WO2014012402A1 - Power supply, charge and fee deduction components for mobile device - Google Patents

Description

 Mobile device supply, charging and deduction components

 [0001] The present invention belongs to the field of electronic applications, and more specifically to a power conversion technology. Background technique

 [0002] At present, power supply to mobile devices is to convert electrical energy into chemical energy and store it in a battery, and then power the mobile device with a battery. This method has high requirements on the capacity of the battery, and the capacity of the battery is subject to objective conditions. The limitation cannot be expanded in an infinite amount, so that the use of electric energy by the mobile device is greatly restricted; the invention completely solves the limitation of the mobile device on the use of electric energy.

 [0003] The present invention enables mobile devices to use electrical energy without restriction, allows mobile devices to fully utilize clean electrical energy, reduces environmental pollution caused by petroleum use, and reduces chemical contamination caused by manufacturing capacitance.

SUMMARY OF THE INVENTION

The invention consists of three parts: a power supply component, a power take-off component and a charge-off component:

The power supply component is composed of a plurality of open-loop iron core coils, each of which is controlled by two switches, one of which is controlled by a positioning device disposed on the mobile device, and the other switch is controlled by a ground deduction system, and the deduction is charged. The system deducts the charge according to the received recharge information and controls the switch to be turned on. The power take-up component is composed of two core coils in parallel, and the coupled electric power is sent to the battery and the automatic voltage regulator, and the switch of the reluctance motor will be The electric power sent by the voltage regulator is sent to the reluctance motor to make the reluctance motor run, and the motor drives the mobile device to move. The relative position of the power supply components is controlled by two stepper motors and related components.

[0005] The application of the invention can completely change the energy used by current mobile devices. Create epoch-making innovations.

 BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is the general connection diagram of each part of the supply, charging and deduction components; Figure 2 is the connection diagram of the components of the power supply part of the supply, charging and deduction components; Figure 3 is the location of the power supply part of the supply, charging and deduction components Figure 4 is a connection diagram of the power supply and power consumption parts of the charging, charging and deduction components; Figure 5 is a relative position diagram of some components of the power supply and charging components of the charging, charging and deduction components; 6 is a connection diagram for the positioning and control positioning of the power take-off component of the charging, charging and deduction components;

As shown in Fig. 1, wherein the power supply system is connected to the power supply, the components of the power supply system are: (8) a rectifier for rectifying the power supply, and a high frequency inverter (7) inverter for the (8) rectifier output DC power, The (7) inverter output current is sent to the (4) open-loop core coil assembly for control (2) electronic switch and (3) gate turn-off thyristor switch, power supply (8) rectifier, (8 Rectifier is connected to (7) inverter, (7) inverter is connected (3) gate can turn off thyristor switch, (3) gate can turn off thyristor switch (2) electronic switch, (2) electronic switch Connect (4) an open-loop core coil assembly; (2) the electronic switch is controlled by a (1) Hall switch, (1) the Hall switch is controlled by a (61) inductive positioner disposed on the mobile device, (61) The inductive positioner is controlled by (63) the CPU, and (63) the CPU compares the signal measured by the (61) inductive positioner with the position signal previously measured and stored in the (63) CPU, according to the comparison Results for the (30) open-loop core coil assembly in the power take-off assembly The relative position of the (4) open-loop core coil assembly of the electrical component is adjusted; (3) the gate turn-off thyristor switch is controlled by (6) the CPU, and (6) the CPU receives the signal according to the (5) signal receiver. Fees for recharge cards on mobile devices The situation is (3) the gate turn-off thyristor switch is controlled, (5) the signal receiver compares with the information of the IC on the received mobile device and (6) the payment information in the CPU, if there is sufficient cost (6) The CPU deducts the charge and outputs a signal to enable (3) the gate turn-off thyristor switch is turned on, and several (3) gate turn-off thyristor switches are connected together and turned off at the same time; (45) The signal transmitter is based on (43) the information on the IC card read by the card reader is processed by the (40) CPU and transmitted; when the (41) manual button is pressed, (43) the card reader reads the payment IC The information, after (40) CPU processing, when (61) the inductor positioner is positioned to the position of the power take-off component, (45) the signal transmitter emits the read payment information; (41) manual button and (43) a card reader and (45) signal transmitter connection (40) CPU; (63) the CPU is connected to the (40) CPU to obtain (61) the position information of the inductor positioner;

The height spacing is adjusted by the (63) CPU according to (61) Inductor Positioner Positioning Information Control (23) Stepper Motor, and the lateral position is controlled by (63) CPU according to (61) Inductor Positioner Positioning Information Control (20) Stepper Motor (63) The CPU simultaneously controls (20) the stepper motor and (23) the stepper motor according to the information of the obstacle scanned by the scanner, and adjusts the core coil assembly of the open component of the power take-off component (30). Position, to avoid obstacles; when (63) CPU acquires (40) CPU boot information, according to (61) position information of the inductor positioner control (20) stepper motor and (23) stepper motor Adjust (30) the position of the open-loop core coil assembly so that it is at a reasonable distance from the relative position of the open-loop core coil assembly of the power supply assembly (4); take the assembly (30) open-loop core coil assembly, (45 ) signal transmitter, (61) inductive positioner and (62) scanner assembled together; (61) inductive positioner, (62) scanner, (23) stepper motor and (20) stepper motor Both are connected to the (63) CPU;

The electric power obtained by the core assembly of the open-loop core assembly of the power take-off assembly (30) is sent to the (39) reluctance motor, and the other portion of the obtained electricity is fed to the (35) battery to charge the (35) battery; Show: The power supply assembly consists of several (4) open-loop core coils, each

(4) The open-loop core coil is controlled by two switches, one of which is (2) an electronic switch, (2) the electronic switch is controlled by (1) a Hall switch, (1) the Hall switch is positioned by (61) inductor Control, (1) Hall switch sensing (61) Inductor positioner after flux control (2) Electronic switch on; When (61) Inductor positioner is off (1) Near Hall switch, (1) Hall After the switch does not sense (61) the magnetic flux of the inductor positioner, (1) the Hall switch control (2) the electronic switch is turned off; (1) the Hall switch connection (2) the electronic switch; the control power supply component (4) The other switch of the ring core coil is (3) the gate can turn off the thyristor switch, and several (3) gate turn-off thyristor switches are connected together by the (6) CPU control, (6) CPU according to (5) Control of the payment information of the IC card received by the signal receiver

(3) The gate can turn off the opening and closing of the thyristor switch; if there is a fee on the IC card, the (3) gate can be turned off and the thyristor switch is turned on. If there is no fee on the payment IC card, it will not be opened.

(3) The gate can turn off the thyristor switch; the switch (2) the electronic switch and the switch (3) the gate can turn off the thyristor switch in series on the line that supplies the (4) open-loop core coil; (3) the gate The control terminal that turns off the thyristor switch and (5) the signal receiver are connected to the (6) CPU.

As shown in Figure 3: Power take-off assembly (30) Open-loop core coil assembly, (45) Signal transmitter, (61) Inductor positioner and (62) Scanner assembled components and power supply components

(4) The relative position of the open-loop core coil assembly is controlled by two sets of motor systems; and (14) Support frame support, the support frame is fixed on the mobile device; (14) The support frame is composed of upper and lower parts, (14) the upper and lower parts of the support frame are connected by (13) screws; the core of the open component of the power take-off component (30) Coil assembly, (45) signal transmitter, (61) Inductor positioner and (62) The components assembled by the scanner are fixed at one end of the (15) screw, (15) on the screw sleeve (16) with external gear The nut is mounted on the (17) tapered bearing, (17) the tapered bearing is placed on the (18) threaded slider, and (18) the threaded slider is placed over the (19) lead screw, (18) The threaded slider is placed on the (14) slider of the (14) support frame; (16) the nut with the external gear and (23) the stepper motor through the (24) gearbox after shifting (25) The output shaft of the external gear is engaged; the rotation of the (23) stepping motor is changed to (15) the up and down movement of the screw, thereby controlling the core assembly of the open loop of the power take-off assembly (30), (45) signal transmitter , (61) Inductor Locator and (62) Scanner assembled components and power supply components (4) Open-loop core coil The relative position of the members; jacket in

(19) (18) threaded slider on the lead screw, moving left and right with (19) screw rotation, (19) screw is connected with (20) stepper motor (21) transmission gearbox Will

(20) The rotation of the stepping motor becomes (19) the rotation of the lead screw, thereby causing (18) the threaded slider to move left and right;

As shown in Figure 4: The power take-off component consists of two (30) open-loop core coils connected in parallel, and two (30) open-loop core coils are connected in parallel to form a part of the electricity directly fed into (37). Automatic regulator, (37) The power from the automatic regulator is sent to the (39) reluctance motor via the (38) control switch; the coil set is connected in parallel by two (30) open-loop core coils (37) Automatic regulator; (37) automatic regulator connection (38) control switch, (38) control switch connection (39) reluctance motor; two (30) open loop The coil set consisting of the core coils in parallel is connected and the other part of the electricity is rectified by the (32) rectifier and sent to (33) the inductor filter is fed into the (35) battery via the (34) one-way switch; wherein (32) the rectifier is connected (33) Inductor filter, (33) Inductor filter connection (34) Unidirectional switch, (34) Unidirectional switch connection (35) Battery; (35) Battery in the battery (36) Gate can turn off the thyristor The switch enters (31) the inverter feeds (37) the auto-regulator, enters (37) the auto-regulator current is fed through (38) the control switch (39) reluctance power (32) rectifier and (33 Inductor filter and (35) battery and (34) unidirectional switch in series, (35) battery and (36) gate turn-off thyristor switch and (37) auto-regulator in series, (36) gate can be off The control pole of the thyristor switch connects two (30) open-loop core coils in parallel and a coil set in parallel with the (37) automatic voltage regulator in series; when two (30) open-loop core coils are connected in parallel (36) Gate when the coil set is connected to the (37) auto-regulator in series The turn-off thyristor switch is turned off,

(34) The one-way switch is turned on, the two (30) open-loop core coils are connected in parallel to form a coil group to charge (35) the battery, and (37) the automatic voltage regulator is supplied; when two (30) are turned on When the coil cores of the ring core coils are connected in parallel, there is no power, (36) the gate can turn off the thyristor switch, (35) the battery pair (37) the automatic voltage regulator supplies; (37) the automatic voltage regulator and ( 38) Control switch connection, (38) Control switch connection (39) Reluctance motor.

(41) The manual button connects and controls (40) the CPU. When the (41) manual button starts (40) the CPU, (43) the card reader reads (44) the information of the payment IC card; and when (61) the inductor is positioned When the position sensed by the device is close to the position stored in the (63) CPU in advance, (40) the CPU will read (44) the IC card through the (45) signal transmitter. The information is transmitted.

As shown in FIG. 5: a relative position and shape diagram of the (30) open-loop core coil assembly in the power take-off assembly and the (4) open-loop core coil assembly of the power supply assembly, wherein in order to increase the between the power supply components Magnetic circuit connection, soldering (52) a plurality of fine magnetic wires at the core end of the core coil of the open-loop component of the power take-off component (30), so that the gap between the supply electromagnetic cores is as small as possible, and when encountering a hard object It does not damage (30) the open-loop core coil assembly.

As shown in Figure 6: Power take-off assembly (30) open-loop core coil assembly, (45) signal transmitter, (61) inductor positioner and (62) scanner assembled together, (61) inductive positioner and (62) The scanner is respectively connected to the (63) CPU, (20) the stepping motor and (23) the stepping motor are also respectively connected to the (63) CPU; (63) the CPU according to (62) the information scanned by the scanner and (61) The information sensed by the inductor positioner controls (20) the stepper motor and (23) the stepper motor.

DETAILED DESCRIPTION OF THE INVENTION

The invention is used in a car, installing a power supply component in the middle of the road, installing a power take-off component on the automobile, and installing a charge system along the road, installing a card reading system on the car, as long as there is a payment card, then all the cars can be Changed to an electric car. And at any time, you can deduct the cost of the electricity consumed by the car. When the mobile device needs to be charged, press (41) the manual button to start (40) the CPU, (40) after the CPU is started, (43) the card reader reads (44) the information of the payment IC card; and when (61) When the position information sensed by the inductor positioner is close to the position information stored in the (63) CPU in advance, (40) the CPU command (45) signal transmitter transmits the information of the read (44) payment IC card. (5) The signal receiver receives (44) the payment information of the payment IC card and (6) the payment information in the CPU. Compare, if there is sufficient cost, (6) CPU deducts the charge and outputs a signal to make (3) the gate can turn off the thyristor switch, and (63) CPU command (20) stepper motor and (23) The stepping motor operates to move the power take-up component up and down, so that (61) the inductor positioner senses the position of the power supply component, and when (61) the inductor positioner senses the position of the power supply component and adjusts the position of the power supply component, 1) The Hall switch also senses (61) the magnetic flux of the inductive positioner, so that (2) the electronic switch is turned on, the power supply component is energized, and the magnetic flux is supplied to the core of the power supply component. Inductive current, after the adjusted current is controlled by the reluctance motor, the windings of the reluctance motor are sequentially sent to make the reluctance motor run; when the power take-off component leaves the power supply component, the battery is resisted by the reluctance The motor is powered, and another part of the power take-off component is electrically fed into the (32) rectifier. After (33) inductive filtering, the battery is charged after the (34) one-way switch, when two (30) open-loop core coils are connected in parallel consist of When no electricity ring group, (36) a gate turn-off thyristor switch is turned on by the (35) of the battery (37) automatic voltage regulator power; motor run magnetoresistance. Drive the car.

In addition, a corresponding power transmission component can be set up in the parking place to supply power to the battery of the parked vehicle. It is possible to deduct relatively expensive electricity supply charges for passing vehicles in places where traffic is congested.

Claims

Claim  1, a mobile device for charging, charging and deducting components: comprising a power supply component disposed on the ground and a power take-off component disposed on the mobile device and a charge component, wherein the power supply component is comprised of (4) The open-loop core coils are juxtaposed, wherein each core coil is controlled by two switches (2) electronic switches and (3) gate turn-off thyristor switches in series, (2) the electronic switches are controlled by (1) Hall switches, (1) The Hall switch is controlled by (61) electric induction positioner, (61) the electric induction positioner is controlled by (63) CPU, (41) the manual push button switch is connected and controlled (40) CPU, (40) CPU Connect and control (63) CPU, (3) Gate turn-off thyristor switch connection (6) CPU, (6) CPU connection (5) signal receiver, (5) Signal receiver receives mobile device (45) signal The signal emitted by the transmitter, several (3) gate-turnable thyristor switches are connected in series and turned off at the same time, (45) the signal transmitter is connected to the (40) CPU and controlled by the (40) CPU. (40) CPU connection (43) card reader and acquisition Signal read IC card payment (44), (44) is inserted into the IC card payment (43) in the card reader, The power take-off component is characterized in that two (30) open-loop core coils are arranged in parallel and parallel, (30) the core end face of the open-loop core coil is connected with (52) a plurality of thin magnetic wires, two (30) The open-loop core coils are arranged in parallel and in parallel to form a coil group and (32) a rectifier, (33) an inductive filter, (34) a unidirectional switch and (35) a battery in series, and two (30) open-loop core coils are spaced apart Parallel parallel coil sets are connected in series with (37) auto-regulator, (35) battery and (36) gate turn-off thyristor switch and (31) inverter and (37) auto-regulator in series, (36) The gate of the gate turn-off thyristor switch is connected to a coil set of two (30) open-loop core coils arranged side by side in parallel (37) On the circuit in which the auto-regulator is connected in series, (37) the auto-regulator is connected to the (38) control switch of the reluctance motor, and the (38) control switch of the reluctance motor is controlled by the (40) CPU, (38) Control switch and (39) reluctance motor connection, It is characterized by a core assembly coil assembly with an open component of the power take-off component (30), (45) a signal transmitter, (61) an inductor positioner and (62) a component assembled with the scanner and a power supply assembly (4) an open core The relative position of the coil assembly is controlled by two sets of motor systems and supported by (14) support frame, the support frame is fixed on the mobile device, (14) the support frame is composed of upper and lower parts, and (14) the upper and lower parts of the support frame are ( 13) Screws are connected together, power take-off assembly (30) open-loop core coil assembly, (45) signal transmitter, (61) inductive positioner and (62) scanner assembled parts are fixed in (15) wire One end of the rod, (15) the screw sleeve (16) the nut with the external gear is mounted on the (17) conical bearing, and (17) the conical bearing is placed on the (18) threaded slider, (18) The threaded slider is placed on the (19) screw, (18) the threaded slider is placed on the (14) slider of the (14) support frame, (16) the nut with the external gear and ( 23) The stepping motor is occluded by the output shaft of the (25) external gear after the (24) gearbox is shifted. (19) (21) and screw gear box (20) is connected to the stepper motor, It is characterized in that (62) a scanner, (61) an inductor positioner and (20) a stepper motor, and (23) a stepper motor are respectively connected to the (63) CPU;