Currently, there is a huge evolution in the field of both electric vehicles and hybrid vehicles that can be observed in all technological aspects characterizing electric mobility.
Resulting from the automobile industry efforts, vehicles have been more advanced, where the more efficient and best-performing engines, and also lighter and longer-lasting batteries' new technologies stand out. The massification of electric mobility depends on increasing the production of electric and hybrid vehicles, which is achieved through the reduction of production costs and the consequent increase in sales of low-priced vehicles.
This accretion in electric and hybrid vehicles in circulation has not been followed by an increase in the number of infrastructures available for battery charging. Charging possibilities can be residential, such as when the vehicle is in the garage charging batteries overnight through a charging process that can be slow or fast, depending on the type of charger used, or by using fast charging stations that can be found at service stations, public or private parking lots providing charger sockets for fast charging.
The access to fast charging services presents several constraints, among which it is possible to highlight the lack of availability of charging stations, the growing number of competing users, the long duration of charging and consequent waiting time, accessibility to the charging station, and the operational state of the equipment.
For example, a solution for a communications network that aims to help find an available charging station, control the respective charging equipment, and pay for the energy consumed in the vehicle charging is known in the state-of-the-art. However, this solution does not solve most critical situations related to the waiting time during the vehicle charging, the trip to the charging station, the number of competing users and the consequent lack of availability of infrastructures for charging.
On the other hand, power distribution networks also face a great challenge in adapting to the reality of electric mobility. Many networks, especially urban networks, have not been dimensioned, and are not prepared, for the growing increase of energy consumption that is currently occurring related to the growing number of vehicles connected to the electric grid, and charging simultaneously.
The impact on electric power distribution networks when charging thousands of electric vehicles simultaneously is significant, for example, by overloading production centers, transmission and distribution lines.
There is, therefore, a need to develop solutions allowing to optimize the value of distributed resources, contributing to a more efficient and intelligent system for charging electric vehicles that is more decentralized, and at the same time more interconnected, thereby allowing for increased reliability, safety, environmental sustainability, and energy efficiency.
SmartGrids aim to mitigate the aforementioned problems and create solutions that meet the challenges posed by the development of SmartCities and electric mobility.
The global expansion of the Internet of Things (IoT), which is mainly seen in cities and large urban centers, is of crucial importance for interconnecting Smartcities and SmartGrids. However, in the same way that Grids need to adapt, Cities also have to create solutions for buildings, parking lots, streets, recreational areas, in order to efficiently meet the expectations of local populations.
Users of electric vehicles are currently limited to a small number of alternatives for charging their vehicle batteries, which, despite incentives to change, lead to a discouragement of the use of electric vehicles, favoring the use of vehicles with internal combustion engines.
In urban centers, most private parking areas are located at the lower floors of multi-family residential buildings in the form of individual parking spaces or individual garages. Normally, in these buildings, the electric installation of the areas considered common or shared is intended for automatisms, such as elevators, doors, security systems, communication systems, TV signal distribution equipment, and other services, the lighting of floors and safety stairways, and service sockets for connecting small appliances on the floors and in parking areas.
Thus, electric power available for common use in residential buildings is limited to the consumption predicted when the building was constructed, and an increase in the installation's power requires considerable changes such as the replacement of protection switchboards, connections, and wiring.
At present, a solution allowing the connection of electric vehicle chargers is known in the state-of-the-art, which solution involves the installation of a new “prefabricated” cable specially designed and prepared for this application. This type of solution has the disadvantage of requiring a change in the electric installation approved in the building project, which according to current legislation is not permitted in many countries.
Thus, the cost of electric energy consumed for these parking areas is usually shared by the residents or condominium owners. This means that users of electric vehicles living in buildings with individual parking places or garages that do not have private electric installations are unable to charge the batteries of their electric vehicles without overcharging the energy costs of the common parts of the building.
On the other hand, a simultaneous charging of the batteries of several electric vehicles via a connection to the common service sockets in parking places or garages will overload the electric installation of the common areas, with the risk of exceeding the nominal power installed, leading to trigger the protection devices.
Furthermore, a charging solution consisting of connecting the vehicle to a lighting circuit in the parking lot or parking place, by means of a bracket (or mechanical arm) or socket and with an electric cable connected to the wires where a lamp was previously connected is known from the present state-of-the-art.
Considering the increase in the range of current electric vehicles as a consequence of the increase in the energy capacity of batteries, the need to provide more energy for battery charging also increases. Thus, in a lamp circuit, charging a single electric vehicle goes very slowly due to the limitation of energy supply, making it discouraging when there are several competing electric vehicles to be charged at the same time. Also, this solution does not solve the issue of higher shared energy costs with common areas and services.
According to the above-mentioned points, it is thus impossible to charge several electric vehicles simultaneously in parking spaces or garages in residential buildings using the common electric installation.
The present application therefore aims to describe a solution capable of solving all the currently known and previously identified problems of the present state-of-the-art.
The present application describes a system for charging electric vehicles in parking places and garages of multi-family or business buildings, characterized in that it comprises at least one connection to a local power distribution network; at least one electric switchboard, comprising one energy meter connected to the local power distribution network through an electric grid connection and local protections; and at least one charging unit having at least one inlet connected to the at least one electric switchboard, comprising an automatic changeover switch for energy transfer; one energy meter connected to the changeover switch; a tampering sensor; a controller module connected to the automatic changeover switch, the energy meter and the tampering sensor, comprising at least one port adapted for communications with the connections to the changeover switch, to the meter, and to the sensor, and one mobile communications module; a circuit breaker connected to the energy meter; at least one smart socket to which electric vehicles are connected, the smart socket being connected to the circuit breaker; an RGB LED light for operation status indication of the charging unit; and a capacitive sensor for interaction with the vehicle user.
In an embodiment provided, the automatic changeover switch for energy transfer is adapted to switch the at least one inlet of the charging unit between the local power distribution network and/or an off-grid auxiliary circuit comprising renewable energy generation systems and/or energy storage systems in order to increase the power available for the vehicles charging.
Yet in another embodiment, the energy meter comprises a power switch adapted to control the output power of the at least one smart socket.
Yet in another embodiment, the mobile communications module is adapted to communicate with a global information and management system.
Yet in another embodiment, the global information and management system is adapted to control and manage the charging of the vehicles connected to the at least one smart socket through a time-sharing system for electric energy supply which manages the available power of the building electric network by means of a permanent supervision and alarming.
Yet in another embodiment, the time-sharing system for electric energy supply is adapted to enable to charge the vehicles connected to the at least one smart socket without exceeding the available power of the local power distribution network and/or the building.
Yet in another embodiment, the charging unit is adapted to replace the service sockets installed in the parking places or garages of the buildings.
Yet in another embodiment, the global information and management system comprises a “Peak Shaving” mode wherein the electric vehicle charging is carried out through the auxiliary circuit of the renewable energy Generation System and/or the energy stored in energy storage systems; and a “Last Gasp” mode which, in case of failure of the power supply to the vehicle, sends a notification to the user and adapts the charging Units to the off-grid auxiliary circuit, evaluating the available charging power and rearranging the time fractions of vehicles with pending charging.
Yet in another embodiment, the energy meter comprises terminals for connections to at least one Phase and Neutral; a mobile communications module; at least one controller with internal memory, adapted to perform measurements of the electric network; a real-time clock and an internal battery to feed the controller internal memory; and one port for communication with the mobile communications module; wherein the controller internal memory comprises records of imported active energy and active energy at least in one Phase; Voltage instantaneous values in at least one Phase, Current Intensities in at least one Phase, Frequency, Consumed Power and Power Factor, and critical and non-critical Alarms.
Yet in another embodiment, the at least one smart socket comprises a sliding obstructive lid, an electromechanical interlock, and a socket, the interlock being responsible for the automatic displacement of the obstructive lid, ensuring safety and protection of the socket against undue actions.
Yet in another embodiment, the smart socket's sliding obstructive lid has three operating positions comprising: a. obstructive lid blocked in the safety position wherein no vehicle charging connector is inserted in the socket; b. obstructive lid unblocked; c. obstructive lid blocked in the safety position with a vehicle charging connector inserted in the socket.
Yet in another embodiment, the RGB LED comprises three colors Blue-Green-Red indicating the charging status and mode of the charging unit wherein:
Yet in another embodiment, the time-sharing system for power supply is adapted to:
Yet in another embodiment, the charging unit is adapted to allow a bidirectional transfer of power, on-grid or off-grid, between one electric vehicle and a power system through the auxiliary connection; another electric vehicle plugged into a socket of the same charging unit; and another electric vehicle plugged into a socket of a different Charging unit as long as they use the same phase of the circuit.
The present application further describes a method of charging electric vehicles according to the system for charging electric vehicles described above, characterized in that it comprises the following steps:
The present invention refers to a system for charging electric vehicles via a network-controlled charging unit, transferring charge between a local power source and an electric vehicle, to which a charging management methodology is associated.
The electric vehicle charging system provided comprises:
Said charging system is configured by:
With the solution herein provided, it becomes possible to install multiple charging units in parallel, thereby making it possible to simultaneously charge multiple electric vehicles without overloading the infrastructure of the electric network installed.
The charging unit for electric vehicles comprises:
The energy meter equipped with a remote communication module comprises:
The charging unit for electric vehicles communicates with a server installed in a Wide Area Network (WAN), or another similar, non-limited one, or further with a Blockchain-based platform allowing a decentralization of the application, thereby ensuring application security. The server may comprise a user database and the Blockchain platform a structure with Smart contracts.
Both the server with the database and the Blockchain platform with the Smart contracts are provided with a data structure comprising:
The server includes at least one application for charging management provided with a set of functionalities comprising:
The server is provided with a WEBServer application, as well as an access portal having a set of functionalities comprising:
For an easier understanding of the present application figures are appended, which figures depict embodiments that, however, are not meant to limit the art herein disclosed.
Reference being made to the figures, some embodiments are now described in a more detailed way, which are not meant, however, to limit the scope of the present application.
The present invention describes a system for charging batteries (1) of electric vehicles (3) and/or hybrid vehicles to be applied in private parking places or private garages in residential multi-family or business buildings. The charging control is ensured by the management unit (210). The electric vehicle charging system (1) comprises the following elements:
The input/connection (11) of electric power from the distribution network (2) is made through the electric energy meter (10) of the power distribution company. Downstream the meter (10) an energy meter (300) is installed, adapted to communicate remotely via a communications module (310), for example using an LTE mobile network, or other technically suitable for the purpose. This meter (300) output terminals will on their turn be connected to the electric switchboard of the building (30) which is responsible for feeding the circuits (13, 14, 15) L1, L2 and L3 phases of the service sockets provided in parking areas and garages where the electric vehicles (3) charging units (100) will be installed in place thereof.
The electric energy meter (300) is adapted to perform readings, and store records in the memory, determining and/or operating:
The installation of the energy meter (300) is optional if the meter of the electric power distribution company (10) installed in the building has the same functionalities as the energy meter (300), allowing the connection of a communications module (310) to perform the remote readings and parameterizations mentioned above.
The charging units (100) are installed in place of existing service sockets provided in the building's common parking places or private garages.
The sockets that will not be replaced by charging units (100) will be replaced by smart sockets adapted and/or comprising a wireless communications system and/or with power control in order to limit energy consumption in common areas, and thus account for the condominium's actual consumption.
The charging unit (100) is provided with two inlets, one for the connection to the on-grid network (501) and the other one for the connection to the off-grid network (502), which internally connect to the automatic power transfer changeover Switch (101). Both the wiring (501) and the connection (121) are dedicated to one of the three phases (L1, L2, L3) coming from the on-grid circuit switchboard (30). Both the wiring (502) and the connection (122) are dedicated to one of the three phases (L1, L2, L3) coming from the off-grid circuit (6) switchboard (60). Similarly to the on-grid circuit provided by the network (2), the off-grid circuit (6) is connected to an energy meter (600), which on its turn is connected to the switchboard (60) housing the auxiliary electric protections of the auxiliary circuit supporting the vehicle charging (3).
The automatic power transfer changeover Switch (101) is controlled by the controller Module (103) of the charging unit (100) and adapted to operate according to the information received from the Management Unit (210) through the communications Module (110). The automatic changeover Switch (101) enables the selection of the energy supply source, whether the on-grid network (2) and/or the off-grid auxiliary circuit (6), for each of the charging Units (100).
With the solution provided, it becomes possible to install in parallel multiple charging units (100) that allow the simultaneous charging of multiple electric vehicles (3) without overloading the on-grid network infrastructure (2) locally installed, using the auxiliary off-grid circuit (6) that allows to compensate for any capacity and/or supply failures, transforming a conceptually dependent system into an autonomous and energy independent system.
The information collected and analyzed by the energy meters (300, 600), and then forwarded to the management unit (210), enables to determine which is the best solution in terms of supply network selection, whether the on-grid one (2) or the off-grid (6) one.
The automatic changeover Switch (101) has an outlet (123) with a direct connection to an electric energy Meter (102), which is responsible for the consumed energy metering at the Smart Socket (107) for electric vehicles (3) connection. The energy Meter (102) is equipped with a wired communications port responsible for providing the connection (113) and respective communications with the charging unit controller Module (103). Accordingly, the energy Meter (102) communicates with the Management Unit (210) through the charging unit controller Module (103).
The charging unit (100) controller Module (103) comprises:
The energy Meter (102) comprises a PCS (105) acting according to the operating mode wherein the charging Unit (100) is provided.
In one of the existing operating modes called, for example, HIGH POWER, the PCS (105) keeps the circuit closed until the vehicle (3) batteries charging time is completed, or in case the charging current is not supplied within predefined limits for the charging mode ON CHARGE.
In another existing operating mode called LOW POWER, the PCS (105) keeps the circuit closed whenever the output current is not exceeding the predefined limit for this operating mode. In this mode, when the output current is above the limit value defined during a previously established period of time, the PCS (105) opens the circuit by interrupting the output current, and only closes back the circuit after a predetermined period of time.
The energy Meter (102) automatically controls the PCS (105) operation, which may also be controlled by remote commands through the Management Unit (210), according to the present operating mode.
The output of the energy Meter (102) is connected to the protection Circuit Breaker (106) via connection (125). On its turn, the circuit breaker (106) is connected to Smart Sockets (107) for connection to the electric vehicles (3) via connection (127).
Charging unit (100) is pre-equipped with two connection (503, 504) inputs for an auxiliary circuit comprising an energy storage System (7) for off-grid charging, which enhances the current supply capacity during electric vehicles (3) charging.
To use the auxiliary energy storage circuit (7) for off-grid charging (6), the charging unit (100) is provided with two inputs (503, 504) for wiring.
The input (503), which is connected to the circuit (124), interconnects with the AC-IN input of the auxiliary energy storage System (7). The input (504), which is connected to the circuit (126), corresponds to a wired communications connection with the charging unit (100) controller Module (103). The charging unit (100) controller Module (103) may further make the circuit (126) connection with the energy storage System (7) through wireless communication. Furthermore, it is possible to use the energy storage System (7) to help charge the vehicles (3) through a direct connection in the Socket (AC-OUT). Charging unit (100) Sockets (107), and energy storage system (7) Sockets (AC-OUT), are smart sockets capable of power integrated control for the protection against external short-circuits. These comprise a sliding obstructive lid (1071) operated by an electromechanical interlock (1072) that protects users from unintended electric discharges by not allowing the removal of the connection circuit (130) to the vehicle (3) or the battery charger when it is charging, while the charging process of the electric vehicle (3) batteries is ongoing. The connection status between the Socket (107, AC-OUT) and the Connector (1074) of cable (130) connecting to the charger or electric vehicle (3) defines the sliding obstructive lid (1071) position as illustrated in
Inserting or removing the vehicle (3) charging connector (1074) from any of the smart Sockets (7, AC-OUT), opening the lid (1071) of the charging module (100), or moving the unit (100), causes the Tampering Sensor (104) to be triggered, which informs the controller Module (103) about the status change of the connection (130) Socket-Connector. The controller Module (103) checks whether the operating mode of the charging Unit (100) allows changes in these connections. If the present mode of the charging Unit (100) does not allow changes, then the Socket (107), or the Socket (AC-OUT), will be automatically switched off, and a Tampering Attempt Alarm is sent to the Management Unit (210).
The charging Unit (100) allows the use of bidirectional chargers to carry out charging of electric vehicles (3) over the on-grid circuit, and in a cheaper tariff period, or through the renewable energy system, over an off-grid circuit. The user of the electric vehicle (3) with bidirectional charger can authorize the charge transfer to another electric vehicle (3) in a more urgent need of charge, against an agreed compensation.
The charging Units (100) and the Management System (210) record the values of the energy transferred between electric vehicles (3), and the users are informed about the respective energy transfers.
The charging unit (100) is provided with an embedded RGB LED indicating the operating status of said unit, wherein:
The diagram illustrated in
Bidirectional communications (411) of the Smartphones (400) with the Management Unit (210) are performed by an APP provided on said device (400) allowing to register the user and/or the vehicle (3) in the charging management service, associate the user with the charging Unit (100) by reading and sending (412) the QR-code located on the front cover of the charging unit (100), register the connection (130) of the electric vehicle (3) to the unit (100) to start charging, inform the Management Unit (210) about the charge level of the batteries before starting charging, inform the Management Unit (210) about the minimum range required after charging, consult the charging data, schedule the charging, indicate the time at which the electric vehicle (3) is available for charging.
The communication (511) between the Management Unit (210) and a Personal Computer (500) uses a Web Browser to access the electric vehicle Charging Management Portal.
The Charging Management Portal allows to register the user or the vehicle in the charging management service, associate the user with the charging Unit (100) by inserting the charging unit (100) data, register the connection (130) of the electric vehicle (3) to the unit (100) to start the charging process, inform the Management Unit (210) about the charge level of the batteries before starting charging, inform the Management Unit (210) about the minimum range required after charging, consult the charging data, schedule the charging, indicate the time at which the electric vehicle (3) is available for charging.
The operations of the components comprised in the electric vehicle Charging Unit (100) are commanded directly by the unit's controller Module (103), and communications (111) of this Module (103) with the Management Unit (210) are carried out via the mobile communications module (110).
In the Unit (100), the meter (102) measurements, the command to open and close the PCS (105) circuit, the PCS (105) status, the command of the automatic power transfer changeover Switch (101), sending the port opening alarms, the connection to the Socket (107, AC-OUT) status, the energy storage System (7) control for off-grid charges, are functionalities controlled by the unit controller Module (103) and coordinated by the Management Unit (210) through communication connections (111) of the communication modules with the management platform.
The controller and communications Module (103) is provided with an energy reserve that allows it to communicate with the Management Unit (210) to inform that a power failure has occurred.
This functionality, called “Last Gasp”, allows the Management Unit (210) to send orders to the charging Units (100) in a Charging mode on the on-grid circuit to switch to the auxiliary off-grid circuit (6), and thereby the Management Unit (210) evaluates the available energy of the auxiliary system and rearranges the time fractions of electric vehicles with pending charging.
The Management Unit (210) makes use of a time-sharing system for power supply shared among vehicles (3) and remotely coordinates the charging system (1) by:
The system for charging electric vehicles (1) permanently manages the building's available network power, comprising
The system for charging electric vehicles (1) makes use of a feature called “Peak Shaving” that allows to avoid the highest charging tariffs because, during these periods, the charging units (100) switch their energy input to the auxiliary circuit of the renewable energy Generation System (6), being also able to use their stored energy in energy storage systems (7).
The present description is not, naturally, in any way restricted to the embodiments presented herein and a person with average knowledge in the area may foresee many possibilities for modification thereof without departing from the main idea, as defined in the claims. The preferred above-described embodiments are obviously combinable with each other. The following claims further define preferred embodiments.
Number | Date | Country | Kind |
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117023 | Jan 2021 | PT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2022/050465 | 1/20/2022 | WO |