Charging system based on secondary control and secondary control device thereof

Abstract

The invention discloses a charging system based on secondary control, which comprises a transformer, a rectifier device, a secondary rectifier switch transistor, a secondary synchronous rectifier auxiliary chip, a primary control chip and a primary switch transistor, wherein the secondary synchronous rectifier auxiliary chip controls opening and closing of the secondary rectifier switch transistor, detects output voltage and controls the secondary rectifier switch transistor to be opened when the output voltage drops and is smaller than a first reference voltage to enable an abrupt voltage to be generated at two ends of a secondary winding, and the abrupt voltage is fed back to an auxiliary winding; the primary control chip controls the primary switch transistor to be opened according to the abrupt voltage to enable the primary winding to be charged and controls the primary switch transistor to be closed when the voltage detected by a voltage detection end is larger than a second reference voltage to enable a primary winding to be discharged. The charging system can realize ultralow standby power consumption of the system and can also achieve effects of optimizing a system dynamic response. The invention also discloses a secondary control device for the charging system based on secondary control.

Description

technical field [0001] The invention relates to the technical field of chargers, in particular to a charging system based on secondary control and a secondary control device for the charging system based on secondary control. Background technique [0002] With the unification of the USB interface, most current chargers have certain requirements for the dynamic response of the system. The so-called dynamic response is the fluctuation range of the charger output voltage when the load terminal of the charger switches the load. The current mainstream optimization system dynamic response scheme can be divided into a primary-controlled charger scheme and a secondary-controlled charger scheme. [0003] Among them, the circuit diagram of a typical primary-controlled charger solution is as follows figure 1 As shown, since the output parameters of the charger are in the secondary part, and the primary control chip IC receives the secondary feedback signal only once per switching cycl...

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Problems solved by technology

[0004] The circuit diagram of a typical secondary controlled charger scheme is shown in figure 2 As shown, the secondary part adopts optocoupler and TL431, which can detect the change of charging voltage in real time and feed back to the primary control chip IC immediately, and is not affected by the operating frequency of the charger system, so the dynamic response effect of the system is better than that of the charger controlled by the primary The scheme is much better, but the secondary control charger scheme has more components than the primary control, the cost is high, and the loss of the optocoupler and TL431 itself is large, which is not conducive to the application of low-load and no-load power consumption chargers

[0005] The disadvantage of the existing technology is that when the primary control charger solution is used, the dynamic response effect of the system is

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