KR102482956B1 - Superconducting dispenser device for electric vehicle charging - Google Patents

Abstract

The present invention relates to a superconducting dispenser device for charging an electric vehicle, and more particularly, by supplying a refrigerant through a screw-shaped refrigerant pipe surrounding a linear superconducting core, providing an effect as if it has been rotated several times even at a low speed, thereby increasing energy efficiency. electric vehicle charging that can further increase energy efficiency by efficiently rotating the provided refrigerant by providing a screw rotation method and a vibration method in combination by providing ultrasonic vibration elements having multiple vibration points along the refrigerant pipe. It relates to a superconducting dispenser device for use.

Description

Superconducting dispenser device for electric vehicle charging}

The present invention relates to a superconducting dispenser device for charging an electric vehicle, and more particularly, by supplying a refrigerant through a screw-shaped refrigerant pipe surrounding a linear superconducting core, providing an effect as if it has been rotated several times even at a low speed, thereby increasing energy efficiency. electric vehicle charging that can further increase energy efficiency by efficiently rotating the provided refrigerant by providing a screw rotation method and a vibration method in combination by providing ultrasonic vibration elements having multiple vibration points along the refrigerant pipe. It relates to a superconducting dispenser device for use.

As global warming accelerates, weather disasters occur and life is threatened by severe climate change.

In response, strong carbon dioxide regulations are voicing their voices around the world, and the automobile industry is facing a new phase in accordance with these environmental and social demands. Interest in eco-friendly vehicles is increasing.

These eco-friendly vehicles include hybrid electric vehicles (HEVs) that use both an internal combustion engine and electric energy, electric vehicles (EVs) that use only electric energy, and fuel cell vehicles that use fuel cells (FCEVs; Fuel Cell Electric Vehicle), etc.

Demand and supply of electric vehicles are expected to increase rapidly, such as Korea's decision to mass-produce electric vehicles in response to the global trend to reduce carbon dioxide emissions.

In addition, electric vehicles such as plug-in-hybrid electric vehicles (PHEVs) have advantages such as low energy consumption and low air pollution.

Such an electric vehicle plays an important role in solving environmental pollution and energy saving, especially in the paradigm of a smart grid.

With the rapid use of electric vehicles, many studies have been conducted on the effect of electric vehicle loads on a power grid.

With the spread of electric vehicles, infrastructure for electric vehicle charging facilities is gradually being expanded.

In the early days, electric vehicles were charged for a long time with low power, but it took a considerable amount of time compared to conventional internal combustion engine vehicles, causing inconvenience to many users.

In order to solve this inconvenience, research and development on a technology for rapid charging with high power in a short time is actively underway.

However, for rapid charging, a system for cooling a charger (charging terminal) is essentially required.

A cooling system is used for the purpose of cooling heat generated from a power transmission line during rapid charging.

In rapid power transmission, cooling is very dominant to charging efficiency.

In general, metal is judged to be a better system because its electrical conductivity increases as the temperature increases, electrical loss decreases, and power charging efficiency increases. However, since both the charging terminal (dispenser) and the vehicle must have thermal durability, the system is A weight increase occurs due to an increase in unit price and an increase in the thickness of the transmission line (including the dispenser part).

Therefore, there is a need for a cooling system for a charger and transmission line (including a dispenser unit) capable of maintaining cooling at room temperature even when power is rapidly supplied, and having robust stability and high charging efficiency even during long-term charging.

Korean Patent Registration No. 10-1972778

Therefore, the present invention has been made to solve the above conventional problems,

An object of the present invention is to provide a refrigerant through a screw-shaped refrigerant pipe surrounding a linear superconducting core, form a refrigerant layer outside the superconducting core by centrifugal force during rotation of the refrigerant, and circulate to suppress water generation inside the power line. to provide an effect.

Another object of the present invention is to provide ultrasonic vibration elements having a plurality of vibration points along a refrigerant pipe to provide an effect as if they rotated several times even at a low speed.

In order to achieve the problem to be solved by the present invention, a superconducting dispenser device for charging an electric vehicle according to an embodiment of the present invention,

AC power provided from a stationary charger or mobile charger is converted into DC power or DC power is converted into DC power, the converted DC power is supplied to the superconducting unit 300, and the dispenser unit 400 connected to the superconducting unit DC power A power supply means 100 for supplying; and

A cooling means 200 comprising a refrigerant tank and supplying refrigerant to the superconducting unit 300 connected between the refrigerant tank and the dispenser unit; and

A superconducting unit 300 including a superconducting conductor layer therein and including a refrigerant tube for cooling the superconducting conductor layer into a superconducting state;

The object of the present invention is solved by including a dispenser unit 400 connected to one side of the superconducting unit 300 to charge an electric vehicle.

The superconducting dispenser device for charging electric vehicles according to the present invention,

A refrigerant is provided through a screw-shaped refrigerant pipe surrounding the linear superconducting core, and when the refrigerant rotates, a refrigerant layer is formed on the outside of the superconducting core by centrifugal force and circulated to provide an effect of suppressing water generation inside the power line.

In addition, by providing ultrasonic vibration elements having a plurality of vibration points along the refrigerant pipe, an effect as if they were rotated several times even at a low speed is provided to improve energy efficiency.

That is, by minimizing heat generation and maximizing electrical efficiency to increase working hours, it is possible to simultaneously provide economic effects and convenience in use.

In addition, the rotational force of the refrigerant and the ultrasonic waves form an insulation layer by the refrigerant therein, thereby suppressing the generation of water in the superconducting part.

1 is an overall configuration diagram of a superconducting dispenser device for charging an electric vehicle according to an embodiment of the present invention.
FIG. 2 is a configuration diagram specifically showing a cooling means 200 of a superconducting dispenser device for charging an electric vehicle according to an embodiment of the present invention.
3 is a cross-sectional view of a superconducting core 310 of a superconducting dispenser device for charging an electric vehicle according to an embodiment of the present invention.
4 is a cross-sectional view of a superconducting unit 300 of a superconducting dispenser device for charging an electric vehicle according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention.

However, the present invention may be embodied in many different forms and is not limited to the embodiments set forth herein.

And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Hereinafter, an embodiment of a superconducting dispenser device for charging an electric vehicle according to the present invention will be described in detail.

In the following description of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Throughout the specification, when a part "includes" a certain component, it means that it may further include other components without excluding other components unless otherwise stated, and also described in the specification. Terms such as “unit” and “module” refer to a unit that processes at least one function or operation, and may be implemented as hardware, software, or a combination of hardware and software.

1 is an overall configuration diagram of a superconducting dispenser device for charging an electric vehicle according to an embodiment of the present invention.

As shown in FIG. 1, the superconducting dispenser device for charging an electric vehicle according to the present invention,

AC power provided from a stationary charger or mobile charger is converted into DC power or DC power is converted into DC power, the converted DC power is supplied to the superconducting unit 300, and the dispenser unit 400 connected to the superconducting unit DC power A power supply means 100 for supplying; and

A cooling means 200 comprising a refrigerant tank and supplying refrigerant to the superconducting unit 300 connected between the refrigerant tank and the dispenser unit; and

A superconducting unit 300 including a superconducting conductor layer therein and including a refrigerant tube for cooling the superconducting conductor layer into a superconducting state;

It is characterized in that it is configured to include; a dispenser unit 400 connected to one side of the superconducting unit 300 to charge an electric vehicle.

Specifically, the power supply means 100 converts AC power provided from a stationary charger or mobile charger into DC power or DC power into DC power, and supplies the converted DC power to the superconducting unit 300, It serves to supply DC power to the dispenser unit 400 connected to the superconducting unit.

Examples include AC/DC converters and DC/DC converters.

An AC/DC converter converts AC power into DC power, or a DC/DC converter adjusts the size of the converted voltage back to an appropriate voltage supplied to the electric vehicle.

Therefore, the output of the DC/DC converter can be substantially supplied to the electric vehicle.

The cooling means 200 includes a refrigerant tank and performs a function of supplying refrigerant to the superconducting unit 300 connected between the refrigerant tank and the dispenser unit.

Specifically, as shown in FIG. 2, in order to perform the above function, the cooling means 200,

A refrigerant tank 210 in which refrigerant is stored; and

A pump unit 220 connected to the refrigerant tank and supplying the refrigerant stored in the refrigerant tank to the control valve;

A control valve 230 opened to supply refrigerant to the superconducting unit 300 when the electric vehicle is charged under the control of the control unit; and

A rotating part 240 connected to one end of the refrigerant pipe formed in the superconducting part 300 to rotate the refrigerant circulated through the refrigerant pipe;

It is connected to the rotating part and is configured to include; a recovery tank 250 for recovering water among liquid refrigerant and water separated by density difference by rotation.

Specifically, the pump unit 220 is connected to the refrigerant tank to supply the refrigerant stored in the refrigerant tank to the control valve.

At this time, the control valve 230 is opened to supply the refrigerant to the superconducting unit 300 when the electric vehicle is charged under the control of the control unit.

In the case of the control unit, which is generally configured in an electric vehicle charging system, it is opened by providing an operation signal to a control valve configured in a dispenser unit requesting electric vehicle charging to provide refrigerant to the superconducting unit 300.

Also, the rotating part 240 is connected to one end of the refrigerant pipe formed in the superconducting part 300 to rotate the refrigerant circulated through the refrigerant pipe.

At this time, the recovery tank 250 is connected to the rotating part, and when the rotating part rotates, centrifugal force is generated by rotation, so that liquid refrigerant and water are separated due to a difference in density.

At this time, the separated water is recovered.

In addition, it is generally possible to provide the separated liquid refrigerant to the refrigerant tank.

Meanwhile, the superconducting unit 300 includes a superconducting conductor layer therein, and includes a refrigerant tube for cooling the superconducting conductor layer into a superconducting state.

At this time, a characteristic feature is that the refrigerant pipe is configured in a screw shape along the outer appearance of the superconducting core part.

Meanwhile, the material of the refrigerant pipe may be made of a metal material or a plastic material.

Through this, the refrigerant is supplied through the screw-shaped refrigerant pipe, and a refrigerant insulating film is formed as a layer of a high-density material on the outer part of the refrigerant pipe by the centrifugal force generated when the refrigerant rotates by the screw-type, thereby conducting superconductivity. An effect of suppressing water generation in the unit 300 is also provided.

In addition, energy efficiency is improved by providing an effect as if it has rotated several times even at a low speed through one or more ultrasonic vibration elements.

Specifically, as shown in FIGS. 3 and 4, the superconducting unit 300,

A former 311 for passing a fixed current and maintaining a cable shape; and

an inner superconducting conductor layer 312 for transmitting load current; and

An insulating layer 313 for voltage isolation; and

an outer superconducting conductor layer 314 for transmitting load current; and

A superconducting core part 310 including a protective layer 315 for covering the outer circumference of the outer superconducting conductor layer and protecting it;

A core protection tube 320 including the plurality of superconducting cores therein;

Refrigerant tubes 330 formed along the outer surface of the core protective tube 320 to form a refrigerant passage for cooling the inner superconducting conductor layer 312 and the outer superconducting conductor layer 314 in a superconducting state, and

It is characterized in that it is configured to include a storage tube 340 for housing the superconducting core unit 310, the core protection tube 320, and the refrigerant tube 330.

The superconducting unit 300 of the present invention can enable lossless large-capacity power transmission by using superconductivity, lowering liquid helium and liquid nitrogen to a cryogenic state of 196 degrees below zero or higher, and using superconducting materials such as niob and nioptitanium for the conductor. will do

That is, the former 311 performs a function of passing a fixed current and maintaining a cable shape.

In general, it may have a twisted wire structure in which a plurality of wires are twisted, or may have a hollow structure using a metal pipe or a spiral band.

In the case of electronics, particularly in the case of alternating current applications, a coated metal wire such as a copper wire having an insulating coating can be suitably used for the bare wire, but metal wires such as bare copper wire can also be used, particularly in the case of direct current applications. there is.

In the case of the latter, an aluminum (alloy) tube or the like can be suitably used, and the inside thereof can also be used as a flow path for the refrigerant.

In the case of an aluminum (alloy) pipe, it is possible to use a straight pipe because of its excellent flexibility.

On the other hand, the material of the refrigerant pipe is composed of metal or plastic.

In this example, a former having a twisted pair structure in which coated or uncoated metal wires are twisted is shown, and a cushion layer (not shown) may be provided between the former and the inner superconducting conductor layer.

The inner superconducting conductor layer 312 serves to transmit load current.

For example, a tape-shaped wire having an oxide superconductor may be used, and as the tape-shaped wire, for example, a Bi2223-based superconducting tape wire or a RE123-based thin-film wire may be used.

Examples of the Bi2223 superconducting tape wire include a sheath wire in which a filament made of a Bi2223 oxide superconductor is disposed in a stabilized metal such as Ag-Mn or Ag.

Examples of RE123 thin film wires include laminated wires in which an oxide superconducting phase of rare earth elements RE such as Y, Ho, Nd, Sm, and Gd is formed on a metal substrate.

The inner superconducting conductor layer 312 may have a single-layer structure or a multi-layer structure formed by spirally winding the tape-shaped wire.

The insulating layer 313 performs a function for voltage insulation, and is a layer for securing insulation required for a voltage used in the inner superconducting conductor layer.

For the insulating layer, a material that has been proven in normal-conducting cables and has excellent electrical insulating strength, for example, a composite tape of insulating paper and a plastic layer, or kraft paper can be suitably used.

Examples of the composite tape include PPLP, and in the case of such laminated tape insulation, a composite insulator impregnated with an insulating liquid between the gaps can be used.

A specific example of the insulating liquid is liquid nitrogen, which is compatible with a refrigerant. The liquid nitrogen is filled into the core protective tube 320 to impregnate the superconducting core 310 and make the insulating layer a composite insulator of the insulating liquid and tape material.

When the superconducting core unit 310 is not impregnated with a refrigerant, an extruded layer of crosslinked polyethylene or the like may be used as an insulating layer in a CV cable or the like in which an insulating liquid is unnecessary.

When the superconducting core unit 310 is immersed in the auxiliary refrigerant, insulating paper such as the composite tape or kraft paper may be suitably used for the insulating layer.

Between the insulating layer and the inner superconducting conductor layer and between the insulating layer and the outer superconducting conductor layer, a semiconducting layer (not shown) effective for obtaining generally stable electrical characteristics is provided.

The outer superconducting conductor layer 314 serves to transmit load current. In the case of a DC cable, in single-pole power transmission, the inner superconducting conductor layer and the outer superconducting conductor layer serve as a forward path and a return path of current. ) can be used as an outgoing conductor layer or a return conductor layer constituting the

In bipolar power transmission, for example, two superconducting cables are used, each inner superconducting conductor layer of each superconducting cable is used as an outgoing conductor layer and a return conductor layer, and each outer superconducting conductor layer can be used as a neutral wire.

In the case of an AC cable, the outer superconducting conductor layer can be used as a magnetic shield.

This outer superconducting conductor layer is also made of the same superconducting wires as the inner superconducting conductor layer.

The outer superconducting conductor layer is usually provided, but it is not essential and may be provided as needed.

In particular, in direct current transmission, when the inner superconducting conductor layer is used as the outgoing path of current and the outer superconducting conductor layer is used as the return path of current, the current carrying capacity determined by the cross-sectional area of each conductor layer is equalized in both conductor layers, and the outgoing current and It is important to allow the current to flow through the outer superconducting conductor layer in equal return.

The protective layer 315 covers the outer circumference of the outer superconducting conductor layer and serves to protect it.

Specifically, the outer circumference of the outer superconducting conductor layer is covered, the outer superconducting conductor layer is protected, and insulation from the housing tube 340 is ensured.

The protective layer may be formed by winding kraft paper or the like, and a normal conducting layer (not shown) may be provided on the inside of the protective layer, similarly to a superconducting cable.

At this time, the normal conduction layer can be used as a flow path for an ideal current.

The core protection tube 320 is characterized by including a plurality of superconducting cores therein.

For example, it includes three superconducting cores inside, and through this, it is possible to maintain internal conditioning from external pressure.

The refrigerant tube 330 forms a refrigerant passage that cools the inner superconducting conductor layer 312 and the outer superconducting conductor layer 314 in a superconducting state, and is formed in plurality along the outer surface of the core protective tube 320. .

A refrigerant flows through the refrigerant tube and cools the superconducting conductor layer of the superconducting core part 310 to maintain it in a superconducting state.

A straight pipe or a corrugated pipe can be suitably used for this refrigerant pipe.

A straight pipe is easy to smoothly distribute the refrigerant with a small pressure loss, and a corrugated pipe has a slightly higher pressure loss than a straight pipe, but has excellent flexibility.

Regarding the arrangement type and number of coolant tubes for the superconducting core part 310, the coolant tubes are arranged along the superconducting core part 310, and the superconducting core part 310 is cooled to the required temperature by the refrigerant flowing in the coolant tubes. It may be of any form or number as long as it satisfies the condition to be.

For example, a required number of refrigerant tubes having a required inner diameter may be formed on the outer circumference of the superconducting core unit 310, or the refrigerant tubes may be arranged vertically in the superconducting core unit 310.

As shown in FIG. 3, if the refrigerant tube is twisted in one direction around the outer circumference of the superconducting core part 310, it is easy to uniformly cool the superconducting core part 310 over its entire circumference.

In particular, when the three superconducting core parts 310 are twisted, the contact area between the coolant tube and the superconducting core part 310 is increased by arranging the refrigerant tube to match the twisted groove of each superconducting core part 310. The superconducting core part 310 can be efficiently cooled.

The inner diameter and number of refrigerant tubes and the density of the arrangement of the refrigerant tubes outside the cable core or inner housing tube depend on how the length of the cooling section, the flow rate of the refrigerant, and the outer diameter of the housing tube housing the refrigerant tube are designed. It should be set so that it can cool sufficiently.

At this time, preferably, by constructing the refrigerant pipe along the outer appearance of the superconducting core in the form of a screw, a refrigerant insulating layer is formed by the centrifugal force of screw rotation, and the temperature of the superconducting part is efficiently maintained by suppressing the generation of water (than conventional copper wire). ) characterized in that it can improve electrical efficiency.

That is, the refrigerant rotates along the outer surface of the superconducting core, and when it rotates in this way, the superconducting core in the middle stays with the refrigerant, and the material that melts at the part in contact with the outside air can be confirmed by rotation in the cross section of the screw. , the centrifugal force causes the heavy material to flow along the outer part, preventing water from forming throughout the refrigerant tube.

Therefore, the water will occupy the outer part of the wire by the centrifugal force.

In addition, when the refrigerant is pumped out and circulated to recover the refrigerant again, the refrigerant and water can be separated and recovered. The difference in density due to the centrifugal force caused by rotation separates the liquid refrigerant and water, and the separated water is recovered. It will be recovered from the tank.

Also, the housing tube 340 serves to house the superconducting core unit 310, the core protection tube 320, and the refrigerant tube 330.

On the other hand, according to an additional aspect, the ultrasonic vibration element 500 is further included along the outer appearance of the superconducting unit 300 at regular intervals, thereby providing a screw rotation method and a vibration method in combination to provide a refrigerant Since it can rotate efficiently, it is possible to provide an effect that can further increase energy efficiency.

As described above, when the ultrasonic vibration element is configured, when the refrigerant is supplied, a control signal from a control unit (not shown) is provided to the plurality of ultrasonic vibration elements to vibrate.

At this time, the wireless communication module is mutually configured to provide an operation signal to the ultrasonic vibration element.

That is, since it is configured along the outer appearance of the refrigerant pipe configured in the form of a screw, the rotation of the refrigerant is further increased.

Through the above configuration, the refrigerant is provided through the screw-shaped refrigerant tube surrounding the linear superconducting core, so that an effect as if the superconducting core has been rotated several times even at a low speed is provided, thereby improving energy efficiency.

In addition, by providing ultrasonic vibration elements having a plurality of vibration points along the refrigerant pipe, the screw rotation method and the vibration method are provided in combination to efficiently rotate the provided refrigerant, so that energy efficiency can be further increased.

That is, by minimizing heat generation and maximizing electrical efficiency to increase working hours, it is possible to provide economic effects and convenience in use at the same time.

In addition, the rotational force of the refrigerant and the ultrasonic waves form an insulation layer by the refrigerant therein, thereby suppressing the generation of water in the superconducting part.

Those skilled in the art to which the present invention pertains as described above will understand that it can be implemented in other specific forms without changing the technical spirit or essential characteristics of the present invention. Therefore, the embodiments described above are illustrative in all respects and should be understood as non-limiting ones.

100: power supply means
200: cooling means
300: superconducting unit
400: dispenser unit
500: ultrasonic vibration element

Claims (2)

In the superconducting dispenser device for charging electric vehicles,
AC power provided from a stationary charger or mobile charger is converted into DC power or DC power is converted into DC power, the converted DC power is supplied to the superconducting unit 300, and DC power is supplied to the dispenser unit 400 connected to the superconducting unit. A power supply means 100 for supplying; and
A cooling means 200 comprising a refrigerant tank and supplying refrigerant to the superconducting unit 300 connected between the refrigerant tank and the dispenser unit; and
A superconducting unit 300 including a superconducting conductor layer therein and including a refrigerant tube for cooling the superconducting conductor layer into a superconducting state;
A dispenser unit 400 connected to one side of the superconducting unit 300 to charge an electric vehicle; and
A plurality of ultrasonic vibration elements 500 formed at regular intervals along the exterior of the superconducting part 300;
The cooling means 200,
A refrigerant tank 210 in which refrigerant is stored; and
A pump unit 220 connected to the refrigerant tank and supplying the refrigerant stored in the refrigerant tank to the control valve;
A control valve 230 opened to supply refrigerant to the superconducting unit 300 when the electric vehicle is charged under the control of the control unit; and
A rotating part 240 connected to one end of the refrigerant pipe formed in the superconducting part 300 to rotate the refrigerant circulated through the refrigerant pipe;
It is connected to the rotating part and is characterized in that it is configured to include a; recovery tank 250 for recovering water from the liquid refrigerant and water separated by the difference in density by rotation,
The superconducting part 300,
A superconducting dispenser device for charging an electric vehicle, characterized in that it includes a superconducting core and improves electrical efficiency by configuring a refrigerant pipe in a screw shape along the outer appearance of the superconducting core.
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