (2.2.a') surround the U-shaped Heat Sinks (2.3.a'), which are of the same technology and construction as the U-shaped heat sinks of conventional double-wall vacuum tubes, which absorb the heat and cool the respective Series of PV Cells (2.1) or (2.1a) indicatively in series lengths of 1.5-2.0 meters, where then the two legs of each Tube (2.3.a') are connected in the pairs of Head Pipes (2.4.a'), which are also of the same technology and construction as the head pipes of conventional solar water heaters with vacuum double-walled pipes, which through a Circulation Pump (2.5.a') or through an Organic Fluid circulation and Steam (2.3.c) heat pipes (heat pipes) transport the abducted heat indicatively either in Hot Water Tanks (2.6.a') or in a Cooling Tower (2.7.a') or in another heat exchanger or in a heat storage system, through the Heat Dissipation Fluid (2.3.b), which is preferably from thermal oil resistant to the operating conditions of the System (A.3) or from Organic Fluid and Vapors (2.3.c) for the operation of heat pipes or from another suitable fluid,

where also the Thermal Insulation Surface (A.2.7) is characterized by the fact that it consists of standard polyurethane or stone wool insulation as is the technical level of thermal insulation for solar water heaters,

where the Solar System (A) is also characterized in that the Mirror (A.1.1) and the Mirror (A.1.1a) can be permanently connected to the System (A.2) or to the System (A.3) , in an indicative arrangement where the System (A.2) or the System (A.3) is in a horizontal position and the Mirror (A.1.1) and the Mirror (A.1.1a) with angles (a2) and ( a4) equal to 22.5° and -30° with respect to the vertical respectively and where the driving for the seasonal or daily angle change for tracking the Sun and maximizing the degree of concentration is done by rotating the respective set of permanently connected elements, i.e. the Mirror (A.1.1) and the Mirror (A.1.1a) with the System (A.2) or the System (A.3), in packages of one or two or three or even more repetitions of the above set through the System Support and Slope Change (A.1.2a), with passage of the Fluid (2.3. b) next to the Axis (10g), where the Support and Slope Change System (A.1.2a), is characterized by that it alternately consists of the Push-Pull Half-ring (13a), the Rear Push-Pull Beam (11a), the Rotation Axis (1Oz), the Parallel Tilt Arms (10h) and the Coupling Beam (14b), all manufactured indicatively by aluminum profile or hollow beams and the Linear Motor Mechanism (14a), which through the Electrical Panel (15) and a suitable Sun Monitoring System (16), gives the movement and drive to change the inclination of the set of permanently connected elements about the Axis (10g) i.e. Mirror (A.1.1) and Mirror (A.1.1a) with System (A.2) or System (A.3) in packages as above,

where the Solar System (A) is also characterized by the fact that the Support Surface (22) of the permanently connected elements, i.e. the Mirror (A.1.1) and the Mirror (A.1.1a) with the System (A.2) or the System (A.3) in packages as above is characterized by the fact that it can consist of a Single Formed Sheet / Vessels (23) made of a thin sheet of steel or aluminum with a thickness of approximately 0.5 - 1.0mm in packages of dimensions of approximately 1.0x2.0 meters, which carry a Peripheral Support Frame (24) made of aluminum profiles or steel hollow beam, where the Single Formed Lamina / Vessels (23) can also form the back Heat Dissipation Surface (A.2.6a) of the PV Generators (A .2.1) or (A.2.1a)„ which is characterized by the fact that it constitutes a heat dissipation surface with an area approximately 12 times the area of the corresponding PV Generator (A.2.1) or (A.2.1a)„ with four times the capacity to dissipate the heat emitted by three times the incident solar radiation, thus creating even lower operating temperatures compared to simple PV generators operating under a sun,

wherein alternatively the Solar System (A) is also characterized in that the Single Formed Lamina / Vessels (23) of the Support Surface (22) are also characterized in that they consist of Mirrored Stainless Steel Sheet (25) or Mirrored Aluminum Sheet (26) , which replace both Mirror (A.1.1) and Mirror (A.1.1a),

where the Solar System (A) is also characterized by the fact that it consists of a variant (A.2'+ A.2a'+A.3') of the System (A.2), (A.2a) and (A.3 ) (System A.2'+ A.2a'+A.3') which is characterized by the fact that it consists of the replacement of PV Generators (A.2.1) or (A.2.1a), by Solar Collectors (A.2.1b) and (A.2.1c) respectively, which are characterized by the fact that they are entirely of the same construction as the PV Generators (A.2.1) or (A.2.1a), but are characterized by the fact that they are replaced PV Cells (2.1) or (2.1a) with Absorbing Surfaces (2.1b) and (2.1c) respectively, with a high absorption index and a low emission index of solar radiation, of the same construction as the absorbing surfaces of solar water heaters, which are characterized by the fact that they now only produce thermal energy with a high degree of efficiency, due to the triple incidence of solar energy in relation to the solar panels of a sun, where with the same temperatures of the absorption surfaces, the same thermal losses drop, while the absorbed energy triples, resulting in a doubling of the corresponding thermal efficiency coefficient, especially at high operating temperatures,

where alternatively the Solar System (A) is also characterized by the fact that in the empty space next to the PV Generators (A.2.1) or (A.2.1a), and the Solar Collectors (A.2.1b) and (A. 2.1c) respectively with a width indicatively equal to the width of the respective PV Generators (A.2.1) or (A.2.1a)"

where the Solar System (A) is also characterized by alternatively consisting of a variant (A.2"+A.2a"+A.3") of System (A.2), (A.2a) and (A. 3) (System (A.2"+A.2a"+A.3")) which is characterized by the fact that it consists of the replacement of PV Generators (A.2.1) or (A.2. 1a), of the Systems (A.2) and (A.2a) respectively, with the Double Wall Vacuum Tube Solar Collectors (A.2.1b') and (A.2.1c') respectively, which are characterized by the fact that they are all of the same construction with Double Wall Vacuum Tube Solar Collectors with rear single or double parabolic reflection surface behind each Vacuum Tube as in Reference [4], which are characterized by the fact that they now produce thermal energy with a very high degree of efficiency, due to the triple incidence of solar of energy in relation to the solar panels of a sun, because with the same temperatures of the absorption surfaces and therefore with the same thermal losses, the absorbed energy triples a resulting in the doubling of the corresponding thermal efficiency coefficient especially at high operating temperatures, for example for a temperature of 80°C the degree of efficiency of one sun in Reference [4] is 36.4%, while in the present invention below three suns with the same losses (100-36.4=73.6%) the degree of efficiency becomes (300-73.6)/300= 75.467% or 75.467/36.4=2.0732 i.e. more than double the degree of efficiency, where alternatively the Solar System ( A) is also characterized by the fact that in the empty space next to the respective PV Generators (A.2.1) or (A.2.1a), it also carries the Double Wall Vacuum Tube Solar Collectors (A.2.1b") and (A. 2.1c") respectively, which are characterized by the fact that the rear single or double parabolic reflection surface behind each Vacuum Tube, in the variant of the Support Surface (22) where it consists of Mirrored Stainless Steel (25) or Mirrored Aluminum (26), is then created by the Mirrored Stainless Steel Steel (25) or from Mirrored Aluminum (26) respectively and with a width indicatively equal to the width of the respective PV Generators (A.2.1) or (A.2. 1a), or alternatively bring only Double Wall Vacuum Tube Solar Collectors (A.2.1b") and (A.2.1c") respectively and omit the respective PV Generators (A.2.1) or (A.2.1a )"

where the Solar System (A) is also characterized in that the Heat Storage System (A.4) (System (A.4)) and the Cooling Energy Production System with Heat Pumps (A.5) (System (A.5) ) are connected to the Thermal Energy Production System (A.3) (System (A.3)) through the Three-Way Mixing Valve (28) which supplies the System (A.5) with the temperature of the hot or superheated water, which gives the optimal COP,

where the Solar System (A) is also characterized by the fact that the Inverter (2.9) and the Electrical Panel (2.10) connecting to the grid or consumption are the same as the conventional technology of classical PV, it is also characterized by the that the technology for the Heat Storage System (A.4) (System (A.4)) and the Cooling Energy Production System with Heat Pumps (A.5) (System (A.5)) is the same as the conventional technology the classic Heat storage systems 80°-180°C and the classic cooling energy production systems with heat pumps with adsorption or absorption of one phase or two phases using a thermal fluid indicatively hot water of the order of 80°-180°C but with the possibility of operation and at night, which are thus characterized by the fact that in combination with the rest of the elements of the Solar System (A) they make much better use of solar energy for the production of electrical, cooling and thermal energy from the sun virus.

REFERENCES

[1] Experimental evaluation of low concentration collectors for fagade applications "httD://aut.researchaatewav .ac.nz/bitstream/handle/10292/7197/Revised)

[2] J. v. G. Thoma GmbH Targets New Glass-Focused Development for DESERT Technology http ://www. iva-thoma.de/

[3] The TIGI LTD Honeycomb Collector http://www .tigisolar.com/

[4] Article Guiqiang Li, Gang Pei, Yuehong Su, Jie Ji, Dongyue Wang and Hongfei Zheng "Performance study of astatic low-concentration evacuated tube solar collector for mediumtemperature applications"

Claims (10)

A X I O S E I S 1. A Solar Concentrating System of 3 Suns of Simultaneous Production of Electric and Thermal Energy of Buildings with Adjustable Tilt Mirrors or for short Solar System A, which is characterized by the fact that it consists of the following parts, i.e. the 3 Sun Concentrating System (A.1) (System (A.1)) and from the System (A.2) of Electricity Production from 3 Solar Concentration PV Generators (System (A.2)), where the System (A.1) is characterized by the fact that it consists of the Concentrating Mirror System indicative of 3 Suns (A.1.1) (Mirror (A.1.1)) and the Support and Tilt Change System (A.1.2) of the Mirror ( A.1.1) (System (A.1.2)), where the Mirror (A.1.1) is characterized by being manufactured as a flat or multiple Fresnel or parabolic mirror or of another form, indicatively flat, with a high degree of reflection, where the Mirror (A.1.1) in its flat version, is made of specular material with a high reflection coefficient, where the System (A.2) is arranged together with the Mirror (A.1.1) in such an arrangement and way of monitoring the Sun, that the solar radiation incident on the Mirror (A.1.1) is reflected and directed on the surface of the System (A.2) with a concentration factor of 3 Suns, where the System (A.1) is also characterized by the fact that the Support and Tilt Change System (A.1.2) supports the Mirror (A.1.1) and leads it to change tilt in order to achieve the maximum concentration of solar radiation on the System ( A.2) on a seasonal and daily basis to achieve and maintain the maximum concentration factor, where the Mirror (A.1.1) is also characterized by indicatively amplifying by 2-4 times the incident solar radiation on the System (A.2) for an adjustable Angle of Inclination (a2) between the Mirror (A.1.1) and the Solar of rays (Ia), in order to achieve the maximum degree of concentration, where the Mirror (A.1.1) is also characterized by the fact that, for this purpose, it carries a Tilt Change System through a Drive Mechanism and a suitable Sun Monitoring System, which gives the movement and drive to change the tilt of the Mirror (A.1.1), where the Solar System (A) is also characterized by the fact that it carries the System (A.2) of Electricity Production from PV Generators Concentration indicative of 3 Suns, which is characterized by the fact that it consists of the following structural elements, i.e. the Φ/ B Generators (A.2.1), the Heat Dissipation Surface (A.2. 2), the Support System (2.8), the Inverter (2.9) and the Electrical Panel (2.10), where PV Generators (A.2.1) are characterized by being indicatively composed of one or two or more series of standardized PV Cells (2.1) of monocrystalline or polycrystalline silicon dimensions indicatively 156 x 156mm or other PV material with dimensions and number of rows such that their width is preferably equal to one quarter or one sixth of the width of the Mirror (A.1.1), which are characterized by the fact that each PV Cell (2.1) is divided into two, three or even more PV Cells (2.1.1), (2.1.2), (2.1.3) etc., which are connected to each other in series, so that the current flowing through the PV Cells (2.1.1), (2.1.2), (2.1.3) etc. to remain the same under two or three or more suns respectively with the current flowing through the entire undivided PV Cells (2.1) under one helium, and then connected in series with the next PV Cells (2.1.1), (2.1.2), (2.1.3) etc within the frames of each PV Generation of three (A.2.1), and then connecting each PV Generator (A.2.1) in series with the Cables (2.7) to the next PV Generator (A.2.1), so as to create the desired series ( string) PV Generators (A.2.1), and where the rest of the PV Generators (A.2.1) are manufactured like conventional monocrystalline or polycrystalline silicon PV Generators, where the PV Generators (A.2.1) are also characterized by having on their rear surface welded or glued or in mechanical contact thereon, the Heat Dissipation Surface (A.2.2), which is characterized by the heat developed by PV Generators (A.2.1), 2.  A Solar System (A) as in Claim 1, which is characterized in that the Mirror (A.1.1) is manufactured as a flat or parabolic mirror or of another form, indicatively flat, with a high degree of reflection, where the Mirror (A. 1.1) in its flat version, it is manufactured from a sheet of mirrored stainless steel or mirrored aluminum with a reflection coefficient of more than 0.84 or from a reflective film with a support substrate indicative of 3M or SKY FUEL or from a glass plate of thickness indicatively 3-4 mm with rear silvering with anti-reflective coatings and a final layer of protection for exposure to the environment, as is the current state of the art, with a reflection coefficient of more than 92%, where the Mirror (A.1.1) is also characterized by having the Support Frame (12), which on its underside carries the Rotation Hinges (10a), the Push-Pull Rear Beam (11), the Push-Pull Arms (13) and the Coupling Beam (14) of the Support and Tilt Change System (A.1.2), all made indicatively of aluminum profiles or hollow steel beams and the Linear Motor Mechanism (14a), which through the Electrical Panel (15) and of a suitable Sun Monitoring System (16), gives the movement and drive to change the inclination of the Mirror (A.1.1), where the Mirror (A.1.1) is also characterized by bearing under the Axis (10e) of the Rotation Hinges (10a) and on the Thrust Arms (13) the Counterweights (13a) made indicatively of cast iron, the center of gravity of which compensates the moment of the center of gravity of the Mirror (A.1.1) and Systems (A.2) and (A .3) with respect to the Axis (10e), where the PV Generators (A.2.1) are also characterized by having on their rear surface welded or glued or in mechanical contact thereon, the Heat Dissipation Surface (A.2.2), which is characterized by consisting of indicative of the Lamination (20) of Thin Elastic Steel or Aluminum Sheet, which must be pressed mechanically (or even glued) onto the Tedlar/Aluminum Sheet (2.1.c) that covers the rear surface of the PV Generators (A .2.1) with retention in the final contact position by the Lips (20.2) of the Perimeter Aluminum Profile (20.1) and thus come into complete thermal contact with them for the removal of the heat rejected by the PV Cells (2.1), with the addition on the contact surface between the Lamination (20) and the Tedlar/Aluminium Sheet (2.1.c) of a thin conductive semi-fluid layer of Material (20.c), where the Lamination (20) has attached to its outer surface the Cooling Fins ( 2a') from Thin Aluminum Sheet minium (2a"), which creates the parallel Cooling Fins (2a') with a P-shaped folding in a direction perpendicular to the longitudinal axis of the PV Generator (A.2.1), Where the Solar System (A) is also characterized by having the Overheating Avoidance System (27), which consists in changing the inclination of the overlying Mirror (A.1.1) until leveling and sealing against the underlying System (A.2), so as to shade the PV Cells (2.1) or (2.1a) for protection from overheating, as well as from weather effects with corresponding activation of the Tilt Change Motor Mechanism, through appropriate sensors and activation software. 3. A Solar System (A) as in Claims 1 and 2, which is however characterized by having the Heat Dissipation Surface (A.2.2a), which is characterized by the fact that the Lamination (20) has mechanically bonded or pressed on its outer surface the Support Surface (22) of the System (A.2) or (A.3), which protrudes to the right and left of the surfaces of the Systems (A.2) and (A.3) by such a width (22e), indicatively equal to the width (a) of the PV Generator (A.2.1) or (A.2.1a), so that the total heat dissipation surface of the heat rejected by the PV Cells (2.1) is above more than 3 times greater than the heat dissipation surface of the PV Generators (A.2.1) or (A.2.1a), below 1 sun, which leads to a lower operating temperature of the PV Generators (A.2.1) or (A.2.1a), under 3 suns, 4.  A Solar System (A) as in Claims 1, 2 and 3, but characterized in that it carries the System (A.2a), characterized in that it consists of PV Generators (A.2.1a ), and PV Cells (2.1a) suitable for operation at high temperatures, where PV Generators (A.2.1a), and PV Cells (2.1a) can operate continuously indicatively at temperatures up to 125 °C with a maximum of 145°C and with better performance than conventional PV Generators. 5. A Solar System (A) as in Claims 1, 2, 3 and 4, which is however characterized by having the Systems (A.2) and (A.2a), which are characterized by having the System (A.3) Production and Thermal Energy from the PV Generators of Concentration of 3 Suns (System A.3), which is characterized by having in front of the PV Generators (A.2.1) or (A.2.1a ), the Front Glass Cover (A.2.5) and on the back of the PV Generators (A.2.1) or (A.2.1a), the Heat Dissipation Surface (A.2.6) and the Thermal Insulation Surface (A. 2.7), where the Front Glass Cover (A.2.5) is characterized by the fact that it consists of at least one more front Glass Cover (2.5), constructed like the double glass cover of solar water heaters, where the Front Glass Cover (A.2.5) is characterized by the fact that in the space between the two front glass covers, i.e. the Glass Cover (2.5) and the Glass Surface (2.1d) of the PV Generators (A.2.1) or (A.2.1a) and Transparent Airgel Insulation (2.6) or Cellular Transparent Insulation (2.6'), for an even greater increase in the degree of thermal efficiency at higher operating temperatures, where also the Heat Dissipation Surface (A.2.6) is characterized by the fact that the PV Generators (A.2.1) or (A.2.1a),) have on their rear surface welded or glued or in mechanical contact on it , the Heat Dissipation Surface (A.2.6), which is characterized by the fact that it consists indicatively of a curved Lamina (20a) of construction and placement/operation like the Lamina (20) in cooperation with the Material (20.c) in Claim 1 , which is characterized by the fact that it consists of a Thin Elastic Sheet of Steel or Aluminum with a thin wall, indicatively 0.2-0.3mm, which with elastic deformation from its outwardly curved structure is forced to be pressed mechanically (whether or not glued) on the Tedlar/Aluminum Sheet (2.1.c) covering the rear surface of the PV Generators (A.2.1) or (A.2.1a), held in the final contact position by the Lips (20.2) or ( 20.2a) of the Perimeter Aluminum Profile (20.1) or (20.1a) and thus come into complete thermal contact with for the removal of the heat rejected by them, where the Plate (20a) is characterized by having the Cooling Plates (2.1.a') of Thin Steel or Aluminum Sheet (2.1.a") attached to them, with a thin wall, indicatively 0 ,2-0, 3mm, which creates for each series of PV Cells (2.1) or (2.1a) two cylindrical Folds (2.2.a') with an axis parallel to the longitudinal axis of the series of PV Cells (2.1) or (2.1a), which Folds (2.2.a') surround the U-shaped Heat Sinks (2.3.a'), which are of the same technology and construction as the U-shaped heat sinks of conventional double-wall vacuum tubes, which absorb the heat and cool the respective Series of PV Cells (2.1) or (2.1a) indicatively in series lengths of 1.5-2.0 meters, where then the two legs of each Tube (2.3.a') are connected in the pairs of Head Tubes (2.4.a'), which are also of the same technology and construction as the head tubes of conventional solar water heaters with double-walled vacuum pipes, which through a Circulation Pump (2.5.a') or through circulation of Organic Fluid and Vapors (2.3.c) heat pipes (heat pipes) transfer the extracted heat indicatively either to Hot Water Tanks ( 2.6.a') either in a Cooling Tower (2.7.a') or in another heat exchanger or in a heat storage system, through the Heat Dissipation Fluid (2.3. b), which preferably consists of thermal oil resistant to the operating conditions of the System (A.3) or of Organic Fluid and Vapors (2.3.c) for the operation of heat pipes or of another suitable fluid, where also the Thermal Insulation Surface (A.2.7) is characterized by the fact that it consists of standard polyurethane or stone wool insulation as is the technical level of thermal insulation for solar water heaters. 6. A Solar System (A) as in Claim 1, 2, 3, 4 and 5, but characterized by the fact that in addition to the Mirror (A.1.1) it also carries a second Mirror (A.1.1a), opposite the Mirror (A.1.1), which through the Hinges (10c) and the Parallel or Independent Tilt Arms (10d) monitors the movement of the Mirror (A.1.1), where the Mirror (A.1.1a) is also characterized by the that it carries the Support Frame (12a) made of an aluminum profile or hollow beam or a circumferential folding of the stainless steel or aluminum sheet, which on its underside carries the Rotation Hinges (10a'), which allow it to change its angle of inclination with respect to the vertical plane with the help of the Rear Push-Pull Beam (11), the Push-Pull Arms (13), the Hinges (10a) and (10a'), the Parallel or Independent Tilt Arms (10d) and the Coupling Beam ( 14) of the Support and Tilt Change System (A.1.2) and the Linear Motor Mechanism (14a), which through the th Electric Panel (15) and a suitable Sun Monitoring System (16), gives the movement and driving for changing the inclination of the Mirror (A.1.1) and the Mirror (A.1.1a), It is also characterized by having under the Axis (10e) of the Rotation Hinges (10a) and on the Thrust Arms (13) the Counterweights (13a) made indicatively of cast iron, the center of gravity of which is antidiametrically to the center of gravity of the Mirror (A.1.1), the Mirror (A.1.1a) and Systems (A.2) and (A.3), regarding Axis (10e). 7. A Solar System (A) as in Claims 1, 2, 3, 4, 5 and 6, but characterized in that the Mirror (A.1.1) and the Mirror (A.1.1a) are fixedly connected to the System (A.2) or the System (A.3), in an indicative arrangement where the System (A.2) or the System (A.3) is in a horizontal position and the Mirror (A.1.1) and the Reflector (A.1.1a) with angles (a2) and (a4) equal to 22.5° and -30° to the vertical respectively and where the driving for the seasonal or daily angle change for tracking the Sun and the maximization of the degree of concentration is done by rotating each set of permanently connected elements about the Rotation Axis (10g), i.e. the Mirror (A.1.1) and the Mirror (A.1.1a) with the System (A.2) or the System (A.3), in packages of one or two or three or even more repetitions of the above set through the Support and Slope Change System (A.1.2a), with passage of the Fluid (2.3. b) parallel to the Axis ( 10 g ), where the Support and Tilt Change System (A.1.2a), is characterized by the fact that it consists of the Push-Pull Half Ring (13c), the Push-Pull Rear Beam (11a), the Rotation Axis (10g), the Arms Parallel Slope (10th) and the Coupling Beam (14a), all made indicatively of aluminum profiles or hollow beams and the Linear Motor Mechanism (14a), which through the Electrical Panel (15) and a suitable Sun Monitoring System (16), gives the movement and driving to change the inclination of all the permanently connected elements, i.e. the Mirror (A.1.1) and the Mirror (A.1.1a) with the System (A.2) or the System (A.3) in packages as above. 8. A Solar System (A) as in Claims 1, 2, 3, 4, 5, 6 and 7, but characterized by the fact that the Support Surface (22) of the permanently connected elements, i.e. the Mirror (A.1.1) and of the Mirror (A.1.1a) with the System (A.2) or the System (A.3) in packages as above is characterized by the fact that it consists of a Single Formed Sheet / Vessels (23) of thin sheet steel or aluminum or from Mirrored Stainless Steel Wire (25) or from Mirrored Aluminum Wire (26), which replace both the Mirror (A.1.1) and the Mirror (A.1.1a), in packages of indicative dimensions of 1.0x2.0 meters, which carry a Peripheral Support Frame (24) made of aluminum profile or steel hollow beam, where the Single Formed Plate / Vessels (23) is also the rear Heat Dissipation Surface (A.2.6a) of the PV Generators (A.2.1) or (A.2.1a)„ which is characterized by constituting a heat dissipation surface with an area approximately 12 times the area of the corresponding PV Generator (A.2.1) or (A.2.1a)„ with four times the capacity to dissipate the heat emitted by three times the incident solar radiation, thus creating even lower operating temperatures compared to simple PV generators operating under one sun. 9. A Solar System (A) as in Claim 1, 2, 3, 4, 5, 6, 7 and 8, but characterized in that the Support and Tilt Change System (A.1.2) apart from the Linear Motor Mechanism (14a), the Electrical Panel (15) and the Sun Monitoring System (16) also has a rotation system around an Axis perpendicular to the level of the Solar System (A) for full tracking of the Sun, where with an appropriate change of its orientation and inclination Mirror (A.1.1) maximizes the degree of concentration on System A.2 or A.3. 10. A Solar System (A) as in Claims 1, 2, 3, 4, 5, 6, 7, 8 and 9, which is however characterized by the fact that in the empty space next to the respective PV Generators (A.2.1 ) or (A.2.1a), carries the Double Wall Vacuum Tube Solar Collectors (A.2.1b") and (A.2.1c") respectively, which are characterized by the fact that the rear single or double parabolic reflection surface behind each Vacuum Tube, respectively, is created from the Mirrored Stainless Steel Sheet (25) or from the Mirrored Aluminum sheet (26) respectively and with a width indicatively equal to the width of the PV Generators (A.2.1) or (A.2.1a) ).