RU2199450C1 - Power supply source of mobile object - Google Patents

Abstract

FIELD: power supply sources. SUBSTANCE: proposed power supply source of mobile object contains storage battery, four capacitive energy accumulators, four discharge switches, four charging switches, charging device, electric motor and microcontroller. EFFECT: improved characteristics and reduced overall dimensions and mass. 1 dwg

Description

 The invention relates to energy sources of mobile objects using an electric motor as an actuator, and can be used in aircraft, automotive and other industries.

 There are a large number of various sources of energy supply for mobile objects, which include tracking systems in aviation, navigation systems, control systems on unmanned flying objects, the actuator of which is an electric motor.

 The prototype of the invention is the power source of a mobile object (RF patent RU 2085413 C1), which contains a battery, charger, capacitive energy storage, a combination of charging and discharge keys, an electric motor. Its disadvantage is that the capacitive energy storage device uses a short time, significantly less than the total operating time, and exclusively to overcome peak loads, and the rest of the power supply to the actuator (electric motor) is carried out from the battery, whose properties depend on the ambient temperature, therefore, for To ensure good dynamics, a high-capacity rechargeable battery is required, which leads to an increase in the overall mass indicators of the system itself.

 The objective of the invention is the improvement of dynamic properties and the reduction of overall mass indicators.

 The essence of the invention lies in the fact that the power source of the mobile object containing a battery, charger, a combination of charging and discharge keys, capacitive energy storage, the electric motor is additionally equipped with a microcontroller, three capacitive energy storage, the inputs of which are connected to the charging keys through the charger in the form throttles, and outputs through discharge keys with an electric motor, while the input of the microcontroller is connected to capacitive storage, and the output of the microcontroller Teller associated with charging and switches through bit keys, with the electric motor.

 The drawing shows a diagram of a power source of a mobile facility. The power source of the mobile object contains a rechargeable battery — a chemical current source (HIT) —1, a charger in the form of chokes — 2, capacitive energy stores — 3, 4, 5, and 6, charging keys — 7, 8, 9, and 10, discharge keys - 11, 12, 13, and 14, a charge key 7 of a capacitive energy storage device 3, a charge key 8 of a capacitive energy storage device 4, a charge key 9 of a capacitive energy storage device 5, a charge key 10 of a capacitive energy storage device 6, a discharge key 11 of a capacitive energy storage device 3, a key 12 discharge capacitive energy storage 4, key 13 discharge capacitive of the 5th energy storage device, discharge key 14 of the capacitive energy storage device 6, the microcontroller - 15, the input of which is proportional to the values of the operating voltages from the drives 3, 4, 5 and 6, and the output is the control voltage to the keys 7, 8, 9, 10 as well as 11, 12, 13 and 14, the actuator (electric motor) 16. The positive output of the battery 1 is connected through a key 7 to a capacitive energy storage 3, through a key 8 to a capacitive energy storage 4, through a key 9 to a capacitive energy storage 5 through key 10 with capacitive storage e Energy 6. Capacitive energy storage devices 3, 4, 5 and 6 are connected via keys 11, 12, 13, 14 respectively to the electric motor 16. The negative output of the battery 1 is connected to the negative plates of the capacitive energy storage devices 3, 4, 5 and 6 and the negative input electric motor 16.

 The charging process occurs when the keys 11, 12, 13 and 14 are open, switching of the input keys 7, 8, 9, 10 occurs when the voltage on the capacitive energy storage devices reaches the voltage values of the power source. In the initial state, all drives are charged.

 In the process of charging, the key 7 is initially closed and the capacitive energy storage device 3 is charged, at the moment the voltage of the power supply 1 (HIT) is reached on it, the key 8 is simultaneously closed and the key 7 is opened, after which the charging of the capacitive energy storage 4 begins, and at the time of reaching on it, the voltage of the power source 1 (CIIT) simultaneously closes the key 9 and the disconnection of the key 8, after which the charge of the capacitive energy storage unit 5 starts, and when the voltage of the power supply 1 (CIIT) reaches it It simultaneously locks the key 10 and opens the key 9, after which the charge of the capacitive energy storage device 6 starts, and when the voltage of the power supply 1 (HIT) reaches it, the key 10 opens. At the final stage of charging, all the keys are open and the voltage on the capacitive energy storage devices 3, 4, 5, and 6 are equal to the voltage at power source 1 (HIT).

 The process of the system and the process of recharging capacitive energy storage is carried out as follows: at the time of connecting the electric motor 16, the capacitive energy storage 3 starts to discharge to the electric motor 16, which is achieved by closing the key 11, with all other keys open. When the allowed residual voltage is reached on the capacitive energy storage 3, the input and output keys are switched - the key 12 is opened, connecting the energy storage 4 to the discharge, then after a certain delay time (previously set equal to the transient time in the motor circuit 16) the key is opened 11 and the closure of the key 7, as a result of which the recharging of the capacitive current storage 3 begins.

 When the allowed residual voltage is reached on the capacitive energy storage 4, the input and output keys are switched - the key 13 is closed, connecting the capacitive energy storage 5 to discharge, then after some delay time the key 12 opens and the key 8 closes, as a result of which the capacitive charging starts energy storage 4. At the moment the allowed residual voltage is reached on the capacitive energy storage 5, the input and output keys are switched - the key 14 is closed, connecting to discharge the capacitive energy storage device 6, then after a certain delay time the key 13 opens and the key 9 closes, as a result of which the capacitive energy storage device 5 starts charging. When the allowed residual voltage is reached on the capacitive energy storage device 6, the input and output keys are switched - key 11 it closes by connecting the capacitive energy storage device 3 to the discharge, then after a certain delay time, the key 14 opens and the key 10 closes, as a result of which the tapping begins a capacitive energy storage device 6. Further discharge of the system to the electric motor 16 occurs in similar cycles. In the considered mode of operation of the power system, there is a parallel process associated with charging capacitive energy storage devices 3, 4, 5, and 6.

 At the time when the capacitive energy storage 3 is recharged (the key 7 is closed and the key 11 is open) and the voltage value is equalized with the voltage value at the current source 1, or at the moment the discharge switch 11 closes (at the moment of the beginning of the discharge of the capacitive energy storage 3 to the electric motor 16), the charging key 7 is opened. At the time when the capacitive energy storage 4 is recharged (key 8 is closed and key 12 is open) and the voltage value is equalized with the voltage value to the source e current 1, or at the moment of closing the discharge key 12 (at the moment of starting the discharge of the capacitive energy storage 4 to the electric motor 16, the charging key is opened 8. At the time when the capacitive energy storage 5 is recharged (the key 9 is closed and the key 13 is open) and the voltage value is equalized with the voltage value at the current source 1, or at the moment of closing the discharge key 13 (at the time of discharging the capacitive energy storage 5 to the motor 16), the charging key 9 is opened. At the time and when the capacitive energy storage device 6 is recharged (the key 10 is closed and the key 14 is open) and the voltage value is equalized with the voltage value at the current source 1, or at the moment of the discharge key 14 closing (at the moment of the beginning of the discharge of the capacitive energy storage 6 to the electric motor 16) , the opening of the charging key 10.

 As a result of using the proposed scheme, not only the dynamic properties of the system are increased due to the possibility at each moment of time to obtain large values of the current supplied by the capacitive energy storage, as well as to carry out engine operation for a long time, but the overall dimensions of the system are also reduced, since The battery is used only for charging drives, and the engine is operated at the expense of energy stores.

Claims (1)

 A power supply source for a mobile object, comprising a storage battery, a capacitive energy storage device, a discharge key, an electric motor, characterized in that it is additionally equipped with four charging keys, three discharge keys, three capacitive energy storage devices, a microcontroller, the input of which is connected to capacitive energy storage devices, and the output - with charging keys and through discharge keys with an electric motor, while the inputs of capacitive energy storage devices are connected to the charging keys through the charger, and you Odes through the discharge keys - with the electric motor, the positive output of the battery is connected through the first key to the first capacitive energy storage, through the second key - to the second capacitive energy storage, through the third key - to the third capacitive energy storage, through the fourth key - to the fourth capacitive storage energy, the negative output of the battery is connected to the negative plates of the four capacitive energy storage devices and the negative input of the electric motor, and the charging process is capacitive energy storage occurs when the discharge keys are open, the switching of the charging keys occurs when the voltages of the capacitive energy stores reach the voltage values of the power source, and the process of discharging capacitive energy stores to an electric motor occurs when the charging keys are open, switching of charging and discharge keys occurs at the time of reaching the capacitive energy storage devices of the allowed residual voltage.