RU224893U1 - Cell of the station for issuing, receiving, servicing and accounting of portable chargers - Google Patents

Abstract

The utility model relates to the field of electrical engineering, in particular to the design of a station for issuing and servicing portable chargers, containing cells for housing these devices. A cell of a station for issuing, receiving, servicing and accounting for portable chargers, made with the ability to interface and receive commands from the station, while the port hole of the internal cavity of the cell is closed with a sealed door, and a movable platform is installed in the cell, structurally connected to an electric motor that drives it , and made with the ability to move the portable charger into or out of the cell, spring-loaded contacts are installed on the platform, one part of which is configured to charge portable chargers, and the other part is interface, and the cell is designed in such a way that when installing the portable charger in cell, the movable platform moves in the direction from the port hole deep into the cell, the door rotates to the closed position, the movable platform moves in the direction of the port hole until the door is pressed against the seal of the cell hole. 7 salary f-ly, 1 ill.

Description

The utility model relates to the field of electrical engineering, in particular to the design of a station for issuing and servicing portable chargers, containing cells for placing these devices.

In the current state of the art, charging systems for mobile devices are known under patents for inventions RU 2737311 and RU 2645748, published on November 26, 2020 and February 28, 2018, respectively. The patents disclose mobile device charging systems consisting of an autonomous station for storing, charging and dispensing mobile chargers, a central server for managing charging stations and mobile chargers, each of which is equipped with an electrical energy storage device, with one electrical connector for charging the storage device when paired with a corresponding a charging station connector and another electrical connector for connecting the electricity storage device to the battery of a mobile device when it is paired with the mating connector of the latter. At the same time, some embodiments of technical solutions provide for the installation of mobile chargers in cells with skids, and other embodiments of the technical solution provide for the installation of mobile chargers in bins with an access portal and an elevator for moving mobile chargers to storage positions. One of the disadvantages of the technical solutions disclosed in the invention patents RU 2737311 and RU 2645748 is the absence in the design of the station cells of wired or wireless communication means suitable for transmitting information between the station cells and the mobile charger. This drawback leads to the fact that the station does not have the ability to collect and retain information about the state of the mobile charger, about the history of discharging/charging by the user, and about the user’s devices charged from the mobile charger. This also results in the station being unable to configure programmable logic for the operation of the mobile charger, for example, such as blocking the mobile charger after the allowed period of use has expired. The lack of the ability to autonomously lock a device after the expiration of the permitted period of use has led to the fact that patents have proposed to charge users with a security deposit for the mobile charger before issuing it; in the future, this condition leads to a decrease in demand for rental services of mobile chargers. Another disadvantage of the technical solutions disclosed in these patents is the impossibility of storing mobile chargers in sealed conditions in relation to the external environment. This drawback leads to the fact that if the station is installed outdoors and exposed to atmospheric factors, the service life of the station will be limited. Thus, the technical solutions presented in patents RU 2737311 and RU 2645748 do not provide protection against intentional damage or contamination of station cells and/or mobile chargers, which in turn will also lead to limited service life of the station.

In addition, a method for selling and charging external batteries for charging mobile devices using a machine and a machine for implementing the method according to application for invention RU 2016105812, published on August 22, 2017, are known. The document discloses an automatic machine for selling and charging external batteries for charging mobile devices, containing a control controller and connected to it a power supply unit, a data input/output unit, a unit for receiving discharged batteries, a battery testing unit, units for issuing and receiving funds, and a battery charging unit. and a block for dispensing charged batteries and a mechanism for transporting batteries inside the machine, characterized in that the machine contains an information display and a dialogue block connected to it, including a mini-display with a screen for interactive interaction between the client and the machine and keys for selecting operating modes, while the transport mechanism is connected electrically with units for receiving, testing, charging and issuing batteries, the control controller is electrically connected to the data input/output unit, the dialogue unit and the keys for transferring the machine from one mode to another mode of its operation. One of the disadvantages of the technical solution presented in the application for invention RU 2016105812 is the absence in the design of the machine cells of wired or wireless communication means suitable for exchanging data between the machine and external batteries. The presence of such means of wired or wireless communication would make it possible to accumulate information about the state of the external battery, about the modes of use of the external battery by the user, and would also make it possible to introduce programmable logic into the operating modes of the external battery. Another disadvantage of the technical solution is the impossibility of storing external batteries in sealed conditions in relation to the external environment. This drawback will lead to the fact that if the machine is installed outdoors and exposed to atmospheric factors, the service life of the machine will be limited. In addition, this technical solution does not provide protection against intentional damage or contamination of the machine’s cells and/or external batteries.

Also known in the prior art, from patent document US 20200410793 A1, is a portable charger, rental system and related methods. The document discloses a portable charger dispensing system consisting of a dispensing station and at least one portable charger. The portable charger is issued by the dispensing station after the user completes the steps to begin renting the portable charger. At the same time, some variants of the technical solution provide for the installation of portable chargers in a cell with a door, but without providing the possibility of storing portable chargers in sealed conditions in relation to the external environment. The disadvantage of the technical solution presented in document US 20200410793 A1 is the absence in the design of the dispensing station cells of wired or wireless communication facilities suitable for exchanging data between the dispensing station and portable chargers. The presence of such means of wired or wireless communication would make it possible to accumulate information about the state of the portable charger, about the modes of use of the portable charger by the user, and would also make it possible to introduce programmable logic into the operating modes of the portable charger, as well as the impossibility of storing portable chargers in sealed conditions according to relation to the external environment, which will lead to the fact that if the station is installed outdoors and exposed to atmospheric factors, the service life of the station will be limited.

Thus, the main task for technical solutions revealing the portable charger dispensing station cell is to create a portable charger dispensing station cell that provides the ability to collect information accumulated by the issued portable charger about its use by the user and implement programmable logic into the portable charger, and also providing the ability to store a portable charger installed in a cell in sealed conditions with respect to the external environment, as well as stabilize the temperature of a portable charger placed in a cell, subject to a decrease in ambient temperature.

The technical result of the claimed utility model is to increase the tightness of the cell of the station for issuing, receiving, servicing and accounting of portable chargers while simultaneously increasing the service life by reducing the negative atmospheric impact of the environment.

The technical result is achieved by implementing a cell for a station for issuing, receiving, servicing and accounting for portable chargers, made with the ability to interface and receive commands from the station, while the port hole of the internal cavity of the cell is closed with a sealed door, and a movable platform is installed in the cell, structurally connected to an electric motor , driving it, and made with the ability to move a portable charger into or out of the cell, while spring-loaded contacts are installed on the platform, one part of which is made with the ability to charge portable chargers, and the other part is interface, and the cell is made in such a way, that when installing a portable charger into a cell, the moving platform moves in the direction from the port hole deep into the cell, rotates the door to the closed position, moves the moving platform towards the port hole until the door is pressed against the seal of the cell hole.

In this case, the mechanism for fixing the portable charger in each cell is installed on a movable platform.

At the same time, to ensure that the portable charger can be prevented from overcooling, a heating device is installed.

At the same time, to ensure the possibility of transmitting information between the cell of the issuing station and the portable charger placed in the cell, an additional radio frequency transmitter is installed.

At the same time, to ensure the possibility of inductive charging of the portable charger, an induction coil is installed, configured to transmit data between the station cell and the portable charger placed in the cell by modulating the signal.

In this case, an optical sensor is additionally installed to enable detection of objects placed inside the cell.

At the same time, to ensure the possibility of identifying a portable charger equipped with an RFID tag, an RFID tag reader and at least one RFID tag reader antenna are installed in the cell.

At the same time, to ensure the possibility of data transfer between the cell and a portable charger equipped with an IR receiver and an IR transmitter, and to identify portable chargers installed in the cell whose contact pads were damaged, an IR receiver and an IR transmitter are installed in the cell -transmitter.

The technical solution claimed as a utility model, in comparison with the technical solution presented in document US 20200410793 A1, has the ability to collect and store information accumulated by a portable charger, including information about the history of its condition, about the actions of discharging/charging the portable charger by the user, information about the users' devices being charged, setting up the programmable logic of the operating modes of the portable charger, and allows, among other things, autonomous blocking of the portable charger after dispensing.

The dispensing station cell is an electromechanical device for issuing, receiving, servicing and accounting of portable chargers and is designed to interface, through an interface connection, with the issuing station, receiving, servicing and accounting of portable chargers and controlling commands received from the dispensing station. In addition, through the dispensing station, the cell can be interfaced with a distributed network of control servers that manages the dispensing process of portable chargers, and is shared with multiple portable chargers.

Utility model presented

in fig. 1 - general view of the cell of the station for issuing, receiving, servicing and accounting of portable chargers.

Cell 1 of the station for issuing, receiving, servicing and accounting of portable chargers contains a port hole 2 of cell 1, a door 3 of cell 1 covering the hole 2, a group of flat contact pads 5 of the portable charger 4 installed in cell 1, spring-loaded contacts 6 of cell 1, moving platform 7, electric motor 8 moving the moving platform 7.

Cell 1 is designed to receive portable chargers 4 inside it, to provide the ability to charge discharged portable chargers 4, service and account for portable chargers 4, and issue charged portable devices 4 to the user. The internal cavity of the cell 1 for storing the portable charger 4 is closed by a sealed door 3. The door 3 of the cell 1 isolates the internal cavity of the cell 1 from the external environment both with and without the portable charger 4 placed inside the cell 1. In this case, for a tighter sealing of the cell, the movable platform 7, after turning the door 3 to the closed position, moves towards the port hole 2 until the door 3 is pressed against the seal of the hole 2. The cell 1 of the dispensing station has spring-loaded contacts 6 for reliable connection with the group of flat contact pads 5 of the portable charger 4. Part of the contact pads is designed to supply power for charging the portable charger 4. The other part of the contact pads is interface (UART, I2C, SPI, CAN, RS232/485, 1-Wire) and is intended for exchange data from the dispensing station microcontroller to the microcontroller of the portable charger 4. Such spring-loaded interface contacts 6 provide the ability to identify the portable charger 4 and collect information accumulated by the portable charger 4 during operation of the portable charger 4. Accumulated information may include, but not limited to the following information: information about the status of the portable charger 4; information about the discharge/charging history of the portable charger 4 by the user; information about the user's mobile devices charged from the portable charger 4. The specified spring-loaded interface contacts 6 allow you to configure the programmable logic of the portable charger 4 by transferring data between the microcontroller of the dispensing station and the microcontroller of the portable charger 4, which subsequently, in addition to providing other capabilities, allows perform autonomous self-locking of the portable charger 4 after the allowed rental time has expired, and thus reduce the risk of theft of portable chargers 4, as well as refuse to make a deposit by the user before renting the portable charger 4. Additionally, spring-loaded interface contacts 6 by providing the ability to access programmable logic make it possible to provide the possibility of autonomous self-locking of the portable charger 3 in the event of a critical loss of capacity, reaching the maximum permissible number of charge/discharge cycles of the battery of the portable charger 3 and exceeding the recommended operating temperature of the portable charger 3. In this case, cell 1 of the issuing station additionally has a mechanism for fixing the portable charger 4 in cell 1 and locking the door in the closed position, regardless of the presence of power to the cell.

A typical procedure for issuing portable chargers 4 to a user includes registering the user in a mobile application and/or on an Internet site and paying for the rental of a portable charger 4 through Internet acquiring related to the selected distribution station. After the user pays the rent, a distributed network of control servers communicates with the issuing station. Cell 1 of the dispensing station, using spring-loaded interface contacts 6, sends a command to the microcontroller of the portable charger 4 to unlock the portable charger 4, then releases the mechanism that fixes the portable charger 4 in cell 1, opens the door 3 of cell 1 and by moving the portable charger 4 on the movable platform 7 outside the cell 1 it is issued to the user. When the portable charger 4 is returned to cell 1, after it is captured, the movable platform 7 moves in the direction from the port hole 2, the door 3 rotates to the closed position, the movable platform 7 moves in the direction of the port hole 2 until the door 3 is pressed against the hole seal 2 to ensure the tightness of the cell structure.

This design of cell 1 makes it possible to ensure its tightness, which in turn increases service life, since it allows you to reduce or eliminate the adverse effects of environmental conditions (snow, rain, high humidity, wind, dust), and especially when placing the device in an open space without protective equipment.

Additionally, a heating device is installed in the station cell 1, designed to prevent overcooling of the portable charger 4, subject to low ambient temperatures.

Also, in cell 1 of the dispensing station, in addition to the spring-loaded interface contacts 6, a radio frequency transmitter is installed, which provides the ability to exchange data between cell 1 of the dispensing station and the portable charger 4 placed in cell 1.

In addition, in cell 1 of the dispensing station, in addition to the spring-loaded contacts 6 for charging, an induction coil is installed, which makes it possible to inductively charge the portable charger 4 in cell 1, while, by modulating the signal, it is capable of ensuring data transmission between cell 1 of the dispensing station and the portable charger 4 placed in cell 1.

Also, additionally, an optical sensor is installed in cell 1 of the issuing station, designed to provide the ability to detect the placement of objects inside cell 1.

And, in addition, in cell 1 of the issuing station, an RFID tag reader and an RFID tag reader antenna are installed, which allows for identification of a portable charger 4 placed in cell 1, equipped with an RFID tag. In addition, this design of cell 1 makes it possible to identify portable chargers 4 that are out of order and placed in cell 1 by users.

Also, an IR receiver and an IR transmitter are installed in cell 1, providing the ability to transmit data between cell 1 of the dispensing station and a portable charger 4 installed in cell 1, equipped with an IR receiver and an IR transmitter. This allows the dispensing station cell 1 to provide the ability to identify portable chargers 4 placed in cell 1 whose contact pads have been damaged.

Thus, the cell of the station for issuing, receiving, servicing and accounting of portable chargers, declared as a utility model, makes it possible to increase the service life, due to the fact that its operation in adverse environmental conditions is carried out while ensuring increased tightness of the device.

Claims (8)

1. Cell of the station for issuing, receiving, servicing and accounting of portable chargers, designed with the ability to interface and receive commands from the station, characterized in that the port hole of the internal cavity of the cell is closed with a sealed door, and a movable platform is installed in the cell, structurally connected to an electric motor, driving it, and made with the ability to move a portable charger into or out of the cell, while spring-loaded contacts are installed on the platform, one part of which is configured to charge portable chargers, and the other part is interface, and the cell is designed in such a way that When installing a portable charger into a cell, the moving platform moves in the direction from the port hole deep into the cell, the door rotates to the closed position, and the moving platform moves in the direction of the port hole until the door is pressed against the seal of the cell hole. 2. The station cell according to claim 1, characterized in that the mechanism for fixing the portable charger in the cell is installed on a movable platform. 3. Cell according to any one of paragraphs. 1, 2, characterized in that in order to prevent overcooling of the portable charger, a heating device is installed. 4. Cell according to any one of paragraphs. 1–3, characterized in that to ensure the possibility of transmitting information between the cell of the dispensing station and the portable charger placed in the cell, a radio frequency transmitter is additionally installed. 5. Cell according to any one of paragraphs. 1–4, characterized in that to ensure the possibility of inductive charging of a portable charger, an induction coil is installed, configured to transmit data between the station cell and the portable charger placed in the cell by modulating the signal. 6. Cell according to any one of paragraphs. 1–5, characterized in that an optical sensor is additionally installed to make it possible to detect the placement of objects inside the cell. 7. Cell according to any one of paragraphs. 1–6, characterized in that to enable identification of a portable charger equipped with an RFID tag, an RFID tag reader and at least one RFID tag reader antenna are installed in the cell. 8. Cell according to any one of paragraphs. 1–7, characterized in that to enable data transfer between the cell and a portable charger equipped with an IR receiver and an IR transmitter, and to identify portable chargers installed in the cell whose contact pads were damaged, a IR receiver and IR transmitter.