JP3245770U - Overhead line power receiving device with device box - Google Patents

Abstract

An object of the present invention is to provide an overhead line power receiving device that includes a device box that can obtain power from an overhead line by utilizing the principle of magnetic resonance with a power receiving resonant coil at a resonant frequency. [Solution] An overhead line power receiving device equipped with a device box includes a power supply 1, a power transmission device 2, a power receiving device 3, a power supply unit 4, an oscillation circuit 5, a power supply coil 6, a controller 7, a thermometer 8, and a status display unit. 9. Power transmission resonance coil 10, first capacitor 11, temperature sensor 12, foreign object detection coil 13, power reception resonance coil 14, second capacitor 15, power extraction unit 16, power reception coil 17, charging circuit 18, rechargeable battery 19 and status A sensor unit 20 is provided. [Selection diagram] Figure 1

Description

This utility model is related to the field of power grid power harvesting technology, and is an overhead line power harvesting device equipped with a device cartridge.

Conventional technology

With the rapid development of the scale of power grids, the use of online monitoring systems of overhead power lines and mobile equipment for charging work has become more and more widespread, providing important guarantees for the safe and reliable operation of high-voltage power lines. However, these equipments operate in the field and under unmanned natural conditions for a long time, and the energy replenishment problem is one of the important technical problems that limits stable and reliable online operation in the long term. Currently, the common method for replenishing energy is to install dedicated low-voltage lines, solar cells, small wind power generators, etc., but due to limitations in factors such as economic efficiency, generated power, and equipment volume, equipment manufacturers and maintenance This is causing a lot of inconvenience to the teachers. As an ideal online power supply system, earth induction tapping technology is used in the online monitoring device of the power transmission line at each voltage level, which can effectively use own resources and solve the reliability problem of power supply.

The electricity collection device of this utility model forms a stable power supply voltage, and can be directly used for energy storage battery storage, online monitoring, inspection lighting, and other devices. The principle of magnetic resonance with a receiving resonant coil at a resonant frequency is used to enable the device to obtain power from an overhead line.
Note that, as used herein, related terms such as first and second refer to one entity or two without necessarily requiring or implying that there is any such actual relationship or ordering between these entities or operations. Used only to distinguish an operation from another entity or operation. Additionally, the terms "comprising,""comprising," or any other variations thereof refer to a process, method, article, or apparatus that includes a set of elements, and not just those elements.
It is intended to include non-exclusive inclusion to include other elements not expressly listed or may include elements specific to such process, method, article, or apparatus. can.
This utility model provides an overhead line power receiving device with an equipment case, and this utility model provides the following technical solutions:
An overhead line power receiving device having a device cartridge, the device includes a power source, a power transmission device, a power receiving device, a power supply unit, an oscillation circuit, a power supply coil, a controller, a thermometer, a status display unit, a power transmission resonant coil, a first Capacitor, temperature sensor, foreign object detection coil, power reception resonance coil, second capacitor, power extraction unit, power reception coil, charging circuit, rechargeable battery and status sensor unit,
The power transmission device includes a controller, a thermometer, a power supply unit, and a power transmission resonance coil, the power transmission device is used as a wireless power supply device, and the power reception device includes a power reception resonance coil, a power extraction unit, a charging circuit,
The power supply unit includes an oscillation circuit connected to an external power source and a power supply coil, the power transmission resonant coil can be open at both ends, the power transmission resonant coil has a temperature sensor, and optionally a first
A first capacitor is electrically coupled in series with the power transmission resonant coil to adjust the first capacitance for resonance conditions.
Preferably, the temperature sensor detects the temperature Td of the electrical transmission resonant coil, the electrical transmission resonant coil has an internal resistance, and when current flows, the internal resistance generates heat, thereby increasing the temperature.
When the power transmission resonant coil is provided with a first capacitor, the temperature sensor contacts the first capacitor and detects the temperature Td of the first capacitor.
Preferably, the capacitor includes a unit volume internal resistance that is greater than the unit volume resistance of the power transfer resonant coil, or alternatively, the capacitor includes a unit volume internal resistance that is relatively greater than the unit length resistance of the power transfer resonant coil. including internal resistance.
Preferably, when current flows through the power transfer resonant coil, heat is generated intensively and increases the sensitivity of the temperature sensor.The controller is connected to an external status display, and the status display is connected to the display screen and the speaker, and causes the status display unit to visually or audibly display the power supply status of the power transmission resonant coil.
Preferably, the controller determines the power from the power transmitting resonant coil to the power receiving resonant coil by comparing the analyzable range for the elapsed time t between the detected temperature Td detected by the temperature sensor and the reference temperature distribution Tr in the thermometer. Determine the state of the transmission.
Preferably, if the power supply from the power transmission device to the power transmission device is not normal, the controller stops the power supply to the oscillation circuit of the power supply section using a control signal for controlling the oscillation circuit, and stops the power supply from the power transmission device to the power transmission device. If the power supply is not normal, a warning indicating the abnormality of the power supply status will be displayed on the status display, displayed on the screen, or displayed with audio from the speaker.
Preferably, the temperature sensor may use a thermocouple and voltage indicator temperature detector.
Preferably, the status sensor unit is mainly composed of STM32 monolithic and temperature sensor, voltage current sensor, alarm lamp and wireless network module, in the process of the device drawing electricity, the sensor can detect the temperature of the electricity drawing circuit and charging circuit in real time. Collect and collect voltage and current information, and transfer the data to the monolithic, and the monolithic will also upload the data to the cloud through the wireless network module, realizing cloud data monitoring.During monitoring, if the data such as temperature is abnormal, The alarm lamp lights up, and the monolithic machine controls the disconnection of the power-feeding circuit to ensure the safety of the equipment.
A power withdrawal device that extracts electricity based on an overhead line having a device cartridge.
A wireless installation that draws electricity based on an overhead line with a device cartridge.
This utility model has the following beneficial effects:
The utility model device utilizes the principle of magnetic resonance with a receiving resonant coil at a resonant frequency to enable the device to obtain power from an overhead line.
This utility model device is equipped with a condition sensing unit, uploads real-time monitoring data to the cloud, and realizes remote condition monitoring and control of the power withdrawal device, which is advantageous in improving the safety and efficiency of the equipment.

In order to more clearly explain the specific embodiment of the present utility model or the technical solution in the prior art, the following briefly introduces the drawings that need to be used to explain the specific embodiment or the prior art: Obviously, the drawings in the following description are some embodiments of this utility model, and those skilled in the art can also obtain other drawings based on these drawings without any creative effort.
FIG. 2 is a schematic diagram of the device configuration. Here, 1-power supply, 2-power transmission device, 3-power receiving device, 4-power supply unit, 5-oscillation circuit, 6-power supply coil, 7-controller, 8-thermometer, 9-status display unit, 10 - Power transmission resonant coil, 11 - First capacitor, 12 - Temperature sensor, 13 - Foreign object detection coil, 14 - Power reception resonance coil, 15 - Second capacitor, 16 - Power extraction unit, 17 - Taking coil, 18 - Charging circuit, 19- Rechargeable battery, 20- Status sensor unit.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be clearly and completely described with reference to the drawings, but it is evident that the described embodiments are some but not all embodiments of the present invention. All other embodiments obtained by a person skilled in the art without creative labor based on the embodiments in this utility model are:
It falls within the scope of this utility model protection.
In the explanation of this utility model, the terms "center", "top", "bottom", "left", "right", "vertical"
, "horizontal", "inside", "outside", etc. indicate directions or positional relationships based on the directions or positional relationships shown in the drawings, and are merely for explaining this utility model and simplifying the explanation. This cannot be understood as a limitation on the utility model because the device or element to which it refers is constructed and operated in a specific direction and in a specific direction. Furthermore, the terms "first,""second," and "third" are used for descriptive purposes only and are not to be understood as indicating or implying relative importance.
In the description of this utility model, the terms "attachment" and "connection" will be used unless there are clear provisions and limitations.
, "connection" should be understood in a broad sense, for example it can be a fixed connection, a removable connection or an integral connection, it can be a mechanical connection, The connection may be an electrical connection, a direct connection, an indirect connection via an intermediate medium, or an internal connection between two elements. Those skilled in the art can specifically understand the specific meanings of the above terms in this utility model.
Example 1:
Well-known wireless power supply technologies include electromagnetic induction and radio wave transmission methods. In recent years, magnetic resonance power feeding technology has also been proposed. In a known wireless power supply system using magnetic resonance, a resonant coil having a specific resonant frequency is provided in a power transmission device, and a resonant coil having the same resonant frequency as the coil in the power transmission device is provided in a power receiving device. . Through magnetic field coupling, we realized the possibility of transporting electrical energy through magnetic resonance. This system increases the efficiency of power transfer by approximately 10
It has become possible to separate the power transmitting device and receiving device relatively far. For example, if the size of the resonant coil is about tens of centimeters, the spacing between the coils can be tens of centimeters or more.
Such a known contactless power transmission device uses a first coil of the main unit and a second coil of the terminal to contactlessly transmit electrical energy from the main unit to the terminal. The power transmission device is also equipped with an overheat prevention device that automatically stops power supply to the terminal when it detects a temperature above a predetermined level to protect the device. Further, a known non-contact charging device includes a barcode reader for reading a secondary battery barcode on the top surface, a power receiving coil and a power transmitting coil on the bottom, and a charging unit that electromagnetically couples the two. A temperature sensor is also installed to detect the temperature of the power transmission coil. The charging control circuit can control the charging current based on the temperature detected by the temperature sensor, and when the temperature is below the set temperature, the charging current increases, and when the temperature exceeds the set temperature, the charging current decreases. These designs help improve device safety and efficiency.
In this non-contact charging device, the temperature detection element is provided on the contact surface between the charger and the primary transmission coil, and its center position is approximately 5 mm away from the center of the primary transmission coil of the charger. Selection of this position enables accurate detection of an abnormal temperature rise of the metal foreign object in real time, and improves the safety of the charging device. Known secondary battery charging methods change the charging current depending on the degree of temperature rise of the battery. This method includes detecting a battery temperature at the start of charging and an increasing slope of battery temperature during charging. The current switching temperature for switching the charging current can be adjusted based on the detected charging start temperature and temperature gradient. This method allows rapid charging at higher currents without degrading battery performance. These designs and methods help increase the efficiency and safety of contactless charging devices and secondary battery charging processes.
As shown in FIG. 1, the present utility model relates to an overhead line power receiving device having a device cartridge.
This utility model includes a power supply 1, a power transmission device 2, a power reception device 3, a power supply unit 4, an oscillation circuit 5
, power supply coil 6, controller 7, thermometer 8, status display unit 9, power transmission resonance coil 10, first capacitor 11, temperature sensor 12, foreign object detection coil 13, power reception resonance coil 14, second capacitor 15, power extraction part 16, power collection coil 17, charging circuit 18, rechargeable battery 1
9 and the state sensor section 20,
The power transmission device includes a controller, a thermometer, a power supply unit, and a power transmission resonance coil, the power transmission device is used as a wireless power supply device, and the power reception device includes a power reception resonance coil, a power extraction unit, a charging circuit,
The power supply unit includes an oscillation circuit connected to an external power source and a power supply coil, the power transmission resonant coil can be open at both ends, the power transmission resonant coil has a temperature sensor, and optionally a first
A first capacitor is electrically coupled in series with the power transmission resonant coil to adjust the first capacitance for resonance conditions.
The temperature sensor detects the temperature Td of the power transmission resonant coil, the power transmission resonant coil has an internal resistance, and when current flows, this internal resistance generates heat, thereby increasing the temperature.
When the power transmission resonant coil is provided with a first capacitor, the temperature sensor contacts the first capacitor and detects the temperature Td of the first capacitor.
The capacitor includes a unit volume internal resistance that is relatively greater than the unit volume resistance of the power transfer resonant coil, or the capacitor includes a unit volume internal resistance that is relatively greater than the unit length resistance of the power transfer resonant coil. including internal resistance.
When current flows through the power transmission resonant coil, heat is generated intensively, which improves the sensitivity of the temperature sensor.The controller is connected to an external status display, and the status display includes a display screen, a speaker,
The controller causes the status display unit to visually or audibly display the power supply status of the power transmission resonant coil.
The controller determines the state of power transmission from the power transmitting resonant coil to the power receiving resonant coil by comparing the analyzable range for the elapsed time t between the detected temperature Td detected by the temperature sensor and the reference temperature distribution Tr in the thermometer. Determine.
If the power supply from the power transmission device to the power transmission device is not normal, the controller stops the power supply to the oscillation circuit of the power supply section using a control signal for controlling the oscillation circuit, and stops the power supply from the power transmission device to the power transmission device. If it is not normal, a warning indicating the power supply status abnormality will be displayed on the status display section, and it will be displayed on the screen or displayed with audio from the speaker.
The temperature sensor can use thermocouple and voltage indicator temperature detectors.
The status sensor unit is mainly composed of STM32 monolithic and temperature sensors, voltage and current sensors, alarm lamps and wireless network modules. In the process of the device drawing electricity, the sensor can monitor the temperature collection and voltage of the electricity drawing circuit and charging circuit in real time. It collects current information and transfers the data to the monolithic, and the monolithic also uploads the data to the cloud through the wireless network module to realize cloud data monitoring. During monitoring, if the data such as temperature is abnormal, the alarm lamp will light up and the monolithic machine will control the disconnection of the power-feeding circuit to ensure the safety of the device.

Example 2:
The difference between Example 2 and Example 1 of this application is
Device configuration The power transmission device 2 includes a controller 7 mounted on a processor such as a microprocessor or a microcomputer, a thermometer 8 including, for example, a ROM and a RAM, a power supply unit (or circuit) 4 for transmitting power, and a power transmission resonant coil 10. Power transmission device 2 functions as a wireless power supply device. Power receiving device 3 includes a power receiving resonant coil 14 , a power extraction unit (or circuit) 16 for extracting power, and a charging circuit 18 .
In the power transmission device 2, the power supply unit 4 includes an oscillation circuit 5, and preferably includes a power supply coil (or electromagnetic induction coil) 6. The oscillation circuit 5 is connected to an external DC (direct current) power supply 1. The power transmission resonant coil 10 may be open at both ends. The power transfer resonant coil 10 has a temperature sensor 12 and can optionally be provided with a capacitor 11 electrically coupled in series with the power transfer resonant winding 10 to adjust the capacitance C of the resonance condition. The temperature sensor 12 is
For example, it may be a temperature sensor using a thermocouple and a voltage indicator.
Temperature sensor 12 detects temperature Td of power transmission resonant coil 10 . The power transmission resonant ring 10 has an internal resistance that generates heat and increases the temperature when current flows. When the power transmission resonant coil 10 is provided with a capacitor 11, the temperature sensor 12 is connected to the capacitor 11.
It is preferable to detect the temperature Td of the capacitor 11 by contacting with the capacitor 11. Capacitor 11 preferably includes a unit volume internal resistance larger than the unit volume resistance of power transfer resonant coil 10. Alternatively, capacitor 11 preferably includes an internal resistance per unit length that is relatively greater than the resistance per unit length of power transfer resonant coil 10 . Therefore, when a current flows through the power transmission resonant coil 10, heat is generated intensively, and the sensitivity of the temperature sensor 12 is improved. The controller 7 is connected to an external status display section 9. The status display unit 9 includes a display screen and/or a speaker. The controller 7 causes the status display unit 9 to visually or audibly display the power supply status of the power transmission resonant coil 10 . For example, the power supply status may be abnormal, warning,
It may be normal and power transfer completed.
The controller 7 compares the detected temperature Td detected by the temperature sensor 12 with the analyzable range (Trmin-Trmax) of the reference temperature distribution Tr in the table in the thermometer 8 for the elapsed time t. The state of power transmission from the coil 10 to the power transmission resonant coil 14 is determined. When the power supply from the power transmission device 2 to the power transmission device 3 is not normal, the controller 7 stops the power supply to the oscillation circuit 5 of the power supply unit 4 using a control signal for controlling the oscillation circuit 5, and the power transmission device 2 If the power supply from the power transmission device 3 to the power transmission device 3 is not normal, a warning indicating the power supply state abnormality is displayed on the status display unit 9, and the warning is displayed on the screen or by the sound of the speaker.
(3) Status sensor unit The status sensor unit is mainly composed of STM32 monolithic and temperature sensor, voltage and current sensor, alarm lamp and wireless network module, and in the process of the device extracting electricity,
The sensor collects the temperature and voltage and current information of the electricity-taking circuit and charging circuit in real time, and transfers the data to the monolith, and the monolith also uploads the data to the cloud through the wireless network module, realizing cloud data monitoring. . During monitoring, if the data such as temperature is abnormal, the alarm lamp will light up and the monolithic machine will control the disconnection of the power-feeding circuit to ensure the safety of the device.

Example 3:
The difference between Example 3 and Example 2 of this application is
The present utility model provides a device for extracting electricity based on an overhead line with an equipment cartridge.
Specific example 4:
The difference between Example 4 and Example 3 of this application is
The present utility model provides a wireless appliance that draws electricity based on an overhead line with a device cartridge.
In the description herein, reference terms such as "one embodiment,""someembodiments,""example,"
A statement such as "a specific example" or "some examples" means that the specific feature, structure, material, or characteristic described in connection with the embodiment or example is the embodiment of at least one embodiment of the present utility model. or mean included in an example. As used herein, the schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or features described may be combined in any suitable manner in any or N embodiments or examples. Furthermore, unless inconsistent, those skilled in the art can combine and combine different embodiments or examples and features of different embodiments or examples described herein. Furthermore, the terms "first" and "second" are used for descriptive purposes only and do not indicate or imply relative importance or imply the number of technical features indicated. can not understand. Therefore, the features defining "first" and "second" can include at least one feature explicitly or implicitly. In the description of this utility model, "N" means at least two, for example two, three, etc., unless there is a specific limitation. The descriptions of processes or methods illustrated in flowcharts or otherwise described herein may include modules, fragments, or portions that contain one or more code of executable instructions for implementing custom logical functions or steps of a process. The scope of the preferred embodiments of this utility model is presented essentially simultaneously based on relevant features and not in the order shown or discussed.
or performing the functions in the reverse order, as should be understood by those skilled in the art to which the embodiments of this utility model pertain. The logic and/or steps illustrated in a flowchart or otherwise described herein, e.g., may be considered a sequence of executable instructions used to implement the logical functions of an instruction execution system, computer-based system, including a processor, or any other system capable of retrieving and executing instructions from an instruction execution system, device, or device; It can be used in combination with devices. For the purposes of this specification, a "computer-readable medium" refers to a computer-readable medium that contains, stores, communicates, propagates, or transmits an instruction-execution system, device, or device, or a program for use in conjunction with such an instruction-execution system, device, or device. It may be any device that can. More specific examples (non-limiting list) of computer readable media include electrical connections with one or N wires (electronic equipment), portable computer disk boxes (magnetic equipment), random access memory (RAM), Read-only memory (RO
M), including erasable editable read only memory (EPROM or flash memory), fiber optic devices, and portable optical disk read only memory (CDROM). Further, the computer-readable medium may be, for example, paper or other medium, optically scanned and then edited, translated, or processed in any other suitable manner as necessary to obtain the program electronically and stored in the computer memory. It may be paper or other suitable medium on which the program can be printed. It is to be understood that portions of this utility model can be implemented in hardware, software, firmware, or a combination thereof. In the embodiments described above, the N steps or methods may be implemented using software or firmware stored in memory and executed by a suitable instruction execution system. When implemented in hardware, as in other embodiments, discrete logic circuits having logic gate circuits for implementing logic functions on data signals, dedicated integrated circuits combining suitable logic gate circuits, programmable gate arrays (PGA), Field Programmable Gate Array (FPGA), etc., or a combination thereof, which are well known in the art.
The above is only a preferred embodiment of the composite material acoustic performance test evaluation method based on a large-scale model, and the scope of protection of the composite material acoustic performance test evaluation method based on a large-scale model is not limited to the above-mentioned examples. All the technical proposals below fall within the protection scope of this utility model. For those skilled in the art, it should be pointed out that some improvements and changes without departing from the principle of this utility model should also be considered as the protection scope of this utility model.

Claims (10)

An overhead line power receiving device equipped with a device box,
A power supply, a power transmission device, a power receiving device, a power supply unit, an oscillation circuit, a power supply coil, a controller, a thermometer, a status display unit, a power transmission resonance coil, a first capacitor, and a temperature sensor. , a foreign object detection coil, a power reception resonance coil, a second capacitor, a power extraction unit, a power reception coil, a charging circuit, a rechargeable battery, and a status sensor unit,
The power transmission device includes a controller, a thermometer, a power supply unit, a power transmission resonant coil,
The power transmission device functions as a wireless power supply device,
The power receiving device includes a power receiving resonant coil, a power extraction section, and a charging circuit,
The power supply unit includes an oscillation circuit and a power coil connected to an external power supply,
The power transmission resonant coil can be open at both ends, the power transmission resonant coil is equipped with a temperature sensor, and has a first capacitor;
a first capacitor is electrically coupled in series with the power transfer resonant coil to adjust the first capacitance for resonant conditions;
Overhead line power receiving device equipped with a device box. An overhead line power receiving device comprising the device box according to claim 1,
The temperature sensor detects the temperature Td of the power transmission resonant coil,
The power transmission resonant ring has an internal resistance, and when current flows, this internal resistance generates heat, thereby increasing the temperature,
When the power transmission resonant coil is provided with a first capacitor, the temperature sensor contacts the first capacitor and detects the temperature Td of the first capacitor.
Overhead line power receiving device equipped with a device box. An overhead line power receiving device comprising the device box according to claim 2,
the capacitor includes a unit volume internal resistance greater than the unit volume resistance of the power transfer resonant coil;
Alternatively, the capacitor includes an internal resistance per unit length that is greater than the resistance per unit length of the power transfer resonant coil.
Overhead line power receiving device equipped with a device box. An overhead line power receiving device comprising the device box according to claim 3,
When current flows through the electrical transmission resonant coil, heat is generated, increasing the sensitivity of the temperature sensor,
The controller is connected to the status display section,
The status display unit includes a display screen and a speaker,
The controller causes the status display unit to visually or audibly display the power supply status of the power transmission resonant coil.
Overhead line power receiving device equipped with a device box. An overhead line power receiving device comprising the device box according to claim 3,
The controller determines the state of power transmission from the power transmitting resonant coil to the power receiving resonant coil by comparing the analyzable range for the elapsed time t between the detected temperature Td detected by the temperature sensor and the reference temperature distribution Tr in the thermometer. determine,
Overhead line power receiving device equipped with a device box. An overhead line power receiving device comprising the device box according to claim 5,
When the power supply from the power transmission device to the power transmission device is normal, the controller stops power supply to the oscillation circuit of the power supply unit using a control signal for controlling the oscillation circuit;
If the power supply from the power transmission device to the power transmission device is not normal, the controller causes the status display unit to display a warning indicating the abnormality of the power supply state on a screen or with audio from a speaker.
Overhead line power receiving device equipped with a device box. An overhead line power receiving device comprising the device box according to claim 6,
The temperature sensor adopts thermocouple and voltage indicator temperature detector,
Overhead line power receiving device with device box An overhead line power receiving device comprising the device box according to claim 1,
Condition sensor unit includes STM32 monolithic machine, temperature sensor, voltage current sensor,
Consists of a warning lamp and a wireless network module,
In the process of extracting electricity, the sensor collects the temperature and voltage and current information of the electricity extracting circuit and charging circuit in real time, and transfers the data to the single chip, and at the same time, the single chip uploads the data to the cloud through the wireless network module. , realize cloud data monitoring,
During monitoring, if the temperature data is abnormal, the alarm lamp will light up and the STM32 monolithic machine will control the disconnection of the power collection circuit to ensure the safety of the equipment.
Overhead line power receiving device equipped with a device box. An electrical device comprising an overhead line power receiving device comprising the device box according to claim 8. An overhead line power receiving device comprising the device box according to claim 8,
The power collection device is a wireless power collection device,
Overhead line power receiving device equipped with a device box.