KR101269224B1 - Module type of non-touch power supply - Google Patents

Abstract

The present invention relates to a modular non-contact power supply device, a power supply device for transmitting electric power to the electric vehicle in a self-induction method, embedded in the road surface along the traveling direction of the road and the air tightly sealed out the case, the out Both sides of the outer case by alternately winding an inner case installed at an inner bottom of the case, a plurality of magnetic poles having a plurality of magnetic poles arranged at regular intervals disposed on an upper surface of the inner case, and a magnetic pole of the feeding core Disclosed is a modular non-contact power feeding device including a feed line connected to a terminal formed at a stage and a resonance capacitor electrically connected to the feed line and installed inside the out case. From this, it is modularized by including a pressure adjusting tube for maintaining a constant internal pressure change of the outer case or a pump for injecting or exhausting air into the outer case, and a heat dissipating unit for maintaining a constant temperature inside the outer case. When the power feeding device is embedded and the power feeding devices can be easily connected to each other, the construction can be easily connected, and there is an effect that the repair and replacement of the damaged power feeding device can be performed quickly.

Description

Modular Non-Contact Feeder {MODULE TYPE OF NON-TOUCH POWER SUPPLY}

The present invention relates to a modular non-contact power feeding device, and more particularly, the power feeding device can be modularized so as to have a structure that has excellent heat dissipation and waterproofness, and can be easily embedded in a driving path, and thus the electric power feeding devices can be easily connected. The present invention relates to a modular non-contact power supply device capable of smoothly supplying power to a current collector of an electric vehicle.

In order to charge a battery of an existing electric vehicle or a plug-in hybrid vehicle, there is a drawback of connecting to an electric network for a certain time by using a plug connected to the outside of the vehicle. With the currently developed battery technology, the distance that the vehicle can travel is limited only by one charge, and the charging time is long.

In addition, even if the battery is charged using the rapid charger, it takes more than 1 hour, and the latest advanced technology takes more than 10 minutes. Therefore, in order to solve the above problems, a technology for increasing the capacity of the battery and increasing the efficiency of the charging system has been developed, but using a heavy battery increases the weight and volume of the vehicle, which not only reduces the performance of the vehicle but also the production price of the vehicle. There is a problem that the life of the battery is shortened instead of shortening the charging time of the battery by increasing the rapid charge.

Therefore, in order to solve problems such as excessive battery capacity which is the biggest problem of existing battery electric automobile, increase of vehicle weight and volume, increase of cost, long charging time or large capacity charging facility, low charging efficiency, shortening of battery life, A non-contact type power feeding system using induction is being developed.

The non-contact power supply system charges electric power in a non-contact manner by using electromagnetic induction to the current collector device from the power supply device facing the current collector device with a gap, such a non-contact power supply system is a power supply device is installed on a predetermined driving path and the A current collector is installed at the bottom of the vehicle traveling upwards to transfer power to the power supply of the vehicle passing the driving path, thereby delivering power for the vehicle to travel and collecting surplus power not used for driving the vehicle. The device will charge the battery.

When a vehicle having such a non-contact power supply system is driven out of a driving path where a power supply device is installed, the vehicle is driven by using electric power charged in a battery installed in the vehicle.

In particular, since the power supply device installed in the driving path must continuously supply electric power to the current collector of the vehicle, the power feeding device is continuously installed along the driving path. 1 is a cross-sectional view showing a part of a traveling path provided with a conventional power feeding device.

Referring to the drawings, a substantially "T" shaped recessed groove 2 is formed on the road surface 1 of the driving path, and a power feeding device 10 is installed inside the embedded groove 2. The power feeding device 10 has a predetermined length and a hollow case 11, a feed core 12 installed inside the case 11, and a feed line 13 wound around the feed core 12. After the power feeding device 10 is buried in the buried groove (2) is installed in the upper portion is packed with ascon (3).

The power feeding device 10 having the above configuration is manufactured to have a predetermined length and is continuously installed on the road surface 1 of the driving path, and the current collecting device of the vehicle passing through the power feeding device 10 (not shown). To deliver power. That is, when the power supply device is installed in the buried groove 2 of the driving path as described above, the power supply device is buried close to the power supply source supplying power first, and then the power supply device is sequentially embedded and electrically connected. It is possible to install a power feeding device on the driving path.

However, when the length of the driving path becomes longer and the length of the feeding devices installed on the driving path increases, the length of the feeding line also increases, so that the voltage applied to the feeding device installed far from the power supply is not only unstable, but also continuously electric. Due to the resistance of the feeder is flowing through the temperature increase inside the feeder to prevent the breakage of the feeder to smooth operation of the feeder.

In addition, since the traveling path in which the power feeding device is installed is exposed to a harsh environment, it adversely affects the operation of the power feeding device installed in the driving path, thus causing a problem of smoothly transferring power to the current collector of the vehicle.

In addition, in Korea, where the four seasons are distinct, the temperature difference is clear according to the season, and snow, rain, and precipitation or rainfall are different accordingly. For example, in mid-July, which is a hot summer, the road's midday temperature reaches 50 ° C, but the night's road temperature drops to 25 ° C, accompanied by heavy rains during the rainy season.

Such a rise in the road surface temperature in the summer raises the temperature inside the power supply device installed in the driving path, causing the parts to be damaged by thermal expansion or to break the electrical connection between the parts, resulting in inoperability. In addition, when moisture caused by heavy rain penetrates into the power feeding device, the durability of the parts may be reduced or the electrical connection between the parts may be prevented, thereby causing malfunction.

In addition, in winter, the cold accompanied by heavy snow causes freezing on the road surface, and the freezing of the road leads to a vehicle accident, so that a large amount of calcium chloride is removed to remove snow and freezing of the road. Spray on. However, when the calcium chloride sprayed on the driving path penetrates into the inside of the power feeding device, it accelerates the corrosion of the metal component and prevents the smooth operation of the power feeding device.

The driving route of Korea exposed to such a harsh environment is usually designed / constructed to withstand the changes of about -20 ℃ ~ + 80 ℃, but the conventional power feeding device installed in the driving route has a temperature change and The change in pressure inside the power supply device due to the temperature change and the penetration of a material that adversely affects the parts of the power supply device such as moisture and calcium chloride can not be tolerated for a long time, causing breakage and inoperability of parts due to deterioration in durability. There is a problem in that the repair / replacement cycle is short and the cost increases.

The present invention has been made to solve the above problems, by embedding the feeder on the driveway to modularize the feeder so that it can be easily connected when the feeders are electrically connected to each other, the workability and excellent repair of the damaged feeder and It is an object of the present invention to provide a modular non-contact power supply that can perform a replacement quickly.

In addition, even if the length of the feeder increases along the driving path, each feeder has a stable voltage, and accordingly, even if the feeding device is located at a long distance from the power supply regardless of the total length of the feeder installed in the driving path. The purpose of the present invention is to provide a modular non-contact power feeding device capable of transferring electric power to a current collector of a vehicle.

Another object of the present invention is to provide a modular non-contact power feeding device having excellent waterproofness such that foreign matters that adversely affect moisture or components of the power feeding device do not penetrate into the power feeding device.

In addition, when the power supply device is provided with a sealed structure having excellent water resistance as described above to provide a modular non-contact power supply device that can quickly respond to the internal pressure change of the power supply device to prevent breakage or malfunction of parts. The purpose is.

In addition, it is possible to quickly and effectively release heat generated from itself in the power feeding device or the road surface of the driving path to the outside of the power feeding device, thereby improving the reliability of the power feeding device without causing breakage or malfunction of the power feeding device. Its purpose is to provide a modular non-contact power feeding device.

Technical concept of the present invention for achieving the above object, as a power supply device for transmitting electric power to the electric vehicle in a self-induction method, embedded in the road surface along the traveling direction of the driving path and the inside is hermetically sealed out case And alternately winding an inner case installed at an inner bottom of the outer case, a feeding core having a plurality of magnetic poles disposed at regular intervals provided on an upper surface of the inner case, and a magnetic pole of the feeding core. It is achieved by a modular non-contact power feeding device including a feed line connected to the terminals formed on both ends of the outer case and a resonant capacitor electrically connected to the feed line and installed inside the outer case.

Here, it is preferable that the inner case further includes a pressure control tube made of an elastic material containing the contents that are expanded or contracted in accordance with the change in the internal pressure of the outer case.

In addition, the contents contained in the pressure control tube is preferably any one of nitrogen, helium, argon, carbon dioxide.

On the other hand, according to another technical idea of the present invention for achieving the above object, as a power supply device for transmitting electric power to the electric vehicle in a self-induction method, is embedded in the road surface along the traveling direction of the road and hermetically sealed inside Alternating a power supply core having a plurality of magnetic poles disposed at regular intervals provided at an inner case of the outer case, an inner case installed on an inner bottom of the outer case, and an upper surface of the inner case; A winding wire connected to the terminals formed at both ends of the outer case by winding, a resonant capacitor electrically connected to the feeding line, and installed in the outer case, a pressure sensor for detecting a pressure change in the outer case; To the inside of the outer case according to the pressure change inside the outer case detected by the pressure sensor Group is achieved by a modular contactless power supply device including a pump for injecting or exhaust.

Here, it is preferable to further include an air conditioner installed on the flow path connecting the out case and the pump to dehumidify or cool the air inside the out case.

The apparatus may further include a check valve installed on a flow path for injecting or exhausting the air inside the out case and intermittently exhausting the air inside the out case to the outside when the pressure inside the out case falls below a predetermined pressure. desirable.

On the other hand, according to another technical idea of the present invention for achieving the above object, as a power supply device for transmitting electric power to the electric vehicle in a self-induction method, is embedded in the road surface along the traveling direction of the road and hermetically sealed inside Alternating a power supply core having a plurality of magnetic poles disposed at regular intervals provided at an inner case of the outer case, an inner case installed on an inner bottom of the outer case, and an upper surface of the inner case; A winding wire connected to terminals formed at both ends of the outer case, a resonant capacitor electrically connected to the feeding line, installed in the outer case, and in contact with a portion of the outer case and extending to a road surface of a driving path Modular non-contact power supply unit including a heat dissipation unit for transferring heat inside the outer case to the outside It is achieved by.

In this case, the heat dissipation unit preferably has a shape of a plate made of aluminum or graphite and is embedded toward the center of the earth.

On the other hand, according to another technical idea of the present invention for achieving the above object, as a power supply device for transmitting electric power to the electric vehicle in a self-induction method, is embedded in the road surface along the traveling direction of the road and hermetically sealed inside Alternating a power supply core having a plurality of magnetic poles disposed at regular intervals provided at an inner case of the outer case, an inner case installed on an inner bottom of the outer case, and an upper surface of the inner case; A winding wire connected to terminals formed at both ends of the outer case, a resonant capacitor electrically connected to the feeding line, and installed inside the outer case, and in contact with a portion of the outer case to a road surface of a driving path A heat dissipation unit which extends to transfer heat inside the outer case to the outside and an outer cable which is in surface contact with the heat dissipation unit Su is connected is achieved by a modular contactless power supply device including the outer case installed to the heating value of the parts installed in the group adjacent to the part or more set reference values, or the heat transfer medium, which is installed in close contact.

Here, it is preferable that a part of the out case which is in surface contact with the heat dissipating part is made of any one of aluminum or graphite.

In addition, the heat transfer medium may be connected to the heat dissipation part through the out case in a state in which the heat generation amount is installed adjacent to or in close contact with a part having a heat generation amount greater than or equal to a predetermined reference value among the parts installed in the out case.

In addition, the out case is preferably glass fiber reinforced plastics (FRP, Fiber Reinforced Plastics).

In addition, it is preferable that the outer case is open at both ends and forms a multistage inside each of the open ends to form a cover provided with a feed line connecting terminal.

In addition, it is preferable to have a structure in which the inside of the out case is hermetically sealed by interposing a gasket when the covers are respectively joined to both ends of the out case.

The apparatus may further include a connector installed between the out case buried at a predetermined distance along the traveling direction of the driving path and the next out case to electrically connect the feed line installed in the out case.

Here, the connector preferably includes a cap surrounding the space between the out case and the next out case, and a jump line electrically connecting the feed line installed inside the out case and the next out case in the cap.

The apparatus may further include a shielding part that seals the terminal and the periphery of the terminal in an airtight manner when electrically connecting the terminals of the out case and the next out case, wherein the shielding part is formed around the terminals of the out case and the next out case. It is preferable to include a coupler that is tightly fixed to the connector projecting from each and a corrugated pipe connecting between the coupler and the coupler.

And a shielding portion for hermetically shielding the terminal and the periphery of the terminal when the terminals of the out case and the next out case are electrically connected, wherein the shielding portion protrudes from a cover formed around the terminals of the out case and the next out case. Preferably, the connector includes a corrugated pipe having an end inserted into each end, and a tightening band for tightly fixing the end and the connector of the corrugated pipe by wrapping an outer diameter of the end of the corrugated pipe.

The core support may further include a core support provided between the power feeding core and the inner case and extending vertically toward the inside of the upper surface of the out case to support the out case and having a beam surrounding the pole of the power feeding core.

Here, the core support is formed in the support plate is installed on the upper surface of the inner case, the vertical beam extending from the support plate toward the inner side of the upper case and supporting the out case and the vertical beam adjacent to the pole of the feed core It is preferable to include a reinforcing part wrapped around the reinforcement.

In addition, the protrusion is formed on the upper surface of the support plate, it is preferable that a depression for coupling the protrusion with the protrusion is formed on the bottom surface of the feed core in contact with the upper surface of the support plate.

The modular non-contact electric power feeding device according to the present invention includes a pump for injecting or evacuating air into a pressure control tube or an outer case for maintaining a constant change in internal pressure of the outer case, and a heat dissipation for maintaining a constant temperature inside the outer case. Modularity, including the parts, can be easily connected when the power supply devices are embedded in the roadway, and the power supply devices can be easily connected to each other, thereby providing excellent workability and quick repair and replacement of the damaged power supply device. .

In addition, a resonant capacitor is installed inside the outer case so that the feeder of each feeder has a stable voltage even if the length of the feeder increases along the roadway, and thus, from the power source regardless of the total length of the feeder installed on the roadway. Even if the power feeding device is located at a long distance, power can be stably transmitted to the current collector of the vehicle.

In addition, since the outer case of the power feeding device embedded in the road surface of the driving path has a hermetically sealed structure, it has excellent waterproofness to prevent the ingress of foreign matter that adversely affects the moisture inside the power feeding device or the parts installed inside the out case. do.

In addition, when the power supply device is provided with a sealed structure having excellent water resistance as described above, it is possible to quickly respond to the internal pressure change of the power supply device, it is possible to prevent breakage or malfunction of parts.

In addition, it is possible to quickly and effectively release heat generated from itself in the power feeding device or the road surface of the driving path to the outside of the power feeding device, thereby improving the reliability of the power feeding device without causing breakage or malfunction of the power feeding device. have.

1 is a cross-sectional view showing a part of a traveling path provided with a conventional power feeding device.
2 is a perspective view showing a modular non-contact power feeding device according to the present invention.
Figure 3 is an embodiment showing the winding of the feeder wire wound on the feed core of the modular non-contact feeder according to the present invention.
Figure 4 is another embodiment showing the winding of the feeder wire wound on the feed core of the modular non-contact feeder according to the present invention.
5 is a wiring diagram showing the wiring of the feeder wire wound on the feed core of the modular non-contact feeder according to the present invention.
6 is a perspective view showing the connection of the modular non-contact power feeding device according to the present invention.
7 is a schematic view showing a state in which a pressurization device is applied to a modular non-contact power feeding device according to the present invention.
8 is a cross-sectional view showing a heat dissipation structure of the modular non-contact power feeding device according to the present invention.
9 is a cross-sectional view showing a modified heat dissipation structure of the modular non-contact power feeding device according to the present invention.
10 is a cross-sectional view illustrating a state in which a heat pipe is installed in the modular non-contact power feeding device according to the present invention.
11 is a cross-sectional view showing another embodiment of a heat pipe applied to a modular non-contact power feeding device according to the present invention.
12 to 14 is an exploded perspective view and a cross-sectional view and a plan view showing a state in which the shielding portion of the modular non-contact power supply according to the present invention is applied.
15 and 16 are exploded perspective views and cross-sectional views showing another embodiment of the shield of the modular non-contact power feeding device according to the present invention.
17 is a perspective view showing a core support of the modular non-contact power supply according to the invention.
18 is a cross-sectional view showing a state in which a core support is installed in the modular non-contact power feeding device according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing a modular non-contact power feeding device according to the present invention. Referring to the drawings, the modular non-contact power feeding device according to the present invention is a power feeding device for transmitting electric power to the electric vehicle in a self-induction method, buried in the traveling direction of the driving path and the inside is hermetically sealed out case ( A power feeding core having a plurality of magnetic poles 132 arranged at an interval between the inner case 120 and the inner case 120 installed on the inner bottom of the outer case 110. 130 and the feed line 140 and the feed line 140 electrically connected to terminals formed at both ends of the out case 110 by alternately winding the magnetic pole 132 of the feed core 130. It is composed of a resonant capacitor 150 connected to and installed inside the out case 110.

The out case 110 has a shape of a square pillar having an empty space therein and both ends are open, the out case 110 is preferably formed to have a length of about 1m length, so that the running path is bent Even in the case of the case, the plurality of out cases 110 may be buried in accordance with the traveling direction of the curved driving path.

The out case 110 buried in the road surface of the road as described above is preferably formed of glass fiber reinforced plastics (FRP, Fiber Reinforced Plastics). Here, glass fiber reinforced plastic is a generic term for resins that have improved mechanical strength by incorporating a fiber base into a synthetic resin. Such glass fiber reinforced plastics have a long life, light weight, strong and non-corrosive, and are light, durable, impact resistant, and abrasion resistant. This is an excellent, rust-proof, heat-deformable and easy to process, so that even if the outer case 110 is buried in the road surface of the long-term road, the appearance does not change, it is possible to reliably protect the components located inside the outer case 110 Can be.

In particular, since the out case 110 is buried in the road surface of the driving path, the out case 110 should be excellent in waterproofness so that moisture or foreign matter does not flow into the out case 110. To this end, the inner case 120, the power feeding core 130, the power feeding line 140, the resonant capacitor 150, and the like, which will be described later inside the outer case 110, with both ends of the out case 110 being opened. After the parts are assembled, both ends of the open outer case 110 are fixed to the cover 160 to hermetically seal the inside of the outer case 110.

In other words, the cover 160 is fixed to each of the open ends of the outer case 110, the surface of the outer case 110 and the cover 160 is maximized by the moisture and foreign matter and the outer case 110 After forming the multi-stage in each of both ends of the outer case 110 so as not to flow between the cover 160, the cover 160 having a shape corresponding to the multi-stage is coupled to both ends of the outer case 110, respectively It is fixed by a fastening member such as a fastening bolt.

As such, when the cover 160 is coupled to both ends of the outer case 110, the cover 160 is fixed by interposing the gasket 170 between the outer case 110 and the cover 160. The surface contact between the and the outer case 110 can be more hermetically sealed.

The gasket 170 is made of a soft resin such as rubber, and when the cover 160 is in close contact with the out case 110, the gasket 170 causes an external deformation between the cover 160 and the out case 110. The inside of the outer case 110 is in close contact with the airtight seal structure, and thus rainwater, snow, and the like flowing on the road surface of the driving path may be prevented from penetrating into the outer case 110. Here, the gasket 170 interposed between the cover 160 and the out case 110 may be replaced with a sealing member such as an o-ring in some cases.

Meanwhile, an inner case 120 is installed at an inner bottom of the outer case 110, and the inner case 120 forms an empty space therein to have a shape similar to that of the outer case 110, and the inner case Inside the 120, components such as a pressure regulating tube 210, a resonant capacitor 150, and the like, which are described later, are installed.

In particular, the inner case 120 is made of an aluminum material having excellent heat transfer, and has a rectangular pillar shape so that the feed core 130 and the feed line 140 may be installed on the upper surface of the inner case 120.

Therefore, the heat generated from the parts that are in close or in direct contact with the inner case 120, for example, the power supply core 130, the resonance capacitor 150, and the like, are transferred to the inner case 120. To cool.

At this time, the shape of the inner case 120 is not limited to the square pillar formed an empty space therein may be variously modified. For example, the inner case 120 has a shape such as "H", "I", "T", and each of the feed core 130 and the pressure control tube 210 and the upper and side surfaces of the inner case 120 and The resonance capacitor 150 may be installed.

A power supply core 130 is installed on the upper surface of the inner case 120, and the power supply core 130 has a plurality of magnetic poles 132 disposed at regular intervals. In the drawing, six magnetic poles are formed at regular intervals on the top of the power feeding core 130. However, in some cases, six or more magnetic poles 132 may be formed by narrowing the interval between the magnetic poles 132. The feed line 140 passes on the feed core 130 so that magnetic poles of the magnetic poles of the magnetic poles 130 of the 130, N pole, S pole can occur.

In this case, the feed line 140 passing over the feed core 130 is preferably connected to terminals formed at both ends of the out case 110 by alternately winding the magnetic pole of the feed core 130. This will be described with reference to FIGS. 3 and 5.

Figure 3 is an embodiment showing the winding of the feeder wire wound on the feed core of the modular non-contact feeder according to the present invention, Figure 4 shows the winding of the feeder wire wound on the feeder core of the modular non-contact feeder according to the present invention Another embodiment.

Referring to the drawings, a plurality of magnetic poles 132 are formed at regular intervals along an upper surface of the power feeding core 130, and a power supply line 140 through which power flows is provided with magnetic poles 132 of the power feeding core 130. Alternating windings are connected to terminals formed at both ends of the out case 110.

In other words, the feeder line 140 alternately winding the magnetic poles of the feed core 130 may alternately wind each magnetic pole 132 as shown in FIG. 3, or as illustrated in FIG. 4. As described above, two pairs of magnetic poles 132 may be used to alternately wind one pair of magnetic poles and another pair of magnetic poles.

In this way, the feed line 140 winding the magnetic pole of the feed core 130 may be made of a wiring as shown in FIG. 5 is a wiring diagram showing the wiring of the feeder wire wound on the feed core of the modular non-contact feeder according to the present invention.

Referring to the drawings, the power feeding device according to the present invention to protect the feed core 130 and the feed line 140 and the feed core 130 and the feed line 140 from the outside and easy to install on the road surface of the road As described above, the module is modularized to a predetermined length and manufactured.

Accordingly, the section marked as the connection section of FIG. 5 represents a portion where the power supply device and the power supply device are connected, and thus the connection between the power supply device and the power supply device is connected by a wire such as a jump line to allow some flow between the power supply devices. The power supply devices may be connected to each other, or the power supply devices may be in close contact, and the connection terminals formed at both ends of the outer case 110 may be directly connected to allow power to flow to the power supply line to flow to the next power supply device.

As such, when a plurality of power supply devices installed along the traveling direction of the driving path are connected to each other, the power supply devices may be closely connected to each other or electrically connected by a jump line, but water such as rain water may be connected through the connection section between the power supply devices. And it is preferable to be connected by the connector 180 to prevent foreign substances from entering and to stably protect the electrical connection between the power feeding device. This will be described with reference to FIG.

6 is a perspective view showing the connection of the modular non-contact power feeding device according to the present invention. Referring to the drawings, the connector 180 is installed between the out case 110 and the next out case 110 buried at a predetermined distance along the traveling direction of the driving path to the inside of the out case 110. In order to electrically connect the feed line 140 is installed, the connector 180 is a cap 182 surrounding the space between the out case 110 and the next out case 110 and the inside of the cap 182 The jump case 184 electrically connects the feed line 140 installed inside the out case 110 and the next out case 110.

Cap 182 surrounding the space between the out case 110 and the next out case 110 is preferably made of glass fiber reinforced plastic or the same as or equal to the out case 110 is embedded in the road surface of the long runway In this state, it is possible to reliably protect the electrical connection between the power supply devices.

Cap 182 for protecting the connection section of the feeder and the feeder may have the shape of a box with an open bottom that can cover the connection section, as shown in the drawing, in some cases empty It may be made in the shape of a box in which only a space is formed.

Meanwhile, the feeder line 140 alternately winding the magnetic poles 132 of the feeder core 130 is connected to the resonant capacitor 150 and stable in the corresponding feeder even when the length of the feeder increases along the driving path. It is electrically connected to the resonant capacitor 150 to have a voltage.

The resonant capacitor 150 is preferably installed inside the inner case 120 installed below the power supply core 130 to transfer heat generated by the operation of the resonant capacitor 150 to the inner case 120. Allow the resonant capacitor 150 to operate in an optimal state.

Although only one resonant capacitor 150 is shown inside the inner case 120, a plurality of resonant capacitors 180 may be installed according to the capacity of the power flowing along the feed line 140.

As the resonant capacitor 150 is installed inside the inner case 120 as described above, even if the power supply device is located at a long distance from a power supply source (not shown) that supplies power to the feeder line 140, the voltage of the corresponding power supply device is provided. It is possible to stably transmit electric power to the current collector of the vehicle passing through the power feeding device.

On the other hand, the inner case 120 is provided with a pressure control tube 210 together with the resonance capacitor 150. The pressure control tube 210 is expanded and contracted in response to a change in pressure in response to a change in the internal pressure of the hermetically sealed outer case 110 to expand and contract to maintain a constant pressure inside the outer case 110. The tube made of material is sealed with contents that expand or contract in response to pressure changes.

Herein, the stretched material includes a material such that rubber or silicone resin has a moderate elastic restoring force and does not tear when the contents are inflated rapidly or the contents are leaked. The contents of the tube made of such stretchable materials include materials that can increase or decrease their volume in response to pressure changes such as nitrogen, helium, argon and carbon dioxide.

When the pressure control tube 210 containing the contents sensitive to the pressure change as described above is installed in the inner case 120, the pressure control tube is expanded or contracted in accordance with the internal pressure change of the out case 110 to actively out. The internal pressure of the case 110 may be kept constant.

That is, when heat is generated in the hermetically sealed out case 110, the air inside the out case 110 is swollen and the pressure is increased. At this time, the contents contained in the pressure control tube 210 are contracted to The volume of the control tube 210 is reduced. As such, when the volume of the pressure adjusting tube 210 is reduced, the volume inside the outer case 110 increases by the volume difference of the reduced pressure adjusting tube 210 to maintain the total pressure inside the outer case 110 at a constant level. It becomes possible.

On the other hand, in order to maintain a constant pressure inside the out case 110, a pressure device may be installed separately from the pressure control tube to maintain a constant pressure inside the out case 110. This will be described with reference to FIG.

7 is a schematic view showing a state in which a pressurization device is applied to a modular non-contact power feeding device according to the present invention. Referring to the drawings, a pressure sensor 220 for detecting a pressure change in the outer case 110 having a hermetically sealed structure is installed in the outer case 110.

In addition, a pump 230 connected to one side or the cover 160 and the flow path 232 of the out case 110 is provided so that the pressure sensor 220 detects a pressure change inside the out case 110. If the pressure inside the outer case 110 is higher or lower than the set pressure, the pump 230 operates to inject or exhaust air into the outer case 110 to maintain a constant pressure inside the outer case 110. do.

At this time, the air conditioner 240 to dehumidify or cool the air supplied to the inside of the out case 110 on the flow path 232 connecting the out case 110 and the pump 230 or the inside of the pump 230 is It is provided to prevent moisture from entering the inside of the outer case 110 and to prevent the temperature rise in the outer case 110 due to the heat generated by the operation of the components installed in the outer case 110.

In addition, when the check valve 250 is installed on the flow path 232 for injecting or exhausting the air inside the out case 110 and the pressure inside the out case 110 falls below a set pressure, the out case 110 The internal air may be intermittently exhausted.

Thus, the power feeding device of the present invention to which the pressurization device is applied does not install the pump 230 for every out case 110 of the power feeding device when the power feeding device is embedded along the traveling direction of the driving path, and the pump 230 for each predetermined section. And the out case of the next feeder is connected to the pipe 234 through which air can flow, based on the feeder on which the pump 230 is installed, thereby minimizing the number of installation of the pump and a plurality of outcases ( 110) The pressure inside may be kept constant.

In some cases, the contents of the pressure control tube 210 is removed, and the pump 230 and the tube are connected by a flow path so that the pump 230 operates according to the pressure change inside the out case 110 so that the air in the tube. Injecting or exhausting it may be to maintain a constant pressure inside the out case (110).

On the other hand, the heat dissipation unit 260 is provided to discharge the heat generated inside the out case 110 to the inside of the out case 110 so that the components installed inside the out case 110 can operate in the best state. . This will be described with reference to FIGS. 8 and 9. FIG.

8 is a cross-sectional view showing a heat dissipation structure of the modular non-contact power feeding device according to the present invention. Referring to the drawings, surface contact with a portion of the outer case 110 to release heat generated from the components installed inside the outer case 110 having a hermetically sealed structure to the outside of the outer case 110. And a heat radiating part 260 extending to the road surface of the driving path.

The heat dissipation unit 260 is formed to have a shape of approximately “T” and is in surface contact with the bottom surface of the out case 110. In this case, a portion of the bottom surface of the outer case 110 in surface contact with the heat dissipation unit 260 is preferably made of a material having excellent heat transfer.

For example, a portion of the bottom surface of the outer case 110 is made of any one of aluminum or graphite. In this case, the inner bottom of the outer case 110 in which the inner case corresponding to the outer surface 112 of the outer case 112 is integrally formed, or the inner case 120 and the lower surface 112 of the outer case and the heat dissipating unit 260 are formed. May be formed of the same material as aluminum or graphite.

As shown in the drawing, the heat dissipation unit 260 has a plate shape, and part of the heat dissipation part 260 is embedded in the depth of the road surface of the driving path so that the heat generated from the components installed inside the outer case 120 and the outer case The heat is released to the bottom surface 112 and the heat dissipating portion 260 of the contact with the heat dissipating portion 260 to maintain a constant temperature inside the out case 110.

In some cases, as shown in FIG. 9, the side surfaces 114 and 116 and the bottom surface 112 of the outer case 110 except for the upper surface of the outer case 110 may be formed of any one of aluminum or graphite described above. It is formed to maximize the heat transfer area to quickly transfer the heat inside the out case 110 to the heat dissipation unit 260 to maintain a constant internal temperature of the out case 110 and from there into the inside of the out case 110 The installed parts can be operated in the best condition.

On the other hand, the heat dissipation unit 260 to discharge the heat generated inside the outer case 110 to the outside of the outer case 110 more quickly so that the components installed inside the outer case 110 can operate in the best state And a heat transfer medium 270. This will be described with reference to FIGS. 10 and 11.

10 is a cross-sectional view illustrating a state in which a heat pipe is installed in the modular non-contact power feeding device according to the present invention. Referring to the drawings, surface contact with a portion of the outer case 110 to release heat generated from the components installed inside the outer case 110 having a hermetically sealed structure to the outside of the outer case 110. And a heat transfer medium connecting a heat dissipation unit 260 extending to the road surface of the driving path, an out case 110 in contact with the heat dissipation unit 260, and an area having a high heat generation value among components installed inside the out case 110. 270 is installed.

The heat transfer medium 270 installed in the out case 110 is connected to the out case 110 and is installed adjacent to or close to the high heat generation component among the parts installed in the out case 110. Heat generated in is transferred to the out case 110 through the heat transfer medium 270.

Here, the heat transfer medium 270 may be a heat pipe (HEATPIPE) or a thermosiphon (THERMOSYPHON), the heat pipe or thermosiphon, a specific state by the two-phase change in which the liquid changes to gas in the place where gravity is applied The working fluid is absorbed by the heat generated at the site, and the working fluid is converted into a gas to quickly move the heat in the opposite direction of gravity.

As shown in FIG. 11, the heat transfer medium 270 penetrates the bottom surface of the out case 110 to be directly connected to the heat dissipation unit 260. In this case, the heat transfer medium 270 passes through the out case 110. In order to maintain airtightness, the bottom surface of the) is hermetically sealed at the bottom surface of the outer case 110 through which the heat transfer medium 270 penetrates by a sealing member 272 such as an o-ring.

Meanwhile, when the terminals of the out case 110 and the next out case 110 are connected by the jump line 184, the shielding part 190 is provided to surround the jump line 184 so that rain water does not affect the terminals. do. This will be described with reference to FIGS. 12 to 14.

12 to 14 is an exploded perspective view and a cross-sectional view and a plan view showing a state in which a shield is applied among the modular non-contact power supply according to the present invention. Referring to the drawings,

The shield 190 has a structure that hermetically shields the periphery of the terminal and the terminal when the electrical connection between the outer case 110 and the terminal 142 of the next outer case 110 has a moisture such as rain water It prevents foreign substances from entering and protects electrical connection between power supply devices.

To this end, the shielding unit 190 is a corrugated pipe connecting the coupler 192 and the coupler 192 and the coupler 192, which are tightly fixed to the terminals of the out case 110 and the next out case 110, respectively. (194).

In this case, the coupler 192 has a large cylindrical shape and a thread is formed at an inner diameter thereof, and a connector 162 screwed with a screw thread formed at an inner diameter of the coupler 192 is formed to protrude from the cover 160. The terminal 142 of the outer case 110 and the next out case 110 in a state where a jump line 184 connecting the terminal 142 and the terminal 142 is located inside the coupler 192 and the corrugated pipe 194. Terminal 142).

When the coupler 192 of the shield 190 and the connector 162 of the cover 160 are threaded, the coupler 192 and the connector 162 contact each other, and a sealing member such as an o-ring ( 164 is provided.

As such, the coupler 192 that is screwed into the connector 162 of the out case 110 and the coupler 192 that is screwed into the connector 162 of the next out case 110 are made of a material having high flexibility and watertightness. The corrugated pipe 194 is connected to the corrugated pipe 194. The corrugated pipe 194 is provided to have a structure in which the coupler 192 is rotated at both ends of the corrugated pipe 194 when connected to the coupler 192.

Accordingly, when the coupler 192 provided at the end of the corrugated pipe 194 is coupled to thread the connector 162 of the cover 160, the coupler 192 is autonomously rotated and smoothly without twisting the corrugated pipe 194. It is fastened to the connector 162. In addition, since the corrugated pipe 194 is structurally stretched and elastic restoring force is exerted, the jump line 184 is concealed in the shield 190 without being exposed to the outside.

In addition, since the corrugated pipe 194 is flexible, the terminal 142 and the terminal 142 when the terminal of the out case 110 and the terminal of the next out case 100 are electrically connected as shown in FIG. 14. The terminal 142 electrically connecting the out case 110 and the next out case 110 of the power supply device because the rainwater penetrates into the inside of the road surface because the jump line 184 is concealed continuously without being connected evenly. ) To protect the electrical connection between the power supply devices.

In some cases, the corrugated pipe may be directly connected to the connector. This will be described with reference to FIGS. 15 and 16.

15 and 16 are exploded perspective views and cross-sectional views showing another embodiment of the shield of the modular non-contact power feeding device according to the present invention.

Referring to the drawings, the shielding unit 190 according to another embodiment for electrically connecting the out case 110 and the terminal 142 of the next out case 110, the out case 110 and the next time. The end of the corrugated pipe 196 wraps around the outer diameter of the end of the corrugated pipe 196 and the end of the corrugated pipe 196 is inserted into the connector 162 protruding from the cover 160 formed around the terminal of the outer case 110 And a tightening band 198 for tightly fixing the connector 162.

At this time, unlike the connector described with reference to FIGS. 12 and 13, the connector 162 protruding from the cover 160 has a smooth surface without a thread formed therein, and the outer diameter of the connector 162 is a corrugated pipe ( 196) is inserted into the end of the structure. In addition, a tightening band 198 is provided at an outer diameter of the end of the corrugated pipe 196 into which the connector 162 is inserted, and a tightening band 198 tightens the end of the connector 162 and the corrugated pipe 196 of the connector 162. The outer diameter and the inner diameter of the end of the corrugated pipe 196 are in close contact and fixed.

As described above, the fastening band 198 for tightly fixing the ends of the connector 162 and the corrugated pipe 198 may have a structure such as a cable tie as shown in FIG. 15, and in some cases, has a ring shape and an elastic force. It may be a spring made of a material having a.

In addition, a jump line 184 connecting a terminal and a terminal is provided inside the shielding part 190 connecting the out case 110 and the next out case 110 so that rain water does not penetrate the jump line 184. The jump line 184 and the terminal 142 may be connected by a wire connecting lug (LUG) to facilitate the connection of the operator.

In other words, the wire connecting lug is for connecting the jump line 184 and the terminal 142, respectively, the jump line side lug 188 and the terminal side lug 144 at the end of the jump line 184 and the end of the terminal 142, respectively. And a nut is fastened to the bolt passing through the lugs 144 and 188 while the jump line lug 188 and the terminal side lug 144 are grounded, so that the jump line lug 188 and the terminal side are fastened. Lug 144 is bound.

By such a wire connection lug, the operator can easily connect the jump line 184 and the terminal 142. The connection by the lug can be applied to the connection of the jump line and the terminal shown in FIGS. 12 and 13.

On the other hand, the outer case to protect the power supply core 130, the power supply line 140 and the inner case 120, etc. from external forces such as depression of the road surface due to the earthquake or cracking due to vibration transmitted from the vehicle passing through the road surface ( By having a more rigid structure 110, the core support is provided inside the out case 110 to stably protect the components. This will be described with reference to FIGS. 17 and 18.

17 is a perspective view showing a core support of the modular non-contact power supply according to the invention, Figure 18 is a cross-sectional view showing a state in which the core support is installed in the modular non-contact power supply according to the present invention.

Referring to the drawings, the core support 200 is installed between the power feeding core 130 and the inner case 120 and extends vertically toward the inside of the upper surface of the out case 110 to extend the out case 110. A beam is formed to support and wrap around the pole 134 of the feed core 130.

In other words, the core support 200 is formed with a support plate 201 which is installed on the upper surface of the inner case 120, and extends from the support plate 201 toward the inside of the upper surface of the out case 110, out case ( Vertical beams 202 supporting 110 are formed.

In addition, a reinforcement part 203 is formed to surround and reinforce the circumference of the pole 134 of the power feeding core 130 adjacent to the vertical beam 202 so that an external force is applied to the upper surface of the outer case 110 when the core support ( The vertical beams 202 of the 200 are supported by the inside of the outer case 110 so that the outer case 110 is not collapsed or damaged.

In addition, the reinforcement part 203 is formed adjacent to the vertical beam 202 so that the pole 134 of the power feeding core 130 is positioned inside the reinforcing part 203, thereby providing a pole of the power feeding core 130. When the external force is applied to the 134, the pawl 134 is not only supported so as not to be damaged, and in the event that the pawl 134 of the feed core 130 is broken, the debris or pieces of the feed core 130 are reinforced. By being located within 203, maintenance and replacement due to breakage of the power feeding device are convenient.

In addition, a protrusion 204 is formed on an upper surface of the support plate 201, and a recess 136 that is unevenly coupled to the protrusion 204 on the bottom surface of the power feeding core 130 facing and facing the upper surface of the support plate 201. Is formed to not only stably support the power feeding core 130 installed on the upper surface of the support plate 201, but also to facilitate installation by the uneven coupling when the power feeding core 130 is installed on the support plate 201. It can be carried out.

The modular non-contact power supply device according to the present invention as described above is a pump 230 for injecting or exhausting air into the pressure control tube 210 or the outer case 110 to maintain a constant change in the internal pressure of the outer case 110. And a heat dissipation unit 260 for maintaining a constant temperature inside the outer case 110 and a resonance capacitor 150 for stably maintaining a voltage of the power feeding device, thereby embedding the power feeding device in the driving path. Power supply devices can be easily connected to each other when electrically connected, which is excellent in workability and can quickly perform repair and replacement of a damaged power supply device.

In addition, the resonant capacitor 150 is installed inside the outer case 110 so that each power supply device has a stable voltage even if the length of the power supply devices increases along the driving path, and thus the entire power supply device installed in the driving path. Regardless of the length, even if the power supply is located at a long distance from the power supply source, it is possible to reliably transmit power to the current collector of the vehicle.

In addition, since the out case 110 of the power feeding device embedded in the road surface of the driving path has a hermetically sealed structure, it is possible to block the ingress of foreign matter that adversely affects the moisture inside the power feeding device or the components installed inside the out case 110. It has excellent waterproofness.

In addition, when the power supply device is provided with a sealed structure having excellent water resistance as described above, it is possible to quickly respond to the internal pressure change of the power supply device, it is possible to prevent breakage or malfunction of parts.

In addition, it is possible to quickly and effectively release heat generated from itself in the power feeding device or the road surface of the driving path to the outside of the power feeding device, thereby improving the reliability of the power feeding device without causing breakage or malfunction of the power feeding device. have.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

For example, the surface of the heat dissipation unit 260 is formed to have a shape of a heat dissipation fin so as to maximize the contact area between the heat dissipation unit 260 in contact with a part of the outer case 110 and the road surface of the driving path. By embossing the surface of the surface 260 to maximize the contact area between the heat dissipation portion and the road surface from this will be able to transfer the heat inside the out case 110 more quickly to the road surface of the road.

110: out case 112: bottom of the out case
120: inner case 130: feed core
132 Stimulus 134 Paul
136: depression 140: feeder
142: terminal 144: terminal side lug
150: resonant capacitor 160: cover
162: connector 164: sealing member
170: gasket 180: connector
182: cap 184: jump line
188: jump side lug 190: shield
192: coupler 194: corrugated pipe
198: tightening band 200: core support
201: support plate 202: vertical beam
203: reinforcement 204: protrusion
210: pressure control tube 220: pressure sensor
230: pump 240: air conditioner
250: check valve 260: heat dissipation
270 heat transfer medium

Claims (21)

As a power feeding device to transfer electric power to the electric vehicle in a magnetic induction method,
An outer case which is embedded in the road surface along a traveling direction of the driving path and whose interior is hermetically sealed;
An inner case installed at an inner bottom of the out case;
A power feeding core having a plurality of magnetic poles disposed at regular intervals provided on an upper surface of the inner case;
A feed line connected to terminals formed at both ends of the outer case by alternately winding the magnetic poles of the feed core; And
And a resonant capacitor electrically connected to the feed line and installed inside the out case. The method according to claim 1,
Modular non-contact power supply device further comprising; a pressure control tube provided in the inner case and made of a stretch material containing the contents that are expanded or contracted in accordance with the internal pressure change of the outer case. The method according to claim 2,
Contents contained in the pressure control tube is a modular non-contact power supply, characterized in that any one of nitrogen, helium, argon, carbon dioxide. As a power feeding device to transfer electric power to the electric vehicle in a magnetic induction method,
An outer case which is embedded in the road surface along a traveling direction of the driving path and whose interior is hermetically sealed;
An inner case installed at an inner bottom of the out case;
A power feeding core having a plurality of magnetic poles disposed at regular intervals provided on an upper surface of the inner case;
A feed line connected to terminals formed at both ends of the outer case by alternately winding the magnetic poles of the feed core;
A resonance capacitor electrically connected to the feed line and installed inside the out case;
A pressure sensor for detecting a pressure change in the out case; And
And a pump for injecting or evacuating air into the outer case according to a pressure change inside the outer case detected by the pressure sensing sensor. The method of claim 4,
And an air conditioner installed on a flow path connecting the out case and the pump to dehumidify or cool the air in the out case. The method according to any one of claims 4 to 5,
A check valve installed on a flow path for injecting or exhausting the air inside the out case and intermittently exhausting the air inside the out case to the outside when the pressure inside the out case falls below a predetermined pressure; Non-contact feeder. As a power feeding device to transfer electric power to the electric vehicle in a magnetic induction method,
An outer case which is embedded in the road surface along a traveling direction of the driving path and whose interior is hermetically sealed;
An inner case installed at an inner bottom of the out case;
A power feeding core having a plurality of magnetic poles disposed at regular intervals provided on an upper surface of the inner case;
A feed line connected to terminals formed at both ends of the outer case by alternately winding the magnetic poles of the feed core;
A resonance capacitor electrically connected to the feed line and installed inside the out case; And
And a heat dissipation unit which is in surface contact with a portion of the out case and extends to a road surface of a driving path to transfer heat inside the out case to the outside. The method of claim 7,
The heat dissipating unit has a shape of a plate made of any one of aluminum or graphite, characterized in that the modular non-contact power supply characterized in that it is embedded toward the center of the earth. As a power feeding device to transfer electric power to the electric vehicle in a magnetic induction method,
An outer case which is embedded in the road surface along a traveling direction of the driving path and whose interior is hermetically sealed;
An inner case installed at an inner bottom of the out case;
A power feeding core having a plurality of magnetic poles disposed at regular intervals provided on an upper surface of the inner case;
A feed line connected to terminals formed at both ends of the outer case by alternately winding the magnetic poles of the feed core;
A resonance capacitor electrically connected to the feed line and installed inside the out case;
A heat dissipation unit which is in surface contact with a portion of the outer case and extends to a road surface of a driving path to transfer heat inside the outer case to the outside; And
And a heat transfer medium connected to the out case which is in surface contact with the heat dissipating unit and installed in close contact with or installed in close contact with a component having a heat generation amount greater than or equal to a preset reference value among components installed in the out case. The method according to any one of claims 7 to 9,
A part of the out case which is in contact with the heat dissipating unit is a modular non-contact power supply, characterized in that made of any one of aluminum or graphite. The method according to claim 9,
And the heat transfer medium is connected to the heat dissipation part through the out case in a state in which the heat generation amount is installed adjacent to or in close contact with a part having a heat generation value higher than a predetermined reference value among the parts installed in the out case. The method according to any one of claims 1, 4, 7, and 9,
The out case is a modular feeding device, characterized in that the glass fiber reinforced plastics (FRP, Fiber Reinforced Plastics). The method according to any one of claims 1, 4, 7, and 9,
The out case is open to both ends of the modular feeder, characterized in that to form a multi-stage inside each of the open ends to form a cover provided with a feed line connecting terminal. The method according to claim 13,
And a gasket is interposed between the ends of the outer case to cover the inside of the outer case in an airtight manner. The method according to any one of claims 1, 4, 7, and 9,
And a connector installed between the out case buried at a predetermined distance along the traveling direction of the driving path and the next out case to electrically connect the feed line installed inside the out case. The method according to claim 15,
Wherein the connector comprises:
A cap surrounding a space between the out case and the next out case;
And a jump line electrically connecting a feed line installed in the outer case and the next outer case inside the cap. The method according to any one of claims 1, 4, 7, and 9,
And a shielding part that electrically shields the periphery of the terminal and the terminal when electrically connecting the terminals of the out case and the next out case.
The shielding portion
A coupler that is in close contact with each other and is fixed to a connector protruding from a cover formed around the terminals of the out case and the next out case; And
And a corrugated pipe connecting between the coupler and the coupler. The method according to any one of claims 1, 4, 7, and 9,
And a shielding part that electrically shields the periphery of the terminal and the terminal when electrically connecting the terminals of the out case and the next out case.
The shielding portion
A corrugated pipe having an end to which a connector protruding from a cover formed around a terminal of the out case and the next out case is respectively inserted; And
And a tightening band surrounding the outer diameter of the corrugated pipe and tightly fixing the end and the connector of the corrugated pipe. The method according to any one of claims 1, 4, 7, and 9,
And a core support provided between the power feeding core and the inner case and extending vertically toward the inner side of the upper surface of the outer case to support the out case and having a beam wrapped around the pole of the power feeding core. The method of claim 19,
The core support is,
A support plate installed on an upper surface of the inner case;
A vertical beam extending from the support plate toward an inner side of the upper surface of the outer case to support the outer case; And
And a reinforcing part formed to be adjacent to the vertical beams to surround and reinforce the pole of the feeding core. The method of claim 20,
The projecting portion is formed on the upper surface of the support plate, the modular non-contact power supply device, characterized in that the bottom portion of the feeding core which is in contact with the upper surface of the support plate is formed with a recess for coupling the projection and the uneven.

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