• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Fixed focus solar collector with receiver modules that describes an oval, parabolic collector, with a dimension between 45 and 150 centimeters, for capturing solar energy and subsequent use through receiver modules, characterized in that it is biaxial, towable, with support structure, height mobile arm, parabolic module and receiver modules. The structure supports a fluid reservoir, a control desk and the receiver modules. The height arm is motorized driven by a telescopic cylinder. The azimuth arm, also motorized, supports an off-center parabolic screen, a solar panel, a tracker and a counterweight. The incident rays are oriented, permanently and automatically, on the focus, coinciding with the intersection of the height axis and the azimuth axis. The parabolic, covered with chrome effect, aluminum sheets, silver or similar. Heat resistant glass flask type receiver modules or metal heater. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2779173A1
    申请号:ES201900019
    申请日:2019-02-12
    公开日:2020-08-13
    发明作者:Fernandez Blai Llisterri
    申请人:Llisterri Fernandez Isabel;
    IPC主号:
    专利说明:

    [0002] SOLAR FIXED FOCUS COLLECTOR WITH RECEIVER MODULES
    [0004] TECHNICAL OBJECT OF THE INVENTION
    [0005] The present invention refers to a high-performance solar collector that captures the sun's rays by means of a parabolic screen known as "off-center" with a reflective surface of the sun's rays that concentrates them at a point close to the parabolic receiver while maintaining said approach constantly because the device is complemented with a highly precise solar tracker.The collector of the invention is of the two-axis type, being mounted on a tubular structure equipped with wheels for its transfer to the most convenient place either manually or as a trailer.
    [0006] The invention includes receiver modules specially designed to optimally capture the heat energy from the sun, being able to be used for cooking or heating different products, edible or not, and also for various other purposes that will be discussed in this document.
    [0008] SECTOR OF THE TECHNIQUE TO WHICH THE INVENTION REFERS
    [0009] The invention falls within the Section of Mechanics, Lighting, Heating, of the International Patent Classification, Section of Lighting, Heat, Paragraph of Heating, Ventilation Stoves.
    [0010] From an industrial point of view, it affects the design and manufacture of devices and accessories for collecting solar energy with medium-sized mobile devices.
    [0012] BACKGROUND OF THE INVENTION
    [0014] Parabolic antennas have multiple applications in capturing energy. Their operation is based on the property of the parabola, either as a geometric line or as a surface of revolution generated by a parabola that rotates on its main axis. This property consists in that any ray of light or electromagnetic energy that falls on the parabola according to the direction of said axis, is reflected in the concave surface and takes a new direction that systematically passes through a point called the focus. This means that if the axis of Incidence on the parabola is oriented towards the sun, the energy received will be concentrated in the focus and when placing an element at that point, it will heat up very quickly and efficiently reaching very high temperatures.
    [0015] The indicated property can also be used in the opposite direction, that is, if we place an energy emitter of any type at the focal point, the corresponding radiations, after reflecting off the parabolic surface, are redirected parallel to the axis of incidence.
    [0016] Because of the above, parabolic antennas can be used as transmitting antennas or as receiving antennas. In transmitting parabolic antennas, the screen reflects the electromagnetic wave generated by a radiating device that is located in the focus and the wave fronts that it generates come out of this reflector in a more coherent way than in other types of antennas, while in receiving antennas, the parabolic screen concentrates the incident wave in its focus where a collector is located. Normally these antennas in microwave networks operate according to the so-called duplex system, that is, they transmit and receive simultaneously, being very suitable to be used at high frequencies in which high gains are achieved.
    [0017] For this reason, the use of satellite dishes is common in the following applications:
    [0018] • Communications satellites
    [0019] • Radar for military or meteorological use
    [0020] • Satellite television receivers
    [0021] • Radio links
    [0022] • Amateur radio stations
    [0023] • Space probes
    [0024] • Space probe tracking stations
    [0025] • Radio telescopes
    [0026] • Doppler sonar for wind measurements
    [0028] These are basic applications for electromagnetic waves, and there is also another series of applications for capturing solar energy, especially the one known as direct radiation that reaches us from the solar focus without intermediate reflections or refractions. Today this energy capture is promoted by all Administrations as it is a modality known as renewable. Spain, whose geographical and climatic characteristics are especially favorable for the capture of solar rays, registers a continuous process of development in this type of facilities. But there is also an important development around the world as evidenced by the large number of known antecedents of which we will cite some, by way of example, but emphasizing that there are many more.
    [0029] - ES-1042691 U Solar energy collector device
    [0030] - ES-1066600 U Mechanical solar tracker
    [0031] - ES-1068804 U Solar tracker on support pulley (two axes)
    [0032] - ES-1071346 U Solar tracker for solar collectors (two axes)
    [0033] - ES-1071347 U Solar tracker on lattice for solar collectors (two axes)
    [0034] - ES-1074127 U Thermal solar collector (two axes)
    [0035] - ES-2304113 A1 Two-axis circular solar tracker
    [0036] - ES-2332117 A1 Solar monitoring system for solar energy collectors - ES-2345078 A1 Structure for solar tracker and installation procedure - ES-2396078 B2 Device for collecting concentrated solar radiation - ES-2428616 T3 Solar collector
    [0037] - ES-2649141 T3 Refraction concentration solar tracker (two axes) It is observed that the Inventions focus on the one hand on solar radiation collectors and on the other on solar trackers
    [0038] However, the inventor does not know of any antecedent in which they are parabolic collectors governed by high precision trackers, supplemented with specific receiver modules, such as the one described here, with the particularity that it is a medium-sized device. , movable on wheels and towable, using collector screens of the “off-center” type, with the property of maintaining the energy concentration in a fixed focus thanks to the arrangement of its axes and follower mechanism. Its configuration is represented and described in the following sections of this document, considering the author that, in addition to the possibility of its industrial application, the idea meets the characteristics of novelty and inventive step required of them in these cases
    [0040] SUMMARY DESCRIPTION OF THE INVENTION
    [0041] The present invention, as explained in the introduction, refers to a solar collector with a fixed focus in space and high performance, with a medium-sized, oval-shaped parabolic screen collector, the largest dimension of which can range from 45 to 150 centimeters, movable on wheels and towable by any vehicle, with multiple uses, thanks to its special receptor modules, such as cooking food, baking, heating water, purification, sterilization, energy storage and other purposes.
    [0042] The device of the invention is composed of three main parts, corresponding to the solar collector:
    [0043] - Support structure
    [0044] - Mobile arm
    [0045] Parabolic screen module
    [0046] All this complemented with special receiver modules for the use of the energy received.
    [0047] The support structure is a tubular frame, equipped with wheels and towing hitch, where all the components of the device are located.Its upper part supports the receiver module, chosen in each case, matching the bulb it has with the spotlight convergence of the solar rays reflected by the parabolic screen that is treated with mirror coating. In the front part, more accessible, is the control desk for the Initial configuration and necessary adjustments.
    [0048] The mobile arm constitutes, in turn, the support for the parabolic screen module with the particularity that it rotates on the main structure around a horizontal axis. It consists of a part in the shape of a "U'1, at the upper ends of which are placed the joints that define the horizontal axis. In its lower part, a single curved bar begins that extends to the front of the general structure where the parabolic screen module sits.In the front third of this bar of the mobile arm there is a joint that receives the push of the telescopic device that allows to regulate, in a motorized way, what we will call the height angle
    [0049] Finally, the parabolic screen module is the one that includes the screen itself, the motor for its drive, a solar panel that, complemented by a battery of accumulators, has enough power to power all the actuators of the device, the capsule sensors and the balancing weight.
    [0050] All these elements allow an automatic operation of the collector with monitoring of sunlight for a very efficient use of the energy received which, through the use of specific receiver modules, is applied to the heating of products of all kinds, electrical applications and even to the accumulation of energy for use at night or when the sun is out. Explanatory figures of the device and a description of the preferred embodiment by its inventor are included in the following sections.
    [0052] BRIEF DESCRIPTION OF THE DRAWINGS
    [0053] Eight schematic figures are included to facilitate understanding of the invention without exhausting other solutions that involve small variations from the original idea.
    [0054] Figure 1
    [0055] It shows a perspective view of the solar collector of the Invention, the following elements having been indicated:
    [0056] 1.- Solar collector
    [0057] 2.- Support structure
    [0058] 3 - Crossbar
    [0059] 4. - Wheel
    [0060] 5. - Leg
    [0061] 6 - Plug
    [0062] 7.- Flask-type receiver module
    [0063] 8 - Control desk
    [0064] 9 - Fluid tank
    [0065] 10.- Fluid conduit
    [0066] 11- Height movable arm
    [0067] 12 - Height axis
    [0068] 13.- Cartouche
    [0069] 14 - Parabolic screen
    [0070] 15. - Mobile azimuth arm
    [0071] 16. - Azimuth motor group
    [0072] 17 - Parabolic support
    [0073] 18 - Solar panel
    [0074] 19 - Sensor capsule
    [0075] 20. - Counterweight
    [0076] 21. - Azimuth axis
    [0077] 22- Focus
    [0078] 23 - Height motor group
    [0079] 24. - Telescopic height
    [0081] Figure 2
    [0082] It shows a side view of the solar collector indicating the same elements of the previous figure.
    [0083] 25. - Angle "a"
    [0084] 26. - Solar rays
    [0086] Figure 3
    [0087] It shows the same front side view of the solar collector in which the height mobile arm has been acted upon with the consequent impact on all the components with a rotation around the height axis. The angle "a" has decreased
    [0088] Figures 4 and 5
    [0089] Here the solar collector is shown in front and side views in a position in which the azimuth motor group has moved the azimuth mobile arm with the parabolic screen and other associated elements, causing a rotation of an angle close to 90 degrees on the azimuth axis.
    [0090] 27.- Angle "p"
    [0092] Figure 6
    [0093] Represents the detail of the flask-type receiver module and that has been shown in (Figs. 1 and 2).
    [0094] 28- Cover
    [0095] 29. - Mesh
    [0096] 30. - Flange and fastening means
    [0098] Figures 7 and 8
    [0099] These figures show the side view (Fig 7) and the top view (Fig 8) of the heater receiver module.
    [0100] 31. - Heater type receiver module
    [0101] 32- Diffuser
    [0102] 32.1.- Capture bulb
    [0103] 33. - Insulating coating
    [0104] 34. - Transparent dome
    [0106] DETAILED EXPLANATION OF A MODE OF EMBODIMENT OF THE INVENTION
    [0107] Fixed focus solar collector with receiver modules (1) (Figs. 1 to 8) that describes a high-performance collector, with a parabolic screen collector, with a diameter between 45 and 150 centimeters, movable on wheels and towable with, at the less, a flask-type receiver module and a heating receiver module, for multiple applications such as heating or cooking food, fluid heating, baking, purification, sterilization, transformation and accumulation of energy and other similar purposes.
    [0108] In a preferred embodiment by its inventor, the solar collector (1) comprises, as main elements, a support structure (2), a height movable arm (11) and the parabolic screen module (Fig 1) that They are complemented by receiver modules where the received solar energy is concentrated
    [0109] The support structure (2) is tubular with two curved bars in the shape of a "C" that are joined together, forming a single body, by means of several transverse bars (3). In the The lower part has a pair of pneumatic wheels (4) and two legs (5), which guarantee a good seat on the ground in the working position and allow easy movement of the assembly in manual movements or in trailer mode, by any vehicle, when, with a slight inclination to raise the legs (5), it rests only on the wheels (4). A tow bar is available (not shown).
    [0110] The upper part of the support structure (2) also serves to support the different receiver modules since, in its front part, it is where the focus (22) is located, a fixed point in space, where the solar rays converge (26) reflected by the parabolic screen of the solar collector (1) of the invention. This is reflected in (Fig. 1) where, for clarity, the installation of the flask-type receiver module (7) has been represented, and it can be seen that the geometric center of the spherical surface of the flask is located precisely at the focus (22) , where the two main axes of the solar collector (1) intersect, which are the height axis (12) and the azimuth axis (21).
    [0111] At mid-height, in a place that is comfortable and accessible, the control desk (8) is located from where the different parameters of the device and other usual details for the correct adjustment of these devices are initially configured. In the lower position of the control desk (8), a fluid reservoir (9) is located, supported on the support structure (2), the tubes of which house the fluid conduits (10) that, reaching the The upper part of said tubes are connected, when necessary, to the aforementioned flask-type receiver module (7), positioned in the focus (22), in order to have hot fluid with circulation activated by a minipump (not shown).
    [0112] In the mobile height arm (11) two characteristic sections are distinguished; an upper one in the shape of a "U" and a lower one, arched, which begins at the lowest part of the "U" and extends forward to the front of the device. This mobile height arm (11) is related to the support structure (2) by means of the height axis (12), which is articulated at the upper edge of said structure. The rotational movements on the height axis (12) are achieved by the action of the height motor group (23), which drives the height telescopic cylinder (24), one of whose ends is attached to one of the transverse bars (3), close to the axis of the wheels and the other end, in the bracket (13), integral with the mobile height arm (11), in the front third of said arm. The position of this arm is defined by the angle "a" (25), as can be seen in (Figs 2 and 3).
    [0113] As for the module of the parabolic screen, another of the fundamental parts of the device of the invention, it is composed of an oval parabolic screen (14), which depending on the models, has its largest dimension between 45 and 150 centimeters and with the characteristic main of being a parabolic screen of the calls "out of center" since It is built and installed in such a way that the focus (22) for concentrating the solar rays (26), reflected, is located, in space, at the intersection of the height axis (12) with the azimuth axis (21) (Fig. 1). Its active, reflective part is technically treated with projection of one or more layers of chrome effect, although it can also be those covered with aluminum, silver or similar reflective solution.
    [0114] In addition to this fundamental piece, the parabolic screen module has the mobile azimuth arm (15), the azimuth motor group (16), the parabolic support (17), a solar panel (18), complemented with a battery accumulators, a sensor capsule (19) of at least four cells and a counterweight (20).
    [0115] The azimuth mobile arm (15) sits on the front end of the height mobile arm (11), by means of the azimuth motor group (16), having at the other end the parabolic support (17), which is it is connected to the parabolic screen (14). The position of this arm is defined by the angle “(3” (27) (Fig. 4) which, in the case represented, is close to ninety sexagesimal degrees
    [0116] Figures (Figs. 2 to 5) show some of the different possible positions in this two-axis collector in its solar tracking process.
    [0117] The solar panel (18) captures light energy with the necessary power for the correct operation of actuators and other consumption centers, being complemented with a battery of accumulators (not represented).
    [0118] The sensor capsule (19) is also a fundamental part of the solar collector (1) of the invention. It is equipped with a minimum of four cells that guarantee perfect tracking of the sun on its path
    [0119] Finally, the counterweight (20) is positioned to achieve a good balance of all the moving components.
    [0120] As it is a tubular structure that must work in the open, subjected to inclement weather, all tube ends are protected with plugs (6) that also prevent the entry of insects and other animals.
    [0121] With this arrangement of the different components described, it is understood that any movement of the height mobile arm (11) affects the height movement of all the components of the parabolic screen module (14) and any movement of the axis of the motor group of azimuth (16) involves the rotation of the parabolic screen (14), the solar panel (18), the sensor capsule (19) and the counterweight (20).
    [0122] It is, therefore, a solar collector (1), with two axes, which is prepared to make a very precise follow-up of the sun in its path, directly receiving the solar rays (26) and redirecting them towards the focus (22) that is located 'Off center1'. By matching the focus (22) of the parabolic screen (14) and the intersection of the height axis (12) with the azimuth axis (21), a stable energy concentration point is achieved in space, which is where the receiver modules are placed, properly centered.
    [0124] Receiver modules
    [0125] The main receiver modules envisaged by the Inventor are those represented in (Figs.
    [0126] 6, 7 and 8).
    [0127] In (Fig. 7) the flask-type receiver module (7) is shown, the shape of which responds to a spherical container, made of heat-resistant glass material, topped by a cylindrical neck, with lid (28), crossed by the conduits of fluid (10) that, connected to the fluid reservoir (9) or any other reservoir, penetrate into the interior of the flask previously filled, in part, with stainless mesh (29), black in color, to favor the capture of radiation.
    [0128] Its optimal positioning is when the geometric center of the sphere is made to coincide with the focus (22) for which a flange (30) is provided with support means on the support structure (2).
    [0129] In (Figs. 7 and 8) the heater-type receiver module (31) is shown, the shape of which responds to a thick, circular metal plate, which works as a diffuser (32), in whose lower part, in an off-centered position, it presents the pick-up bulb (32 1). The heater type receiver module (31) is lined with an insulating coating (33) and the collector bulb (32.1) is covered with a transparent dome (34)
    [0130] Its optimal positioning is when the pick-up bulb (32.1) is centered in the focus (22) for which the aforementioned module rests on the support structure (2) using any means.
    [0131] The heat energy received by the collector bulb (32.1) is transmitted, by direct conduction, to the diffuser (32) and from there, to any element that is placed on top which, for example, may be a Stlrling-type heat engine.
    [0132] o o o o o
    [0133] In summary, it is understood that the fixed focus solar collector with receiver modules (1) of the Invention is a high performance energy harvesting device in which temperatures that exceed 1000 degrees Celsius are achieved allowing multiple objectives such as heating of fluids, food cooking, baking, purification, sterilization, transformation of heat energy into electrical energy (which can be accumulated in batteries for later use), cold generation, food drying, canning and other similar purposes, with the advantage of be a device on wheels, towable by any vehicle and very suitable for use in isolated areas, country houses, motorhomes and even in urban areas where you can carry out your installation inside homes or premises so that, using rails, the collector can be moved outside through a window. It can also be installed in gardens, balconies or on the terraces of buildings.
    [0135] Collector configuration
    [0136] For the initial adjustment of the collector of the invention, the following steps are followed:
    [0137] 1.- Orientation of the support structure (2) with the height axis (12) from East to West balancing it so that it is horizontal with the height mobile arm (11) oriented:
    [0138] a) towards the south or north depending on the position of the sun at noon if we are between the tropics
    [0139] b) to the south in the rest of the northern hemisphere
    [0140] c) to the north in the rest of the southern hemisphere
    [0141] 2- The height movable arm (11) is inclined on the height axis (12) until the azimuth axis (21) is perpendicular to the sun's rays (26) at solar noon, on that day and in that place (variable throughout the year according to the movement of the Earth, as it follows the sun), that is, parallel to the axis of apparent solar movement (axis of the ecliptic).
    [0142] 3.- The module of the parabolic screen is rotated on the azimuth axis (21) until the parabolic screen (14) is oriented towards the sun.
    [0143] Once these actions are carried out, the solar rays (26) are concentrated in the focus (22) of the parabolic screen (14) which, as previously indicated, on several occasions, coincides with the intersection of the height axis (12) with the azimuth axis (21).
    [0144] An important characteristic of the solar collector of the invention is that in a first configuration phase, the height is adjusted and the subsequent azimuthal tracking is automatic unlike other existing models in which it is first focused towards the sun and then heights are given. in successive adjustments.
    [0145] However, this does not preclude manual operation when deemed appropriate.
    [0146] It is not considered necessary to make the content of this description more extensive so that an expert in the field can understand the scope and advantages derived from the invention, as well as develop and put into practice its object. However, it should be understood that the invention has been described according to a preferred embodiment thereof, so that it may be susceptible to modifications without affecting or implying any alteration of the foundation of said invention. That is to say, the terms in which this preferred description of the invention has been set forth should always be taken broadly and not limitatively.
    权利要求:
    Claims (8)
    [1]
    1. - Fixed focus solar collector with receiver modules (1) that describes a high-performance collector, with an oval-shaped parabolic screen collector, whose largest dimension is between 45 and 150 centimeters, intended for the collection of solar energy for further use by means of receiver modules, characterized in that, being of the two-axis type, it comprises a support structure, a movable arm in height, a parabolic screen module and receiver modules.
    The support structure (2) is tubular, with two curved bars in the shape of a "C", joined together by several transverse bars (3), having, in its lower part, a pair of wheels (4) and legs (5 ), a fluid reservoir (9) and a control desk (8), the tubular ends of the support structure (2) being closed by plugs (6), the upper part of said structure being the one intended to support the Receiver modules that are preferably of the flask type (7), in the shape of a sphere, with a cylindrical neck and lid (28) crossed by two fluid conduits (10) or of the heater type (31), in the form of a flat metal plate , circular, with a diffuser (32) and a bulb (32.1) in its lower part.
    The mobile height arm (11) is made up of an upper section in the shape of a "U" and a lower section, arched, which begins at the lowest part of the "LT and extends forward to the front of the device. which is related to the support structure (2), for rotation purposes, by means of a height axis (12) located on the upper edge of said structure and for movement purposes, through the action of a height motor group ( 23), which drives a height telescopic cylinder (24), the ends of which sit on one of the transverse bars (3), close to the axle of the wheels and on a bracket (13), secured to the height mobile arm ( 11), in the front third of said arm.
    The parabolic screen module is made up of an oval parabolic screen (14) that, through the parabolic support (17), is connected to the mobile azimuth arm (15), driven by an azimuth motor group (16 ), also supporting said movable azimuth arm (15), a solar panel (18), a sensor capsule (19) and a counterweight (20).
    [2]
    2. - Fixed focus solar collector with receiver modules, according to claim 1, characterized in that the parabolic screen (14) is of the type known technically as "off-center", capturing the solar rays (26) and redirecting them towards the focus ( 22), located at the intersection of the height axis (12) with the azimuth axis (21), whose intersection defines a fixed point in space
    [3]
    3. - Fixed focus solar collector with receiver modules, according to the first and second claims, characterized in that the parabolic screen (14) is preferably one of which its active side has been technically treated with projection of one or more effect layers chrome, although it can also be coated with aluminum foil, silver or a similar reflective solution.
    [4]
    4 . - Fixed focus solar collector with receiver modules, according to claim one, characterized in that the solar panel (18), complemented with a battery of accumulators, feeds all the actuators and electrical devices of the device.
    [5]
    5. - Fixed focus solar collector with receiver modules, according to claim one, characterized in that, once the height axis (12) has been adjusted, it has an automatic movement, governed by the solar tracker formed by a sensor capsule (19) of at least four cells and the control desk (8).
    [6]
    6. Fixed focus solar collector with receiver modules, according to claim 1, characterized in that the support structure (2), with its wheels (4), which are pneumatic, has a tow bar (not shown).
    [7]
    7 . - Fixed focus solar collector with receiver modules, according to claim one, characterized in that the flask-type receiver module (7) contains stainless mesh (29), black in color and is made of transparent heat-resistant glass
    [8]
    8. - Fixed focus solar collector with receiver modules, according to claim one, characterized in that the receiver module type heater (31), has the diffuser (32) lined with an insulating coating (33) and the bulb (34), in position off-center, it is surrounded by a transparent dome (34) of heat-resistant glass.
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    同族专利:
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    WO2020165471A1|2020-08-20|
    ES2779173B2|2021-02-26|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4195775A|1977-04-18|1980-04-01|Pitts Edward T|Solar energy system|
    US4979494A|1989-09-29|1990-12-25|Andersen John I|Method and apparatus for generating thermal energy|
    CN201041419Y|2007-05-23|2008-03-26|丰日电气集团股份有限公司|Multifunctional automatic solar stove|
    US20140251308A1|2013-03-05|2014-09-11|Frank Stephen Wyle|System and Method for Collecting Solar Energy with a Stationary Thermal Storage Device|
    CN105352200A|2014-08-18|2016-02-24|侯阳|Small focus-fixed solar cooker|
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    PCT/ES2020/000010| WO2020165471A1|2019-02-12|2020-02-10|Fixed-focus solar collector with receiver modules|
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