WO2023272974A1 - Self-powered information-energy integrated system based on transparent glass - Google Patents

Abstract

The present application discloses a self-powered information-energy integrated system based on transparent glass, the system comprising a first layer, a second layer, a third layer, a fourth layer, and a fifth layer from top to bottom; the first layer is an antenna, the second layer is a substrate, the third layer is a battery panel, the fourth layer is an energy storage device, and the fifth layer is a wireless module. In the present invention, glass is used as a substrate of an antenna, and same is integrated above a solar panel so that the solar panel is not blocked and can be used as the floor of the antenna while working normally; the integration of information sending/receiving and energy collection is achieved on the basis of achieving system self-powering; meanwhile, the space utilization rate is increased, the space of the antenna is saved, and more space is made available for collecting more solar energy.

Description

A Self-Powered Telecom Energy Integrated System Based on Transparent Glass technical field

The invention belongs to the technical field of self-supplied and telecommunication energy integrated systems, and relates to a self-supplied and telecommunication energy integrated system based on transparent glass.

Background technique

In addition to the Sub-6G (FR1) frequency band, the spectrum available for 5G wireless networks also includes high-frequency bands such as 28/39G (FR2) that are highly concerned by the industry. Compared with the wireless propagation characteristics of the low-frequency band, the high-frequency band is more sensitive to the occlusion on the wireless propagation path. Therefore, the smaller coverage of the 5G high-band network puts forward higher requirements for the planning accuracy of the site and engineering parameters. Site deployment optimization, Demands such as 5G supplementary blindness emerged as the times require.

In applications such as cellular networks, since mobile terminals have much higher requirements for volume, quality, and power consumption than base stations, and usually cannot meet the requirements of an ideal MIMO system where the distance between adjacent antennas is much greater than the wavelength, multiple antennas can only be installed in base stations. end, it is difficult for mobile terminals to install multiple antennas. In this context, cooperative relay communication came into being, which combines the technical advantages of diversity and relay, and realizes the performance gain of multi-antenna and multi-hop transmission in traditional communication networks, while maintaining the flexibility and performance of MIMO systems. Even more degrees of freedom can be provided.

The increasingly severe global climate change situation and the pressure to reduce emissions have prompted international oil companies to propose transformation strategies one after another to respond to the commercial transformation requirements of energy conservation and emission reduction, control of greenhouse gas emissions, and production and supply of clean and low-carbon energy. With the continuous maturity of carbon compensation mechanism, methodology and carbon market, carbon neutrality, as an effective environmental management tool, has gradually gained more and more support, and the trend of global voluntary carbon reduction actions has also changed accordingly.

Due to the size and the requirements of the working scene, it is difficult for the sensor to carry a large energy source, and the wired energy transmission is complicated. At present, the efficiency of long-distance wireless energy transmission is generally low, so the demand for low-power sensors is more urgent. Low-power sensors can improve battery life, reduce charging frequency, and greatly expand application scenarios and application requirements.

technical solution

The present invention provides a transparent glass-based integrated system of self-supply and telecommunication energy, aiming at overcoming the above-mentioned deficiencies in the prior art.

For realizing above-mentioned object, the technical scheme that the present invention takes is:

A transparent glass-based integrated system of self-powered telecommunication energy, including the first layer, the second layer, the third layer, the fourth layer, and the fifth layer from top to bottom; the first layer is an antenna, and the second layer is the substrate, the third layer is the battery board, the fourth layer is the energy storage device, and the fifth layer is the wireless module.

Further, the substrate is a glass substrate.

Further, the glass substrate is a transparent glass substrate.

Further, the antenna and the substrate together form an antenna to receive and transmit signals.

Further, the antenna form may be any planar antenna or antenna array.

Further, the battery panel is a solar panel.

Further, the wireless module includes one of a relay blind filling module, a wireless sensing module, and a radio frequency identification module.

Beneficial effect

Compared with the prior art, the present invention has the following advantages and beneficial effects:

(1) Most of the existing technologies adopt the design form of substrate + metal ground + power supply, which is not only bulky. The battery and other power supply equipment used in the power supply are not low-carbon and environmentally friendly. In the case of many communication objects, the entire system network will be very cumbersome. The glass + solar panel design is adopted. The solar panel is used as a power source and a floor at the same time. The substrate also uses a light-transmitting glass medium, which not only achieves energy self-sufficiency, but also greatly expands the applicable scenarios due to its light transmission.

(2) The present invention uses glass so that the solar panel is not blocked by the substrate, and the available area can be maximized under a certain volume, that is, the antenna and the solar panel do not need to be placed side by side on the same layer of substrate, which expands the solar energy. The area of the battery board enhances the battery life and performance of the device.

(3) The present invention uses glass as the substrate of the antenna, and integrates it above the solar panel, so that the solar panel is not blocked and can be used as the floor of the antenna while working normally, on the basis of realizing the self-power supply of the system , realize the integration of information sending and receiving and energy collection, and at the same time enlarge the space utilization rate, save the space of the antenna, and release more space for collecting more solar energy.

Description of drawings

Fig. 1 is a schematic structural view of the self-powered telecommunication energy integration system based on transparent glass of the present invention;

Fig. 2 is a structural schematic diagram of the relay blind filling module of the present invention;

Fig. 3 is a schematic structural diagram of the wireless sensor module of the present invention;

Fig. 4 is a schematic structural diagram of the radio frequency identification module of the present invention.

Embodiments of the present invention

As shown in Figure 1, the integrated system of self-powered telecommunication energy based on transparent glass of the present invention includes a first layer 1, a second layer 2, a third layer 3, a fourth layer 4, and a fifth layer 5 from top to bottom. .

The first layer 1 is an antenna, and the second layer 2 is a transparent glass substrate. The thickness of the transparent glass substrate can be adjusted freely with the frequency of the antenna. The antenna and the transparent glass substrate together form an antenna for signal reception and transmission. At the same time, the transparent glass substrate does not block sunlight. , does not hinder the collection of solar energy by the solar panels on the next layer, and the form of the antenna can be any planar antenna or antenna array.

The third layer 3 is a solar panel, which collects solar energy and converts it into electricity to power the entire system and also serves as the floor for the upper antenna.

The fourth layer 4 is an energy storage device, which stores the electric energy converted from solar energy and realizes stable DC output.

The fifth layer 5 is to implement wireless modules with various functions. By loading wireless modules with different functions, functions such as relay communication, signal blind filling and low-power sensing are realized.

Realize the function: realize energy collection, conversion and self-power supply of the whole system through solar panels, no external power supply is required, low-carbon; then receive and transmit signals through the antenna, and realize the integration of signal and energy in the system; through loading with Wireless modules with different functions can realize various functions. Examples are as follows:

(1) Relay communication: When the wireless module contains a relay blind filling module, indoor and outdoor relay communication can be realized. The structural diagram of the relay blind filling module is shown in Figure 2;

(2) Low-power sensing: When the wireless module contains a wireless sensing module, it can realize the function of signal coverage and blind filling. The structural diagram of the wireless sensing module is shown in Figure 3;

(3) Radio frequency identification: When the wireless module contains a radio frequency identification module, it can realize sensing with extremely low power consumption. The structural diagram of the radio frequency identification module is shown in Figure 4.

The present invention uses glass as the substrate of the antenna and integrates it above the solar panel, so that the solar panel can be used as the floor of the antenna while it is not blocked and works normally. On the basis of realizing the self-power supply of the system, the realization of information The integration of transceiver and energy collection, while increasing the space utilization, saves the space of the antenna, and releases more space for collecting more solar energy.

Those skilled in the art will appreciate that the embodiments described here are to help readers understand the principles of the present invention, and it should be understood that the protection scope of the present invention is not limited to such specific statements and embodiments. Those skilled in the art can make various other specific modifications and combinations based on the technical revelations disclosed in the present invention without departing from the present invention, and these modifications and combinations are still within the protection scope of the present invention.

Claims (7)

1. A transparent glass-based integrated system for self-powered telecommunication energy, characterized in that it includes the first layer, the second layer, the third layer, the fourth layer, and the fifth layer from top to bottom; the first layer is an antenna , the second layer is the substrate, the third layer is the battery board, the fourth layer is the energy storage device, and the fifth layer is the wireless module.
2. The transparent glass-based self-powered telecommunication energy integration system according to claim 1, wherein the substrate is a glass substrate.
3. The transparent glass-based self-powered and integrated system for telecommunication energy according to claim 2, wherein the glass substrate is a transparent glass substrate.
4. According to claim 1, the integrated system of self-powered and telecommunication energy based on transparent glass is characterized in that: the antenna and the substrate together form an antenna to receive and transmit signals.
5. According to claim 1, the transparent glass-based self-powered telecommunication energy integration system is characterized in that: the antenna form can be any planar antenna or antenna array.
6. The transparent glass-based self-supplied telecommunication energy integration system according to claim 1, characterized in that: the battery panels are solar panels.
7. According to claim 1, the transparent glass-based self-powered telecommunication energy integration system is characterized in that: the wireless module includes one of a relay blind filling module, a wireless sensor module, and a radio frequency identification module.