KR20130072282A - High frequency power cable having over temperature protection - Google Patents

Abstract

PURPOSE: A high frequency power cable capable of having the overheating protection function based on a centered heater and an overheating protection apparatus including thereof are provided to always closely adhere the heater to the cable, thereby implementing the exact sensing of the heat generation. CONSTITUTION: A conducting wire has a pair of elasticity. The conducting wire is coated to an insulator (26). A heater (25) short-circuits the two conducting wires when the temperature rises. The current is blocked by the short circuit. A thin strand covers an insulated coating around the heater circumference.

Description

High Frequency Power Cable having Over Temperature Protection

The present invention is caused by various factors such as overheating due to cable damage, overheating by a heating element outside the cable, or overheating of the cable by induction heating of adjacent metals in a power cable having a high frequency current such as a wireless power transmission device. The present invention relates to a high-frequency power cable with overheat protection that can detect overheating of a cable and prevent fire.

The wireless power transmitter is a device that transmits power wirelessly by magnetic induction. It wirelessly transmits power to a trolley moving along a track. Sometimes.

The wireless power transmitter uses high-frequency magnetic flux by flowing a high frequency current through a feeder line and uses power induced in a secondary coil. The high frequency magnetic flux is always applied around the feeder line. In this case, if metal is present near the feed line, eddy current flows through the metal, causing eddy current loss.In the case of metal containing iron, eddy current loss and hysteresis loss occur simultaneously, causing the metal to generate heat. High frequency power cables that make up the feed line may be damaged or cause a fire, so a device that can detect heat is necessary.

To this end, various power cable overheat protection devices have been proposed. Specific examples are as follows.

First, when the optical fiber cable receives heat, the transmittance of light is changed.The optical fiber cable is installed along the induction line, and the light emitting part and the light receiving part connected to both ends of the optical fiber cable are detected. The high frequency current is cut off by detecting that the predetermined attenuation rate is higher than or equal to that. This method is not used in the optical fiber cable because it has a problem that the transmission amount is reduced by pressing or bending, the problem that the detection distance is not long, the problem that the construction of the optical fiber cable is difficult to connect, and so on.

Second, in order to improve this, there is a thermal wire protection device that detects heat generated near a high frequency power cable and prevents fire. The thermal wires are formed by twisting each other so as to generate a force to stick together a pair of strong elastic conductors coated with an insulator starting to melt at a predetermined temperature, and in this state, the insulator starts to melt when heated. It is a principle that can detect overheating by connecting two conductors together and making a short circuit. The material of the conductor constituting the thermal wire is made of non-ferrous metal so that the conductor itself is not induction heating. The thermal wire is not affected by bending, it is easy to construct, and it is the most popular method because it is inexpensive.

However, the thermal wire does not detect heat even if it is only a little away from the power cable. Therefore, in order to detect heat well, the thermal wire should always be in close contact with the outer sheath of the power cable. The disadvantage is that it is inconvenient and difficult to attach to the power cable. In particular, in the case of a straight feed line, it can be easily installed as a separate device, but an extension line connected to the high frequency power supply from the feed line has a problem that is not easy to install.

The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to use a conventional thermal wire for overheating protection of a power cable, but it is easy to install or handle, and has a high-temperature protection function having a high overheating protection reliability. To provide a power cable.

In order to achieve the above object, the high-frequency power cable having the overheat protection function according to the present invention is characterized by forming a thermal wire integrated power cable by inserting a thermal wire into the high-frequency power cable.

The thermal wire integrated power cable has an existing thermal wire in the center of the power cable and wraps the wire of the power cable on the outside thereof, and puts an insulation layer between the thermal wire and the power cable wire to be electrically insulated from the outside. Characterized by the outer shell. According to the present invention, when heat is generated in the power cable itself, or when there is a heating element on the outside of the cable, heat is transferred to the thermal wire, and when the two conductors of the thermal wire are shorted to each other, it detects it and blocks the high-frequency current flowing through the power cable. It is characterized in that the fire due to overheating of the cable can be prevented.

The thermal wire integrated power cable with overheat protection according to the present invention does not need to separately install the power cable and the thermal wire as in the conventional thermal wire method, and does not need a close contact between the thermal wire and the power cable. . In particular, when the feed line is in the form of a coil, since it is very difficult to install a separate thermal line, it can be used very conveniently. Existing heat-sensitive wire may not be heat-sensing because heat transfer is not good if the heat-sensitive cable is not well adhered to the power cable, but the heat-sensitive wire integrated power cable according to the present invention has a reliable thermal stability because the heat-sensitive wire is always in close contact. There is a very high advantage.

1 is an essential part diagram of an E-type wireless power transmitter according to a first embodiment of the present invention;
2 is an essential part diagram of an F-type wireless power transmitter according to a second embodiment of the present invention;
3 is a view of the main part of a fixed wireless power transmission apparatus according to a third embodiment of the present invention;
4 is a cross-sectional view and a side view of a thermal line of the same wireless power transmitter,
5 is a cross-sectional view illustrating a configuration of a power cable and a thermal wire of the wireless power transmitter.
6 is a cross-sectional view of a thermal wire integrated power cable for the wireless power transmission device;
7 is a cross-sectional view showing an example of the configuration of the thermal wire integrated power cable for the wireless power transmission device,
8 is a cross-sectional view showing an installation example of a thermal wire integrated power cable for the wireless power transmission device;
9 shows a thermal line sensing circuit of the wireless power transmission apparatus.

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

1 is a main part of an E-type wireless power transmitter which is generally used in a logistic transport device, and FIG. 2 is a F (flat) type wireless power transmitter which is used in an AGV (Automotive Guided Vehicle). 3 is a main part, and FIG. 3 shows a main part of a stationary wireless power transmission device which is widely used for wireless charging such as battery cars.

The wireless power transmission device transmits a high frequency current through the high frequency inverter through the feed line 10 to generate magnetic flux around the feed line 10 and crosses the secondary coil 13 in which the magnetic flux is wound around the pick-up. It transmits power by magnetic induction without contact. 1 to 2 are examples of wirelessly supplying power to a vehicle moving along a rail, and FIG. 3 is a case of transferring power wirelessly in a stopped state.

In any case, since the high-frequency current flows through the feed line 10, if there is a metal material in close proximity, eddy currents also flow in the metal, and if iron is contained, hysteresis loss occurs, and the metal is rapidly heated, It is very dangerous because it leads to fire due to cable sheath damage, insulation breakdown, etc. Therefore, there is absolutely a need for a device that detects the occurrence of overheating in the cable and cuts off the current in the feed line.

The thermal wire is coated with an insulator 22 made of a thermoplastic sensitive to heat that starts melting at a predetermined temperature on a pair of strong elastic conductors 21 as shown in FIG. It is composed, the outer cover 23 to the outside is configured. Since the conductive wire is installed in close proximity to the high frequency power cable to detect heat generation of the power cable, the conductive wire 21 uses an alloy material having a non-ferrous metal elasticity that does not itself induce heating.

The principle of the thermal wire is that when heat is generated around the thermal wire and is transmitted to the thermal wire, when the insulator wound on the wire begins to melt at a predetermined temperature, the two wires are shorted by pressure with each other. By detecting this, it is possible to know the state of heat generation. The thermal wire is not affected by bending, it is easy to construct, and it is the most popular method because it is inexpensive.

However, the thermal wire does not detect heat well even if it is only a little away from the power cable, or time delay occurs a lot, so to detect heat well, it must always be attached to the power cable with a constant force. Although it is used to tie with a cable tie, it is inconvenient and difficult to attach the thermal wire to the power cable. In particular, it is necessary to bundle a thermal wire on an extension line connected to a high frequency power supply device away from a feeder line, which is bundled with a cable tie or a band, which is very inconvenient and cumbersome. In the case of a feeder in the form of a coil rather than a straight feeder, installation is more difficult. FIG. 5 shows an example in which the thermal line 25 is installed in a straight feed line 10.

In order to eliminate such inconvenience, the high frequency power cable having the overheat protection function according to the present invention is characterized by constituting the thermal wire integrated power cable by inserting the thermal wire 25 into the high frequency power cable.

The thermal wire integrated power cable has an existing thermal wire 25 in the center of the power cable as shown in FIG. 6 and wraps the wire 10 of the power cable to the outside thereof, an insulating layer 26 between the thermal wire and the power cable wire. ) To further enhance electrical insulation, and the outer surface of the outer shell. According to the present invention, when heat is generated in the power cable, or when there is a heating element on the outside of the cable, heat is transferred to the thermal wire 25 and the two conductors of the thermal wire 25 are shorted to each other to detect the power cable. It is possible to prevent a fire caused by overheating of the power cable by blocking the flowing high frequency current. In the thermal wire integrated power cable, the power cable may be any type of cable. The thin wire may be configured by collecting a litz wire covered with a thin enamel coating, or may be configured by arranging several strands of a regular strand wire covered with a coating as shown in FIG. 7.

Figure 8 shows an example applied to the linear feed line of the thermal wire integrated power cable. Installation is very easy because only the power cable need not be installed as shown in FIG. In particular, the extension line is connected to the high-frequency power supply from the feeder line does not need to install a separate thermal wire has a very convenient advantage. In addition, the existing heat-sensitive wire may not be heat-sensing because heat transfer is not good if the heat cable is not closely adhered to the power cable, but the heat-sensitive wire integrated power cable according to the present invention is a heat-sensitive detection because the heat-sensitive wire is always in close contact It has the advantage of very high reliability.

9 is a circuit for sensing the thermal line 25. A circuit for detecting that the relay output is open because the relay drive stops when the thermal wire is short-circuited by connecting the relay 28 driving terminal to both opposite wires with the power supply 27 on both the thermal wires as shown in FIG. 9. By detecting the high frequency current flowing through the power cable detected by (29), it is possible to prevent a fire due to overheating of the power cable.

10: feeder line (high frequency power cable)
11: cable supporter
12: pickup core
13: secondary winding
14: power cable jacket
15: core cable sheath
16: litz wire
21: thermal conductor lead
22: heat ray endothelial
23: thermal wire outer shell
25: heat ray
26: insulator
27: power
28: relay
29: sensing circuit

Claims (3)

In a wireless power transmission device for transmitting a high-frequency current to the feed line and wirelessly transfers electric power without electrical mechanical contact by using the power induced in the secondary coil by magnetic induction by the magnetic flux generated therein,
In order to detect heat generation in the feed line itself or around the feed line, a pair of non-magnetic wires having elasticity are covered with an insulator that starts to melt at a predetermined temperature, and the wires covered with these insulators are twisted and covered with an outer sheath. When the temperature rises above a predetermined temperature, the insulator melts so that the two wires are short-circuited, and a plurality of strands of thin wires covered with an insulating coating are arranged around the heat-sensitive wires. It is configured to have a cross-sectional area of wire and surrounds its outer circumference, and when the temperature of the power cable itself or the surrounding temperature rises above the predetermined temperature, the insulation of the thermal wire melts and detects that the two wires of the thermal wire are short-circuited. Thermal cable integrated power cable with overheating protection by blocking.
The method of claim 1,
In order to detect a short circuit of the thermal wire, a predetermined AC voltage is applied to one end of the thermal wire, and an AC driving relay is attached to the opposite end to detect that the thermal operation is shorted, so that the relay operation stops. Circuit for detecting it.
The method of claim 2,
A thermal line sensing circuit for detecting whether a thermal line is short-circuited by attaching a direct current relay to both ends of the thermal line instead of an alternating current and attaching a DC-driven relay to the other end of the thermal line sensing circuit.

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