IT202100024038A1 - “Lamellar module for 5G technology” - Google Patents

Description

Patent Application for Industrial Invention entitled:

?Lamellar module for 5G technology?

The present invention finds application in the field of systems for masking antenna systems of radio base stations (RBS) or in systems for camouflaging the antennas of mobile telephone systems which receive and retransmit the signals of cellular telephones, allowing them to function.

The propagation of mobile phone signals occurs in different frequency bands, between 700 and 3700 MHz, depending on the technological system used.

A radio base station (SRB) of a given operator has one or more? technological systems (GSM, HSDPA WCDMA, LTE FDD-LTE, 4G, 5G) and therefore operates within different assigned frequency ranges in transmission and reception, called services.

The various services are conveyed by one, two or more? frequently three antennas, called sectors, differently oriented in space in order to guarantee service coverage in the surrounding area.

Traditional RBS antennas are generally mounted on masts or poles, installed on the ground, or on masts fixed to the roof of buildings.

The installation of fixed systems for cellular telephony requires, for visual and environmental reasons, that the relative antenna systems are camouflaged so to reduce its visual and environmental impact.

These camouflages have different shapes, dimensions and aesthetic characteristics according to the geometry of the radiant system to be camouflaged, its modality? of installation on the roof (roof top) or in the open field (raw land) and of the visual result that we intend to pursue globally.

In most cases, the camouflage masking appears as a parallelepiped, a prism or a cylinder whose shape recalls that of the existing chimneys on the surrounding roofs, or advertising totems, business signs.

commercial or other similar architectural elements.

The masking? generally made up of paneling with flat or curved faces depending on the geometry to be created, structurally fixed, by means of steel components, to the central load-bearing element which supports the radiant system to be concealed.

The paneling used for this purpose must satisfy, in addition to the aesthetic and mechanical resistance requirements, the precise requirements of transparency to the electromagnetic signal dictated by the network operators, as well as have adequate resistance to high temperatures and fire and a more than ten-year resistance to bad weather.

The characteristic of radio transparency, which constitutes the fundamental element of masking panels, is profoundly influenced by multiple factors such as the frequency of electromagnetic waves.

With the new 5G transmission system for telephony, characterized by performance and speed? superior compared to previous technologies, the current panels that make up the masking systems are no longer? sufficiently radiolucent and are, therefore, inadequate for higher frequencies.

At present, there are no solutions with rigid masking panels that are able to meet the requirements of the current 5G technology, i.e. the requirements of radio transparency, mechanical strength, safety at high temperatures and durability. for exposure to the weather.

The main purpose of the present invention ? that of providing a masking module made up of lamellar, rigid and flat panels, which are transparent to the 5G signal and which are able to allow effective ventilation inside the module, avoiding thermal overload.

The distance between the slats 18 of about 11 cm (range between 7 cm and 15 cm) allows in fact to achieve, besides the degree of radio transparency prescribed by the specifications of the different operators, effective ventilation inside the module with the consequent dissipation of the heat generated by the radiant systems.

Its structure, what? as conceived, combines the pi? high standards of durability for exposure to bad weather with a very high mechanical resistance, to high temperatures and fire.

Another purpose of the present invention ? that of creating a panel made entirely of fiberglass, composed of a succession of parallel slats arranged horizontally and of variable thickness.

The inclination of the slats in the plane of the cross section can? vary to adapt to the tilting characteristics of the antennas, so that the blades themselves are parallel to the direction of radiation, minimizing the resistance opposed to signal propagation.

This and other aims, as will better appear from the following description, are achieved by the new object of the present invention which is described below, in a preferred non-limiting embodiment of further developments within the scope of the invention, both in terms of graphics and in operation , with the help of the attached drawing tables illustrating the following figures:

Fig. 1 Exploded view of the lamellar module;

Fig. 2 Hooking system of the module to the collars;

Fig. 3 A detail of the reinforcement system mounted on the panel;

Fig. 4 Lamellar module in maintenance position;

Fig. 5 Detail of the panel with circular profiles;

Fig. 6 Assembling the fire system;

fig. 7 Antenna mast and section of the module mounted therein; Fig. 8 Example of module mounted on the mast post;

Fig. 9 Different perspective of the module mounted on the mast post; Fig. 10 Sections of the cylindrical lamellar module and detail of the bird barrier;

Fig. 11 Cylindrical panel module;

Fig. 12 Detail of the covering system of the cylindrical module;

Fig. 13 Antenna mast and section of the cylindrical module mounted therein;

Fig. 14 Example of cylindrical module mounted on the mast post; Fig. 15 Different perspective of the cylindrical module mounted on the mast.

With reference to figure one, the masking module, indicated as a whole with the reference number 1, comprises a first element consisting of a paneling, preferably rectangular in shape, made up of panels 2 entirely made of fibreglass, connected and constrained to each other at two by two, by means of an upper collar 15 and a lower collar 4 and fixed to the antenna mast 5 by means of bolted metal components positioned at the ends? upper and lower ribs 6 pi? outside of each panel. Adjacent to the slats? positioned a radiolucent flap 16, which allows the acquisition of the 5G signal, bound to the paneling by means of reinforcements 14.

The parallel slats 3, arranged horizontally and having a variable thickness in a range of 3 / 8 mm, are mutually constrained by means of vertical ribs 6 suitably carved to house the slats themselves. The slats 3 can also? be mutually constrained by means of circular profiles 19 having a variable diameter in a range of 15/50 mm and passing through said slats 3.

The number of vertical ribs - of variable thickness in a range of 7/15 mm? and/or the number of circular profiles varies from two to three according to the width of the panel.

The horizontal blades 3 and the vertical ribs 6 and/or the circular profiles 19 have, on the inner side 7 facing the 5G antennas, a tapering 8 along their entire length, suitable for optimizing their behavior with respect to the frequency signal in use. According to the invention, one of the panels 2 of the module 1, equipped with retainers 9 which guarantee its closure, is laterally hinged in order to allow access to the internal radiant system for the activities? of maintenance.

Above the module pu? be closed with a flat or shaped covering element 10, for example with a pyramidal or truncated cone shape, having on the external side a hooking system 11 for pulling the product to a height.

The covering element 10 allows the housing and subsequent maintenance of a fire-fighting system 17 with automatic extinguisher for fire class A B C with sprinkler valve equipped with a bulb calibrated at 68? C or 93? C suitable for electronic devices (fire alarm system).

The lamellar module 1, deprived of the covering element, can? be fixed at a distance of three meters or at an intermediate distance of two meters, below the apex of the mast.

In a second run, the masking module ? consisting of a cylindrical paneling 13 entirely made of fiberglass, whose parallel blades 3, arranged horizontally, have the shape of a semicircle.

In the internal part of the module with panels of rectangular and/or cylindrical shape, ? the fixing of a barrier 12 is foreseen which has the purpose of preventing the parking, inside the module, of birds or other animals. This barrier can be constituted, for example, by a network.

Claims (10)

1. ?Lamellar module for 5G technology? characterized by the fact that it is made up of a series of fiberglass panels (2) - protected with fire-retardant treatments to increase fire resistance - rigid, flat or curved according to the overall geometry to be created which are perfectly transparent to the 5G signal, guaranteeing ?effective ventilation inside the module (1) and the consequent dissipation of the heat generated by the radiant systems, avoiding the risk of thermal overload. ?2. ?Lamellar module for 5G technology? as per the previous claim characterized by the fact that each panel (2) ? composed of a succession of slats (3) of variable thickness in a range of 3/8 mm. parallel to each other, all with the same rectangular section, arranged horizontally and reciprocally linked to each other through vertical ribs (6) of variable thickness in a range of 7/15 mm. suitably notched to allow the blades (3) to be housed. Both the horizontal blades (3) and the vertical ribs (6) have, on the internal side (7) facing the 5G antennas, a tapering (8) along the entire length, to optimize their behavior towards the signal of the frequencies in use . 3. ?Lamellar module for 5G technology? as per claim one characterized by the fact that the vertical ribs (6) can be replaced by circular profiles number (19) passing through the slats (3) and having a variable diameter in a range of 15/50 mm. 4. ?Lamellar module for 5G technology? as per previous claims characterized by the fact that the inclination of the slats (3) in the plane of the cross section can? be easily varied to adapt to the tilting characteristics of the antennas, so that the blades (3) themselves are parallel to the direction of irradiation, minimizing the resistance opposed to signal propagation. 5. ?Lamellar module for 5G technology? as per the previous claims, characterized by the fact that the distance (18) between the slats (3) is approximately 11 cm. (range between 7 and 15 cm.) allows to achieve the degree of radio transparency prescribed by the specifications of the different operators. 6. ?Lamellar module for 5G technology? as per the previous claims characterized by the fact that the number of vertical ribs (6) and/or circular profiles (19) varies from two to three according to the width of the panel (2). 7. ?Lamellar module for 5G technology? as per the previous claims, characterized by the fact that the individual panels (2) are mutually constrained and fixed to the mast (5) present, by means of metal components bolted to the ends? upper and lower ribs (6) pi? external and/or circular profiles (19) more? outside of each panel (2). 8. ?Lamellar module for 5G technology? as per the previous claims characterized by the fact that one of the two panels (2) of the module (1) ? laterally hinged cos? to allow easy access to the internal radiant system for the activities? of maintenance and ? equipped with retainers (9) which deny effective closure. 9. ?Lamellar module for 5G technology? as per the previous claims characterized by the fact that from the external side the covering element (10) will allow? the easy housing, and subsequent maintenance, of a fire-fighting system with automatic fire extinguisher for fire class A B C with sprinkler valve equipped with a bulb calibrated at 68? C or 93? C suitable for electronic devices (fire alarm system). 10. ?Lamellar module for 5G technology? as from previous claims characterized by the fact that at the top the module can? be closed with a flat or shaped covering element (10), for example with a pyramidal or truncated cone shape, arranged on the external side with ? a hooking system (11) for shooting at height of the artifact. This covering element (10) allows to achieve the concealment of the extinguisher, without hindering the periodic maintenance.? ?????????? ???????????????????????????????????????????????? ??? ? ??