BRPI1003656A2 - Stable aerostat platform and energy-efficient data transmission system obtained from thin-film photovoltaic panel - Google Patents

Abstract

Stable aerostat platform and energy-efficient data transmission system achieved through thin-film photovoltaic panel. The present invention relates to a device for establishing remote wireless data connections by employing a platform comprising: an aerostat (2) supporting a thin-film photovoltaic panel (1) and an integrated electronic module ( 4). The aerostat that makes up the invention has aerodynamics that keep it in a high and stable position even in the event of high winds, allowing wireless data connections to maintain the ideal direct sight situation. The integrated electronics module consists of radio transmitting systems (7 and 9), radiating systems (6 and 10), packet router (8), charge controller (12) and rechargeable battery (13). The compactness level of this module is sufficient for it to have a weight compatible with the aerostat's carrying capacity and for its energy consumption to require a photovoltaic panel with adequate weight and size for platform operation. When disassembled, the present invention has a total weight of less than 1kg to allow for easy storage and transport. The installation and operation of the platform do not require the existence of any civil or electrical infrastructure, allowing its use in remote locations and in temporary or emergency installations.

Description

Disclosure Report of Patent Application "Platform composed of stable aerostat and energy-efficient data transmission system obtained by thin-film photovoltaic panel".

The present invention relates to a device intended for

establishing wireless remote data connections by employing an airship supporting radio transmitters, radiating systems, packet router, charge controller, rechargeable battery and thin film photovoltaic panel. The quality and range of wireless data connections

between two points depend basically on the transmission power used, the frequencies used, the irradiation pattern of the radiating systems and the losses obtained by absorption, diffraction and reflection due to the obstacles existing between the two points considered. Connection technologies for

wireless, point-to-point, and point-to-multipoint data, such as Personal Mobile System (SMP) second- and third-generation cellular systems and WiFi systems employing unlicensed bands of the spectrum. These technologies operate with powers, frequencies and sets of transmitters, cables and antennas that allow connections to links up to a few tens of kilometers under optimal propagation conditions.

Among the ideal conditions of propagation is of paramount importance the existence of direct sight between the radiating systems of the link, respecting the limits distances of Fresnel Zones considering the location of obstacles and the effect of the curvature of the planet. Thus there is a lower limit to the height above ground where the radiating systems of the connected points are installed for optimal propagation.

Calculating the minimum height limits of radiating systems is particularly important in designs that employ metal poles or towers to support the antennas and cables that connect them to transmission equipment. As the costs involved in setting up each metal pole or tower are directly related to its height in relation to the. the ground and the supported weight of the installed equipment, the optimal tower design should be sufficient only to ensure that the lower weight and height limits for optimal propagation are respected.

Another factor that drives the installation of radiating systems at the minimum recommended height is the intrinsic attenuation of the 40 radio frequency cables connecting the radiating systems to the transmission equipment, usually installed at ground level. There is a direct relationship between the length of the radio frequency cable and its attenuation, which results in the loss of transmission power of the radiating systems. To minimize this loss there are different cable specifications, with the cables being relatively heavier and at higher cost attenuation.

Another solution for minimizing cable attenuation is to install transmission equipment as close as possible to radiating systems. In the extreme, transmission equipment can be bundled together with the radiating systems and installed on top of the towers. In this way the attenuation of the radio frequency cables is minimal. At the same time the weight of the cables, which should be supported by the tower, is replaced by the weight of the power transmission, routing, cooling, conversion and storage equipment as well as the power cables that feed them.

For locations where commercial electrical power is not available for equipment power, photovoltaic panels, charge controllers and battery banks are generally employed. This technology is chosen for its high availability most days throughout the year. Traditional photovoltaic panel technologies employ rigid monocrystalline or polycrystalline crystal panels, with exposure areas dependent on the amount of energy required by the equipment and average local insolation. The set of panels with the rectifiers and the batteries usually have a total weight of tens of kilograms, even for a consumption of a few tens of watts.

Although the above is a current reality and is reasonably cost-effective in terms of permanent data connection installations in urban environments, it has limited application in remote regions or temporary installations.

The logistical challenges of transporting, deploying manpower for installing and maintaining metal towers in remote regions are often accompanied by prohibitive costs that make most terrestrial link data connection projects unfeasible. The traditional way out of these cases is to use systems with satellite connection, with relatively simpler and cheaper installation, but with usage costs of more than 10 times the costs of using urban land links under the same conditions of speed, traffic volume. and quality of service.

Similarly, the complexity and cost associated with building metal poles or towers is not feasible for data connection to temporary facilities such as roaming utilities, natural disaster relief services, live radio and television broadcasts, exhibitions. rural areas and scientific expedition facilities.

In view of the scenarios presented above, it is an object of the present invention to provide a platform with the following objectives:

/) Establishment of data connection independent of the available infrastructure of towers or buildings to support antennas; //) Establishment of data connection independent of available commercial electric power infrastructure;

/ 77) Allow easy storage and transport due to the small size of the disassembled equipment and airship, comparable to that of a laptop, and weighing less than 1 kg in total;

iv) Allow quick and easy installation by directly attaching electronic equipment, radiating systems and the photovoltaic panel to the aerostat, which must also be easily assembled and inflated

with helium gas;

v) Maintain the stability of the connection even in the event of strong winds;

vi) Maintain the energy autonomy of the system even in the absence of solar energy for a few hours;

vii) Employ transmission, routing and

radiant systems with minimal weight and energy consumption;

v / 77) Employing flexible photovoltaic panel technology

minimum weight;

ix) Offer a solution with a significantly lower deployment cost than the solutions currently employed.

Success in fully meeting the stated set of objectives largely depends on the result obtained by the invention with respect to objective vii. By compacting the electronics and integrating the different functional elements into a single integrated electronics module - including transmitters, router, radiating systems, battery charge control system and rechargeable battery itself - it is possible to employ a solution weighing less than 200 grams and average consumption less than 5 watts.

Following the philosophy of weight minimization, a photovoltaic panel composed of cells constructed on thin film is employed, as described in the commercially available patent technology CN201045738. To meet the consumption of the integrated electronic module, it is possible to employ a flexible panel with an area of less than 0.5 m2, with a thickness of less than 1 mm and a weight of less than 100 grams. Using this photovoltaic panel model, objectives //, iv, vi and viii are successfully met.

The photovoltaic panel is fixed to the aerostat by means of elastic fibers at defined connection points so that the panel is always positioned at the top of the platform to receive direct solar radiation. 40 The fundamental component for meeting the

The other objectives are the stable airship. The device in question relates to the product treated in GB2280381. Unlike conventional helium balloons, the aerostat in question has aerodynamics that keep it in a high and stable position even in the event of high winds. This situation is fundamental for data transmission links to maintain the direct sight condition at any time condition, meeting the objectives '' and v.

The aerostat sized for a payload of 300 grams, considering the electronic equipment and the photovoltaic panel, must have a volume of at least 1.5 m3 to support even in the absence of wind. The aerostat built in these dimensions with durable and waterproof material weighs about 650 g and can be folded to the approximate size of an A4 sheet about 3 cm thick. Thus, the Hi target is fully met as the total weight of the platform referred to in the present invention is estimated to be about 950g.

Since the transmission between ground-based data equipment and the platform is via radio link and the platform power is fully autonomous via solar energy, it is not necessary to use metal or fiber optic cables for connection. from the platform to the ground. This feature allows for a large reduction in sizing and overall cost of the invention as the weight of cables operating at a height of a few tens of meters would require a much larger airship. Thus, the present invention employs ties with polyethylene fibers having a good compromise between weight and strength.

From the set of components described above it is possible to calculate the total cost of this solution, which allows operation at any time up to 100 m above ground, and to compare it with the typical costs of conventional tower-based equipment.

Under current market conditions, the cost of implementing the present invention is equivalent to the cost of pole or tower based equipment up to 10 m high. Above that height, the cost of the conventional solution increases exponentially with the demanded height, while the cost of the present invention remains constant, finally meeting objective ix.

The invention will now be described with reference to the accompanying drawings in which:

Figure 1 illustrates the composition and physical positioning of the elements comprising the present invention. The photovoltaic panel (1) attaches directly to the aerostat (2) and connects to the integrated electronics module (4) via the power supply cable (3). The integrated electronic module (4) is attached to the lower spark plug of the aerostat (2), where the tie (5) which is fixed to the ground is also attached. 40 Figure 2 illustrates the logical connection of components.

electrical and electronic systems of the integrated electronic module. The omnidirectional radiating system (6) is responsible for amplifying and directing the signal received from the transmitting modem / radio (7) to the long distance transmission link. The packet router 8 controls traffic between the long-distance transmission link and the local transmission link. The local transmitting modem / radio (9) connects to the local radiating system (10) which is directed directly to the ground.

In parallel to the routing and data transmission system, the power supply, control and storage system operates. When illuminated by sunlight, the photovoltaic panel (11) generates enough direct current electrical power to power the elements of the integrated electronics module and to recharge the system battery (13). Control of the power intended for the electronic systems from the photovoltaic panel or battery and the recharge operation of the battery are functions of the charge controller system (12).

Figure 3 illustrates in a simplified manner the radiation diagram of the radiating systems cited in Figure 2 for interconnecting ground operating data equipment to a remote network by means of the present invention. The platform (14) is represented in operation and is supported by its lashing (17) attached to an attachment point (18) on the ground. The radiation diagram for long-distance connection (15) represents, in two dimensions, a spherical section with angular opening dependent on the omnidirectional radiating system employed. The greater the gain of this radiating system, the smaller the angular aperture of the irradiation, and vice versa. Thus, the gain limit to be. employed in this system depends on the varying angular position of the platform, which ultimately depends on the stability of the aerostat. Since this radiant system is omnidirectional, the orientation of the platform with respect to the cardinal points is irrelevant to the perfect functioning of the present invention.

The local radiation diagram (16) represents a cone with angular opening dependent on the directional radiating system employed. The angular opening must be greater than the angular variation of the aerostat bearing axis so that the transmission link between the ground equipment and the platform is not interrupted.

Claims (7)

1. A device for the establishment of wireless data connections using a lighter-than-air platform, characterized in that it consists of an airship (2) equipped with radio transmitters (7 and 9), radiant systems. (6 and 10), packet router (8), charge controller (12), rechargeable battery (13) and photovoltaic panel (11); 2. A device for establishing wireless data connections using a lighter-than-air platform as claimed in claim 1, characterized in that the aerostat (2) has aerodynamic stability that maintains it at a suitable altitude and at a low level. oscillating even in the presence of strong winds; Device for establishing wireless data connections using a lighter-than-air platform as claimed in claim 1, characterized in that the platform has energy self-sufficiency by means of a thin-film photovoltaic panel (11). ), charge controller (12) and rechargeable battery (13), dispensing with the use of power cables connecting the platform to a ground power system; Device for establishing wireless data connections using a lighter-than-air platform as claimed in claim 1, characterized in that the platform is easily carried, stored and installed in any environment, regardless of the existence of any civil or electrical infrastructure; 5. A device for establishing wireless data connections using a lighter-than-air platform as claimed in claim 1, having radio transmitter systems (7 and 9), radiant systems (6 and 10), packet router (8), charge controller (12) and rechargeable battery (13) packed into a single integrated electronics module (4); 6. A device for establishing wireless data connections employing a lighter-than-air platform as claimed in claim 1, characterized in that the platform connects to ground equipment via wireless data link without the need for the need for data transmission cables for connection between the platform and ground equipment; 7. A device for establishing wireless data connections employing a lighter-than-air platform as claimed in claim 1, having omni-directional radiating systems which are independent of the platform's orientation to the cardinal points. for establishing transmission links with long distance systems.