WO2022200353A1 - Electrical device for charging an electrical vehicle - Google Patents

Abstract

The invention relates to an electrical device (1) for charging an electric vehicle comprising a transformer container (2) and at least one charger container (3), a transformer unit provided with a distribution transformer (5), which is connectable to a high voltage power grid and at least one charger unit provided with at least one electrical vehicle charger (8), whereby the distribution transformer (5) is arranged in the transformer container (2) and each charger unit is arranged in an allocated and separate charger container (3). According to the invention the charger container (3) and the transformer container (2) are arranged adjacent to each other.

Description

Electrical device for charging an electrical vehicle

The present invention relates to an electrical device for charging an electric vehicle comprising a tranformer container and at least one charger container, a transformer unit provided with a distribution transformer, which is connectable to a high voltage power grid and at least one charger unit provided with at least one electrical vehicle charger, wherby the distribution transformer is arranged in the transformer container and each charger unit is arranged in an allocated and seperate charger container,

Electrical devices designed as transformers are used for con verting a higher voltage to a lower voltage or vice-versa. They are used in all areas of electrical energy transmission and distribution. Power transformers are used for the trans mission of electrical energy over long distances at high voltages in the range of approximately 50 kV to 1000 kV. In particular at high operating voltages, power transformers may have a weight of several hundred tons and may correspond to the size of a single-family house. Distribution transformers are comparatively compact and may, for example, also be at tached to a utility pole, in a building, underground or mounted on a concrete pad. All transformers have in common a core and windings which are inductively coupled to one anoth er. During operation, the windings are at a high-voltage po tential. An insulating material is used for insulating and cooling the winding, which, in the case of power transform ers, may be a fluid, for example, an oil, an ester liquid, or a gas.

Distribution transformers may also comprise a tank which is filled with insulating fluid. In deviation therefrom, howev er, it is also possible to design the distribution transform ers as so-called dry-type transformers, wherein the windings are embedded in a solid object, for example, an epoxy resin or varnish, instead of a fluid or gaseous insulating medium. Urbanization is a mega trend with underlying needs of e- mobility, smart distribution grid, digital displays, mobile phone, towers, air quality monitors etc. Lack of electric ve hicle charger infrastructure is the major challenge faced by e-mobility. Electrical chargers need footprint (installation space) as well as safe and reliable power supply. Also, large scale deployment of these chargers will lead to distribution infrastructure upgrade costs. Governments and energy compa nies all over the world urgently need smart and integrated solutions which bundle the electrical vehicle chargers and distribution infrastructure which do not significantly in crease the upgrade cost or compensate the upgrade costs by generating additional revenues and are deployable within the available space or footprint.

It is known that to locate distribution transformers and electrical vehicle chargers at discrete locations governed by their individual positioning considerations. Distribution transformer are usually arranged on poles or on the ground surrounded by a safe housing.

Known electrical vehicle chargers are provided on walls, ped estals or ground mounted nearby to parking lots, a roadside and the like. They need separate space and power supply from nearby power distribution system.

The electrical device initially specified has the disad vantage that an additional space is necessary and the elec trical connection between the charger to be installed and an already existing distribution transformer is complex and in volves additional costs.

Object of the present invention is to provide an electrical device of the kind initially specified, which can be easily installed at low costs. The present invention achieves this object in that the charger container and the transformer container are arranged adjacent to each other.

The electrical device according to the inventions is an inte grated and modular electrical device which can be quickly in stalled on site wherever needed. A complex and time-consuming electrical connection between a distribution transformer in stalled elsewhere and the electrical charger unit is no long er needed according to the invention. The distribution con tainer accommodates the distribution transformer unit. The transformer reduces the high voltage of the power grid, i.e. voltages between 1 kV and 50 kV, to the low voltage level and supplies power to the vehicle charger of the charger module just below or beside it. The charger container includes at least one electric vehicle charger and according to a pre ferred embodiment of the invention a low voltage equipment.

The distribution transformer supplies power to the power con sumers arranged in the charger container like one or more electrical vehicle chargers, controllers, communication tools and the like.

According to the invention a plug and play solution is pro vided which bundles customer requirements. It provides effi cient power distribution network combining future needs of digitalization and electric vehicle charging. The solution will be accommodated in the same or similar space or foot print. This will greatly reduce length of supply cables be tween transformer and chargers. Problems like voltage drop, resistive losses, cost of digging trenches and laying long cables are avoided according to the invention.

The term "adjacent" shall mean according to the invention that the charger container and the transformer container are located side by side or one upon the other. The containers can be made of any material. Advantageously they are made of metal sheets.

In an embodiment of the invention the transformer container and the charger container are attached to a support frame.

The support frame is designed to rest on the ground. It holds the transformer and/or the charger container.

The transformer container and the charger container are ad vantageously grounded.

According to another variant of the invention the transformer container is designed as a stand alone transformer cabinet and and each charger container is designed as a stand alone charger cabinet wherin the transformer cabinet and each charger cabinet are positioned side by side. In this case the cabinets or in other words the boards rest on the ground. According to a preferred embodiment they are located side by side. They can be connected with one another to increase the stability of the electical device according to the invention.

According to another embodiment of the invention the transformer unit comprises a communication box wherein the distribution transformer is equipped with transformer sensors connected with the said communication box and wherin the communication box is connectable with a data processing cloud.

The transformer sensors are advantageously connected via a short-range area communication connection to the communica tion box. The short-range communication connection may, for example, be a simple cable. Alternatively, the short-range communication connection is, for example, a ZigBee, Blue tooth, wireless, Ambus or WiFi communication connection. The short-range communication connection extends over a maximum of 100 meters. The communication box comprises a housing including a plural ity of measurement inputs, such that an entire range of dif ferent transformer sensors. A distribution transformer may comprise a vessel or tank which is filled with an insulating fluid. The core and winding are arranged inside the tank. In this case, temperature sensors are generally required which are used for measuring the fluid temperature in the tank. In contrast, so-called dry-type distribution transformers, com prise different sensors which, for example, are configured for measuring a winding temperature or a winding current. In order to be able to use the same communication box for all electrical devices, within the scope of the present inven tion, said communication box is populated with a plurality of analog and digital inputs. In addition, according to the pre sent invention, a so-called GSM module is provided, via which the measurement signals collected by the communication unit can be transmitted to a remote, for example, cloud-based com puting unit, via a known standard.

Advantageously, the communication box comprises a logic unit. The logic unit may, for example, be activated via the USB in terface or via the Ethernet input. In addition, the logic unit is also used to actuate the so-called GSM module or to be actuated from a cloud via the GSM module. The logic unit is software which receives queries, input commands, or param eters from said interfaces and executes corresponding in structions .

A data processing cloud is intended to be understood here to mean an arrangement having one or more data storage devices and one or more data processing devices which can be designed through suitable programming to perform any given data pro cessing operations. The data processing devices normally rep resent universal data processing devices here, such as, for example, servers which initially have no specific design whatsoever in terms of their construction and programming. The universal data processing device is not capable of per forming specific functions until it has been programmed. If the data processing cloud has a plurality of individual components, said components are interconnected in a suitable manner for data communication, for example by means of a com munication network. Any given data can be fed to a data pro cessing cloud for data storage and/or processing. The data processing cloud in turn makes the stored data and/or the events of the performed data processing available to other devices, for example computer workstations, laptops, smartphones connected to a data processing cloud. A data pro cessing cloud can be provided, for example, by a datacenter or a plurality of networked datacenters. A data processing cloud is normally spatially distanced from the high-voltage devices.

The connection between the communication box and the data processing cloud is established via a long-range communica tion connection. In order to set this up, the communication unit has a long-range communication device, such as, for ex ample, a mobile radiocommunication module according to the GPRS or UMTS standard. A long-range communication connection, preferably an IP-based data connection, to the data pro cessing cloud is set up with said module. A provider of a mo bile radiocommunication service, for example, or a telecommu nications provider can be interposed, and the long-range com munication connection can be set up at least partially via a communication network of this provider and/or at least par tially via the Internet. Only a very low configuration or pa rameterization cost is then incurred in setting up the con nection. Apart from the configuration of the long-range com munication device with the information required to set up the long-range communication connection, e.g. the installation of a SIM card of a telecommunication provider, no further cost needs to be incurred for the individual communication unit.

According to another embodiment of the invention each charger unit comprises a low voltage equipment. The low voltage equipment may include a converter for converting AC volage to DC voltage or AC current to DC current, a power meter, digi tal charging controllers, a monitoring device and communica tion means. The said converter is used as a rectifier to gen erate the necessary DC voltage for the charging process. Usu ally, power grids provide AC voltages and AC currents. Power meters are used for measuring the charging voltage and charg ing currents. The charging process can be controlled by one or more controllers whereby one or more monitoring device may interrupt the charging process in case of failure. The moni tor device may also inform a user about the duration of the charging process. The communication means may be used for billing purposes.

According to a further variant of the inventions the electri cal device is equipped with a cell phone antenna, a display for advertisements, cameras, weather-, air quality or traffic monitoring devices. All these components are energized by the output of the distribution transformer.

Additional expedient embodiments and advantages of the pre sent invention are disclosed in the following description of exemplary embodiments of the present invention, with refer ence to the figures of the drawing, wherein identical refer ence signs refer to identically acting components.

Figure 1 illustrates a first embodiment of the invention.

Figure 2 illustrates a second embodiment of the invention.

Figure 1 shows a first embodiment of the electrical device 1 according to the invention. The electrical device 1 comprises a transformer container 2 adjacent to a charger container 3. The charger transformer container 2 and the charger container 3 are attached to a support frame 4 which rests on the ground. The containers 2 and 3 are made of sheet metal. The support frame is also made of metal sheet having a thickness that allows the support frame to hold the transformer con tainer 2 over the charging container 3. A distribution transformer 5 is arranged in the transformer container 2 together with a communication box 6. The distri bution transformer is a so-called dry type transformer equipped several transformer sensor (not shown) for measuring winding currents flowing through a primary and secondary winding of the distribution transformer. The said transformer sensors are connected by blue tooth connection with the com munication box 6 which in turn is connected with a data pro cessing cloud 7 (not shown). The input of the distribution transformer 5 can be connected with a distribution network having a supply voltage between 10 - 30 kV. The output of the distribution transformer 5 is connected by a supply cable 7 with a low voltage equipment located in the charger container 3.

The low voltage equipment comprises an ac-dc converter based on power electronic components to convert the ac voltage of the transformer output to a dc voltage. The ac-dc converter is connected with electrical vehicle chargers 8 by cables 9. Loose ends of the cables 9 represent plug connectors for con nection with the car.

On top of the transformer container 2 a cell phone antenna 10, an environmental parameter monitor 11 and a display for advertisement 12 are located.

Figure 2 shows another embodiment of the electrical device laccording to the invention. In contrast to the embodiment shown in figure 1 the transformer container and the charging container are designed as a stand alone transformer cabinet 2 and a stand alone charger cabinet 3. The transformer cabinet is provided with doors 13 for an easy access to the distribu tion transformer inside the transformer cabinet 2. Loose ends of the cables 9 represent plug connectors.

The larger cabinets 2 and 3 allow to accommodate larger com ponent coping with higher powers.

Claims

Patent Claims

1.An electrical device (1) for charging an electric vehicle comprising a tranformer container (2) and at least one charger container (3), a transformer unit provided with a distribution transformer (5), which is connectable to a high voltage power grid and at least one charger unit provided with at least one electrical vehicle charger (8), wherby the distribution transformer (5) is arranged in the transformer container (2) and each charger unit is arranged in an allocated and seperate charger container (3), c h a r a c t e r i z e d in that the charger container (3) and the transformer container (2) are arranged adjacent to each other.

2.The electrial device (1) as claimed in claim 1 charactrized by a support frame (4), wherin the transformer container (2) and the charger container (3) are attached to the said support frame (4).

3.The electrial device (1) as claim in claim 1 charactrized in that the transformer container is designed as a stand alone transformer cabinet (2) and and each charger container is designed as a stand alone charger cabinet (3) wherin the transformer cabinet and each charger cabinet are positioned side by side.

4.The electrial device (1) as claimed in one of the pre ceding claims, characterized in that the transformer container (2) comprises a communication box (6) wherein the distribution transformer (5) is equipped with transformer sensors connected with the said communication box (6) and wherin the communication box (6) is connectable with a data processing cloud.

5. The electrial device (1) as claimed in one of the pre- ceding claims, characterized in that each charger unit comprises low voltage equipment.

6. The electrial device (1) as claimed in claim 5, charac terized in that the low voltage equipment comprises a power converter for converting AC volage to DC voltage, a power meter, a charging controller, a monitoring de vice and communication means.

7. The electrial device (1) as claimed in one of the pre ceding claims, characterized by a cell phone antenna (10), a display for advertisements (12), cameras, weath er-, air quality or traffic monitoring devices (11).