阅读说明：本技术 一种车载驱动防反接装置以及设备 (Vehicle-mounted driving reverse connection prevention device and equipment ) 是由 陈丽君 赵德琦 吴壬华 于 2020-12-29 设计创作，主要内容包括：一种车载驱动防反接装置(102)以及设备(10),该车载驱动防反接装置(102)包括电能驱动模块(20)以及防反接模块(30),其中：防反接模块(30)包括开关单元(301)和正向导通单元(302)；电能驱动模块(20)用于为开关单元(301)提供驱动电压；开关单元(301)的一端与正向导通单元(302)相连,开关单元(301)的另一端接地,用于在电能驱动模块(20)提供的驱动电压大于或等于导通阈值时导通,在电能驱动模块(20)提供的驱动电压小于导通阈值时截止；正向导通单元(302)与外接电池组(50)相连,用于在开关单元(301)导通时与外接电池组(50)形成闭合回路。(An on-vehicle drive anti-reverse connection device (102) and an apparatus (10), the on-vehicle drive anti-reverse connection device (102) comprising an electric power drive module (20) and an anti-reverse connection module (30), wherein: the reverse connection preventing module (30) comprises a switch unit (301) and a forward conduction unit (302); the electric energy driving module (20) is used for providing driving voltage for the switch unit (301); one end of the switch unit (301) is connected with the forward conduction unit (302), and the other end of the switch unit (301) is grounded and is used for conducting when the driving voltage provided by the electric energy driving module (20) is greater than or equal to the conduction threshold value and stopping when the driving voltage provided by the electric energy driving module (20) is less than the conduction threshold value; the forward conduction unit (302) is connected with the external battery pack (50) and used for forming a closed loop with the external battery pack (50) when the switch unit (301) is conducted.)

1. The vehicle-mounted driving reverse connection prevention device is characterized by comprising an electric energy driving module and a reverse connection prevention module, wherein the reverse connection prevention module comprises a switch unit and a forward conduction unit;

one end of the switch unit is connected with the electric energy driving module, the other end of the switch unit is connected with the forward conduction unit, one end of the forward conduction unit is connected with the electric energy driving module, the other end of the forward conduction unit is connected with a vehicle-mounted storage battery and an external battery pack, and the vehicle-mounted storage battery is connected with the external battery pack in parallel;

the electric energy driving module is used for outputting a driving voltage larger than or equal to a conduction threshold value to the switch unit to conduct when the external battery pack is in forward access, the forward conduction unit is used for forming a closed loop with the vehicle-mounted storage battery to charge the vehicle-mounted storage battery when the switch unit is conducted, wherein when the external battery pack is in reverse access, the electric energy driving module outputs the driving voltage smaller than the conduction threshold value to the switch unit, and the switch unit is cut off.

2. The vehicle-mounted driving reverse connection prevention device according to claim 1, wherein the electric energy driving module comprises a transformation winding, the transformation winding comprises a primary winding and a secondary winding, the primary winding is connected with the vehicle-mounted energy supply unit, the anode of the secondary winding is connected with the switch unit, the cathode of the secondary winding is grounded, and the electric energy driving module is used for converting the output voltage of the vehicle-mounted energy supply unit into the driving voltage and outputting the driving voltage to the switch unit.

3. The vehicle-mounted drive reverse connection prevention device according to claim 2, wherein the secondary winding further comprises a center tap, the center tap is connected with the forward conduction unit, and the center tap is used for outputting a reference voltage to the forward conduction unit when the switch unit is conducted.

4. The vehicle-mounted drive reverse connection prevention device according to claim 3, wherein the electric energy drive module further comprises a first rectifier diode, a second rectifier diode, a third rectifier diode, a first voltage stabilization capacitor and a second voltage stabilization capacitor, wherein:

the negative electrode of the first rectifier diode is connected with the negative electrode of the secondary winding, and the positive electrode of the first rectifier diode is grounded;

the negative electrode of the second rectifier diode is connected with the positive electrode of the secondary winding, and the positive electrode of the second rectifier diode is grounded;

the anode of the third rectifying diode is connected with the anode of the secondary winding, and the cathode of the third rectifying diode is connected with the switch unit and the second voltage-stabilizing capacitor;

one end of the first voltage-stabilizing capacitor is connected with the middle tap and the forward conduction unit, and the other end of the first voltage-stabilizing capacitor is grounded;

one end of the second voltage-stabilizing capacitor is connected with the switch unit, and the other end of the second voltage-stabilizing capacitor is grounded.

5. The vehicle-mounted drive reverse connection prevention apparatus according to claim 4, wherein said switching unit comprises a transistor, wherein:

and the emitting electrode of the triode is connected with the negative electrode of the third rectifier diode and the second voltage-stabilizing capacitor, the base electrode of the triode is grounded through a first protective resistor, and the collecting electrode of the triode is connected with the forward conduction unit.

6. The vehicle-mounted drive reverse-connection prevention device according to claim 5, wherein the forward conduction unit comprises a field effect transistor, wherein:

the grid electrode of the field effect tube is connected with the collector electrode of the triode in the switch unit through a second protective resistor, the source electrode of the field effect tube is connected with the external battery pack, and the drain electrode of the field effect tube is connected with the middle tap and used for generating conduction voltage between the grid electrode of the field effect tube and the source electrode of the field effect tube when the switch unit is conducted so as to conduct.

7. The vehicle-mounted drive reverse connection prevention device according to claim 6, wherein the forward conduction unit further comprises a clamp diode, a cathode of the clamp diode is connected with a grid electrode of the field effect transistor, an anode of the clamp diode is connected with a source electrode of the field effect transistor, and the clamp diode is used for limiting voltage between the grid electrode and the source electrode of the field effect transistor so as to prevent the field effect transistor from being broken down.

8. The vehicle-mounted drive reverse connection prevention device according to any one of claims 1 to 7, wherein the conduction threshold of the drive voltage is 10-14V.

9. The vehicle-mounted driving reverse connection prevention device according to claim 4, wherein the electric energy driving module further comprises a fourth rectifying diode, the anode of the fourth rectifying diode is connected with the cathode of the secondary winding and the cathode of the first rectifying diode, and the cathode of the fourth rectifying diode is connected with the cathode of the third rectifying diode and the second voltage-stabilizing capacitor.

10. An on-vehicle drive reverse-connection prevention apparatus, characterized by comprising an on-vehicle power supply unit and an on-vehicle drive reverse-connection prevention device according to any one of claims 1 to 9;

the vehicle-mounted driving reverse connection preventing device is connected with the vehicle-mounted energy supply unit through a half-bridge driving circuit.

Technical Field

The application relates to the field of electronic circuits, in particular to a vehicle-mounted driving reverse connection prevention device and equipment.

Background

At present, a vehicle-mounted direct current (DC-DC) converter is commonly used in a new energy automobile to replace a DC generator on the original traditional automobile to supply power to a low-voltage system of the whole automobile, and meanwhile, a vehicle-mounted low-voltage storage battery is subjected to floating charging. Because the vehicle-mounted low-voltage storage battery has self-discharge at the same time, after the vehicle is not used for a period of time, the vehicle-mounted battery enters a feed state, the voltage is low to the extent that many low-voltage systems of the whole vehicle cannot work, and the vehicle-mounted low-voltage storage battery also comprises a vehicle-mounted DC-DC converter. In order to restore the normal operation capability of the automobile, an external battery is generally required to be lapped on a low-voltage circuit of the whole automobile, so that the voltage of a low-voltage power supply system is restored to a normal level, and the vehicle-mounted DC-DC converter can work to supply power to the low-voltage system and charge a storage battery. However, the external battery has a reverse connection risk, once the positive electrode of the external battery is reversely connected to the negative electrode of the vehicle-mounted DC-DC converter, because the impedance from the negative electrode to the positive electrode in the vehicle-mounted DC-DC converter is extremely low, the reverse connection is equivalent to directly short-circuiting the external battery, a large current can be formed to damage the vehicle-mounted DC-DC converter, and even burn out the component.

Disclosure of Invention

In order to solve the problems, the embodiment of the application discloses a vehicle-mounted drive reverse connection prevention device and equipment, which can effectively avoid damage to internal devices of the drive device due to reverse connection of an external battery, and enhance the safety of the drive device.

In a first aspect, an embodiment of the present application provides a vehicle-mounted driving reverse connection prevention device, which includes an electric energy driving module and a reverse connection prevention module, where the reverse connection prevention module includes a switch unit and a forward conduction unit;

one end of the switch unit is connected with the electric energy driving module, the other end of the switch unit is connected with the forward conduction unit, one end of the forward conduction unit is connected with the electric energy driving module, the other end of the forward conduction unit is connected with a vehicle-mounted storage battery and an external battery pack, and the vehicle-mounted storage battery is connected with the external battery pack in parallel;

the electric energy driving module is configured to output a driving voltage greater than or equal to a turn-on threshold to the switch unit to turn on the switch unit when the external battery pack is connected in a forward direction, and the forward turn-on unit is configured to form a closed loop with the vehicle-mounted storage battery to charge the vehicle-mounted storage battery when the switch unit is connected in the forward direction.

With reference to the first aspect, in a possible implementation manner, the electric energy driving module includes a transformation winding, the transformation winding includes a primary winding and a secondary winding, the primary winding is connected to an on-vehicle energy supply unit, an anode of the secondary winding is connected to the switching unit, a cathode of the secondary winding is grounded, and the electric energy driving module is configured to convert an output voltage of the on-vehicle energy supply unit into a driving voltage and output the driving voltage to the switching unit.

With reference to the first aspect, in a possible implementation manner, the secondary winding further includes an intermediate tap, the intermediate tap is connected to a forward conducting unit, and the intermediate tap is configured to output a reference voltage to the forward conducting unit when the switching unit is turned on.

With reference to the first aspect, in a possible implementation manner, the electric energy driving module further includes a first rectifying diode, a second rectifying diode, a third rectifying diode, a first voltage stabilizing capacitor, and a second voltage stabilizing capacitor, where:

the negative electrode of the first rectifier diode is connected with the negative electrode of the secondary winding, and the positive electrode of the first rectifier diode is grounded;

the negative electrode of the second rectifier diode is connected with the positive electrode of the secondary winding, and the positive electrode of the second rectifier diode is grounded;

the positive pole of the third rectifier diode is connected with the positive pole of the secondary winding, and the negative pole of the third rectifier diode is connected with the switch unit and the second voltage-stabilizing capacitor;

one end of the first voltage-stabilizing capacitor is connected with the middle tap and the forward conduction unit, and the other end of the first voltage-stabilizing capacitor is grounded;

one end of the second voltage-stabilizing capacitor is connected with the switch unit, and the other end of the second voltage-stabilizing capacitor is grounded.

With reference to the first aspect, in one possible implementation manner, the switching unit includes a transistor, where:

and the emitting electrode of the triode is connected with the negative electrode of the third rectifier diode and the second voltage-stabilizing capacitor, the base electrode of the triode is grounded through a first protective resistor, and the collecting electrode of the triode is connected with the forward conduction unit.

With reference to the first aspect, in one possible implementation manner, the forward conduction unit includes a field effect transistor, where:

the grid electrode of the field effect tube is connected with the collector electrode of the triode in the switch unit through a second protective resistor, the source electrode of the field effect tube is connected with the external battery pack, and the drain electrode of the field effect tube is connected with the middle tap and used for generating conduction voltage between the grid electrode of the field effect tube and the source electrode of the field effect tube when the switch unit is conducted so as to conduct.

With reference to the first aspect, in one possible implementation manner, the forward conducting unit further includes a clamping diode, a negative electrode of the clamping diode is connected to the gate of the field effect transistor, and a positive electrode of the clamping diode is connected to the source of the field effect transistor, and the clamping diode is configured to limit a voltage between the gate and the source of the field effect transistor to prevent the field effect transistor from being broken down.

With reference to the first aspect, in one possible implementation manner, the turn-on threshold of the driving voltage is 10 to 14V.

With reference to the first aspect, in a possible implementation manner, the electric energy driving module further includes a fourth rectifying diode, an anode of the fourth rectifying diode is connected to a cathode of the secondary winding and a cathode of the first rectifying diode, and a cathode of the fourth rectifying diode is connected to a cathode of the third rectifying diode and the second voltage stabilizing capacitor.

In a second aspect, the embodiment of the present application provides an on-vehicle drive reverse connection prevention device, which includes an on-vehicle power supply unit and the on-vehicle drive reverse connection prevention device provided in the first aspect and/or any one of the possible implementation manners of the first aspect.

The embodiment of the application comprises an electric energy driving module and an anti-reverse connection module, wherein: the reverse connection prevention module comprises a switch unit and a forward conduction unit; the electric energy driving module is used for providing driving voltage for the switch unit; one end of the switch unit is connected with the forward conduction unit, and the other end of the switch unit is grounded and is used for conducting when the driving voltage provided by the electric energy driving unit is greater than or equal to a conduction threshold value and stopping when the driving voltage provided by the electric energy driving module is less than the conduction threshold value; the forward conduction unit is connected with an external battery pack and used for forming a closed loop with the external battery pack when the switch unit is conducted. The triode is used as a switch unit, the field effect tube is used as a forward conduction unit, damage to internal devices of the driving device due to reverse connection of an external battery is effectively avoided, and safety of the driving device is enhanced. In addition, a method of adding a tap in the middle of the transformer winding is utilized to provide conduction voltage for the triode and the field effect transistor, so that an anti-reverse connection circuit is effectively simplified, and the design and maintenance cost is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic view of a vehicle drive anti-reverse device provided by the present application;

FIG. 2 is a schematic structural diagram of a vehicle-mounted driving reverse connection prevention device provided by the present application;

FIG. 3 is a schematic view of another vehicle drive anti-reverse apparatus provided by the present application.

Detailed Description

In order to make the technical solutions better understood by those skilled in the art, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only partial embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The following are detailed below.

The terms "first," "second," "third," and "fourth," etc. in the description and claims of this application and in the accompanying drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments. In some scenarios requiring the battery as a secondary power source, such as in an on-board environment, the on-board low-voltage battery is a lead-acid battery, and thus has a small capacity and self-discharge. Therefore, after the automobile is not used for a period of time, the vehicle-mounted battery enters a feeding state, the voltage is low to the extent that many low-voltage systems of the whole automobile cannot work, and the vehicle-mounted battery also comprises an electric energy driving module. In order to restore the normal working capacity of the automobile, an external battery is generally required to be lapped on a low-voltage circuit of the whole automobile, so that the voltage of a low-voltage power supply system is restored to a normal level, and the electric energy driving module can work to supply power to the low-voltage system and charge a storage battery. However, when the positive electrode of the external battery is connected with the negative electrode of the electric energy driving module, and the negative electrode of the external battery is connected with the positive electrode of the electric energy driving module), because the impedance from the negative electrode to the positive electrode in the electric energy driving module is extremely low, the reverse connection is equivalent to directly short-circuiting the vehicle-mounted storage battery, and a large current can be formed to damage elements in the electric energy driving module. For convenience, the present application will be described by taking an in-vehicle driving apparatus including a half-bridge circuit as a driving circuit as an example.

FIG. 1 is a schematic diagram of a vehicle-mounted drive anti-reverse device provided by the application. The application provides a reverse-connection preventing device for vehicle-mounted driving comprises an electric energy driving module and a reverse-connection preventing module, wherein the reverse-connection preventing module comprises a switch unit and a forward conduction unit, and the reverse-connection preventing module comprises a switch unit and a forward conduction unit, wherein:

one end of the switch unit is connected with the electric energy driving module, the other end of the switch unit is connected with the forward conduction unit, one end of the forward conduction unit is connected with the electric energy driving module, the other end of the forward conduction unit is connected with a vehicle-mounted storage battery and an external battery pack, and the vehicle-mounted storage battery is connected with the external battery pack in parallel;

the electric energy driving module is used for outputting a driving voltage which is larger than or equal to a conduction threshold value to the switch unit when the external battery pack is connected in a forward direction so as to conduct the switch unit, and the forward conduction unit is used for forming a closed loop with the vehicle-mounted storage battery when the switch unit is conducted so as to charge the vehicle-mounted storage battery. When the external battery pack is reversely connected, the driving voltage output to the switch unit by the electric energy driving module is smaller than the conduction threshold value, and the switch unit is turned off.

In some possible embodiments, the electric energy driving module includes a transformer winding, the transformer winding includes a primary winding and a secondary winding, the primary winding is connected to the vehicle-mounted energy supply unit, an anode of the secondary winding is connected to the switching unit, a cathode of the secondary winding is grounded, and the electric energy driving module is configured to convert an output voltage of the vehicle-mounted energy supply unit into a driving voltage and output the driving voltage to the switching unit.

In some possible embodiments, the secondary winding further includes an intermediate tap, the intermediate tap is connected to the forward conducting unit, and the intermediate tap is configured to output a reference voltage to the forward conducting unit when the switching unit is turned on.

In some possible embodiments, the power driving module further includes a first rectifying diode D1, a second rectifying diode D2, a third rectifying diode D3, a first voltage-stabilizing capacitor C1, and a second voltage-stabilizing capacitor C2, wherein: a negative electrode of the first rectifying diode D1 is connected to a negative electrode of the secondary winding, and a positive electrode of the first rectifying diode D1 is grounded; a negative electrode of the second rectifier diode D2 is connected to a positive electrode of the secondary winding, and a positive electrode of the second rectifier diode D2 is grounded; an anode of the third rectifying diode D3 is connected to an anode of the secondary winding, and a cathode of the third rectifying diode D3 is connected to the switching unit and the second voltage stabilizing capacitor C2; one end of the first voltage-stabilizing capacitor C1 is connected to the center tap and the forward conducting unit, and the other end of the first voltage-stabilizing capacitor C1 is grounded; one end of the second voltage stabilizing capacitor C2 is connected to the switching unit, and the other end of the second voltage stabilizing capacitor C2 is grounded.

In some possible embodiments, the switching unit includes a transistor Q2, wherein: an emitter E of the transistor Q2 is connected to a negative electrode of the third rectifying diode, a base B of the transistor Q2 is grounded through a first protection resistor R1, and a collector C of the transistor Q2 is connected to the forward conducting unit.

In some possible embodiments, the forward conducting unit includes a field effect transistor Q1, where: the gate G of the fet Q1 is connected to the collector C of the transistor Q2 of the switching unit through a second protection resistor R2, the source S of the fet Q1 is connected to the external battery pack, and the drain D of the fet Q1 is connected to the center tap, and is configured to generate a turn-on voltage between the gate G of the fet Q1 and the source S of the fet Q1 to turn on the switching unit when the switching unit is turned on.

In some possible embodiments, when the external battery pack is turned on in the forward direction, the power driving module starts to operate, and the first rectifying diode D1, the second rectifying diode D2 and the voltage stabilizing capacitor C1 stabilize the ac voltage at the center tap to be the dc voltage VOUT. The voltage of VOUT is the same as that of the vehicle-mounted storage battery, and can be equal to the output voltage of the electric energy driving module. And the third rectifying diode D3 and the second voltage stabilizing capacitor C2 stabilize the ac voltage at the anode of the secondary winding to a dc voltage V1, and the voltage magnitude of V1 may be 2 times VOUT. The direct-current voltage V1 acts on the emitter E of the transistor Q2 through the protection resistor R1, so that a bias current is formed between the emitter E and the base B of the transistor Q2, and the emitter E and the collector C of the transistor Q2 are turned on. The V1 is applied to the grid G of the field effect transistor Q1 through the triode Q2 and the second protection resistor R2, so that the field effect transistor Q1 is conducted, and the requirement of low impedance of an anti-reverse circuit in normal work is met.

When the external battery pack is reversely connected, the anode of the external battery pack is connected with the cathode of the electric energy driving module and is grounded with one end of the second voltage-stabilizing capacitor C2. The negative electrode of the external battery pack is also connected to the other end of the second voltage stabilizing capacitor C2 through the secondary winding, the first rectifying diode D1, the second rectifying diode D2 and the third rectifying diode D3. Therefore, the voltage across the second voltage-stabilizing capacitor C2 is equal, i.e., V1 is 0. No bias current can be formed between the emitter E and the collector C of the transistor Q2, and the transistor Q2 cannot conduct. Therefore, the grid G of the field-effect transistor Q1 is lower than the turn-on voltage, the field-effect transistor Q1 is in the cut-off state, and the forward impedance is very large, so that a large current cannot be formed through the secondary winding, the first rectifier diode D1, the second rectifier diode D2, the third rectifier diode D3 and the field-effect transistor Q1 after the external battery pack is reversely connected, and elements in the electric power driving module are protected.

In some possible embodiments, VOUT is equal to the output voltage of the power driving module, which is between 10-14V, and V1 is 2 times higher than VOUT, so that the voltage applied between the gate G and the source S of fet Q1 is equal to VOUT, which is enough to drive fet Q1 into a low impedance state.

The embodiment of the application comprises an electric energy driving module and an anti-reverse connection module, wherein: the reverse connection prevention module comprises a switch unit and a forward conduction unit; the electric energy driving module is used for providing driving voltage for the switch unit; one end of the switch unit is connected with the forward conduction unit, and the other end of the switch unit is grounded and is used for conducting when the driving voltage provided by the electric energy driving module is greater than or equal to a conduction threshold value and stopping when the driving voltage provided by the electric energy driving module is less than the conduction threshold value; the forward conduction unit is connected with an external battery pack and used for forming a closed loop with the external battery pack when the switch unit is conducted. The triode is used as a switch unit, the field effect tube is used as a forward conduction unit, damage to internal devices of the driving device due to reverse connection of an external battery is effectively avoided, and safety of the driving device is enhanced. In addition, a method of adding a tap in the middle of the transformer winding is utilized to provide conduction voltage for the triode and the field effect transistor, so that an anti-reverse connection circuit is effectively simplified, and the design and maintenance cost is reduced.

Alternatively, as shown in fig. 2, fig. 2 is a schematic structural diagram of a vehicle-mounted drive anti-reverse connection device provided by the present application. The vehicle-mounted drive anti-reverse connection apparatus 10 includes a vehicle-mounted power supply unit 101 and a vehicle-mounted drive anti-reverse connection device 102. The vehicle-mounted energy supply unit 101 comprises a half-bridge driving circuit, the vehicle-mounted driving reverse connection prevention device 102 comprises an electric energy driving module 20 and a reverse connection prevention module 30, and the reverse connection prevention module 30 comprises a switch unit 301 and a forward conduction unit 302;

one end of the switch unit 301 is connected to the electric energy driving module 20, the other end of the switch unit 301 is connected to the forward conduction unit 302, one end of the forward conduction unit 302 is connected to the electric energy driving module 20, the other end of the forward conduction unit 302 is connected to the vehicle-mounted storage battery 40 and the external battery pack 50, and the vehicle-mounted storage battery 40 is connected in parallel to the external battery pack 50;

the power driving module 20 is configured to output a driving voltage greater than or equal to an on-threshold to the switching unit 301 to turn on the switching unit 301 when the external battery pack 50 is connected in a forward direction, and the forward-direction connection unit 302 is configured to be connected to the switching unit 301 and form a closed loop with the vehicle-mounted storage battery 40 to charge the vehicle-mounted storage battery 40 when the switching unit 301 is connected in the forward direction, wherein the driving voltage output to the switching unit 301 by the power driving module 20 when the external battery pack 50 is connected in the reverse direction is less than the on-threshold, and the switching unit 301 is turned off.

In some possible embodiments, the electric power driving module 20 includes a transformer winding, the transformer winding includes a primary winding and a secondary winding, the primary winding is connected to the vehicle-mounted energy supply unit, an anode of the secondary winding is connected to the switching unit 301, a cathode of the secondary winding is grounded, and the electric power driving module 20 is configured to convert an output voltage of the vehicle-mounted energy supply unit into a driving voltage and output the driving voltage to the switching unit 301.

In some possible embodiments, the secondary winding further includes an intermediate tap, and the intermediate tap is connected to the forward conducting unit 302, and is used for outputting a reference voltage to the forward conducting unit 302 when the switching unit 301 is turned on.

In some possible embodiments, the power driving module 20 further includes a first rectifying diode D1, a second rectifying diode D2, a third rectifying diode D3, a first voltage-stabilizing capacitor C1, and a second voltage-stabilizing capacitor C2, wherein: a negative electrode of the first rectifying diode D1 is connected to a negative electrode of the secondary winding, and a positive electrode of the first rectifying diode D1 is grounded; a negative electrode of the second rectifier diode D2 is connected to a positive electrode of the secondary winding, and a positive electrode of the second rectifier diode D2 is grounded; a positive electrode of the third rectifying diode D3 is connected to a positive electrode of the secondary winding, and a negative electrode of the third rectifying diode D3 is connected to the switching unit 301 and the second voltage stabilizing capacitor C2; one end of the voltage stabilizing capacitor C1 is connected to the center tap and the forward conducting unit 302, and the other end of the voltage stabilizing capacitor C1 is grounded; one end of the second voltage stabilizing capacitor C2 is connected to the switch unit 301, and the other end of the second voltage stabilizing capacitor C2 is grounded.

In some possible embodiments, the switching unit 301 includes a transistor Q2, where: an emitter E of the transistor Q2 is connected to a cathode of the third rectifying diode, a base B of the transistor Q2 is grounded through a first protection resistor, and a collector C of the transistor Q2 is connected to the forward conducting unit 302.

In some possible embodiments, the forward conducting unit 302 includes a field effect transistor Q1, where: the gate G of the fet Q1 is connected to the collector C of the transistor Q2 of the switching unit through a second protection resistor, the source S of the fet Q1 is connected to the external battery pack 50, and the drain D of the fet Q1 is connected to the center tap, and is configured to generate a turn-on voltage between the gate G of the fet Q1 and the source S of the fet Q1 to turn on the switching unit 301 when turned on.

In some possible embodiments, when the external battery pack 50 is turned on in the forward direction, the power driving module 20 starts to operate, and the first rectifying diode D1, the second rectifying diode D2 and the voltage stabilizing capacitor C1 stabilize the ac voltage at the center tap to be the dc voltage VOUT. The voltage of VOUT is the same as the voltage of the vehicle-mounted battery 40, and may be equal to the output voltage of the electric energy driving module 20. And the third rectifying diode D3 and the second voltage stabilizing capacitor C2 stabilize the ac voltage at the anode of the secondary winding to a dc voltage V1, and the voltage magnitude of V1 may be 2 times VOUT. The direct-current voltage V1 acts on the emitter E of the transistor Q2 through the protection resistor R1, so that a bias current is formed between the emitter E and the base B of the transistor Q2, and the emitter E and the collector C of the transistor Q2 are turned on. The V1 is applied to the grid G of the field effect transistor Q1 through the triode Q2 and the second protection resistor R2, so that the field effect transistor Q1 is conducted, and the requirement of low impedance of an anti-reverse circuit in normal work is met.

When the external battery pack 50 is reversely connected, the positive electrode of the external battery pack 50 is connected to the negative electrode of the electric power driving module 20, and is grounded together with one end of the second voltage stabilizing capacitor C2. The negative electrode of the external battery pack 50 is also connected to the other end of the second voltage stabilizing capacitor C2 through the secondary winding, the first rectifying diode D1, the second rectifying diode D2, and the third rectifying diode D3. Therefore, the voltage across the second voltage-stabilizing capacitor C2 is equal, i.e., V1 is 0. No bias current can be formed between the emitter E and the collector C of the transistor Q2, and the transistor Q2 cannot conduct. Therefore, the gate G of the fet Q1 is lower than the turn-on voltage, the fet Q1 is in the off state, and the forward impedance is large, so that a large current is not formed through the secondary winding, the first rectifier diode D1, the second rectifier diode D2, the third rectifier diode D3, and the fet Q1 after the external battery pack 50 is reversely connected, thereby protecting the components in the electric power driving module 20.

In some possible embodiments, VOUT is equal to the output voltage of the power driving module 20, which is between 10-14V, and V1 is 2 times higher than VOUT, so that the voltage applied between the gate G and the source S of the fet Q1 is equal to VOUT, which is enough to drive the fet Q1 into the low impedance state.

The vehicle-mounted driving reverse connection preventing equipment comprises a vehicle-mounted energy supply unit, an electric energy driving module and a reverse connection preventing module, wherein: the vehicle-mounted energy supply unit comprises a half-bridge driving circuit, and the reverse connection prevention module comprises a switch unit and a forward conduction unit; the electric energy driving module is used for providing driving voltage for the switch unit; one end of the switch unit is connected with the forward conduction unit, and the other end of the switch unit is grounded and is used for conducting when the driving voltage provided by the electric energy driving module is greater than or equal to a conduction threshold value and stopping when the driving voltage provided by the electric energy driving module is less than the conduction threshold value; the forward conduction unit is connected with an external battery pack and used for forming a closed loop with the external battery pack when the switch unit is conducted. The triode is used as a switch unit, the field effect tube is used as a forward conduction unit, damage to internal devices of the driving device due to reverse connection of an external battery is effectively avoided, and safety of the driving device is enhanced. In addition, a method of adding a tap in the middle of the transformer winding is utilized to provide conduction voltage for the triode and the field effect transistor, so that an anti-reverse connection circuit is effectively simplified, and the design and maintenance cost is reduced.

Fig. 3 is a schematic diagram of another vehicle-mounted driving reverse connection prevention device provided by the present application, which includes an electric energy driving module and a reverse connection prevention module, where the reverse connection prevention module includes a switch unit and a forward conduction unit, where:

one end of the switch unit is connected with the electric energy driving module, the other end of the switch unit is connected with the forward conduction unit, one end of the forward conduction unit is connected with the electric energy driving module, the other end of the forward conduction unit is connected with a vehicle-mounted storage battery and an external battery pack, and the vehicle-mounted storage battery is connected with the external battery pack in parallel;

the electric energy driving module is used for outputting a driving voltage which is larger than or equal to a conduction threshold value to the switch unit when the external battery pack is connected in a forward direction so as to conduct the switch unit, and the forward conduction unit is used for forming a closed loop with the vehicle-mounted storage battery when the switch unit is conducted so as to charge the vehicle-mounted storage battery. When the external battery pack is reversely connected, the driving voltage output to the switch unit by the electric energy driving module is smaller than the conduction threshold value, and the switch unit is turned off.

In some possible embodiments, since the on-board low-voltage battery is a lead-acid battery, the capacity is small, while there is self-discharge. Therefore, after the automobile is not used for a period of time, the vehicle-mounted battery enters a feeding state, the voltage is low to the extent that many low-voltage systems of the whole automobile cannot work, and the vehicle-mounted battery also comprises an electric energy driving module. In order to restore the normal working capacity of the automobile, an external battery is generally required to be lapped on a low-voltage circuit of the whole automobile, so that the voltage of a low-voltage power supply system is restored to a normal level, and the electric energy driving module can work to supply power to the low-voltage system and charge a storage battery. However, when the positive electrode of the external battery is connected with the negative electrode of the electric energy driving module, and the negative electrode of the external battery is connected with the positive electrode of the electric energy driving module), because the impedance from the negative electrode to the positive electrode in the electric energy driving module is extremely low, the reverse connection is equivalent to directly short-circuiting the vehicle-mounted storage battery, and a large current can be formed to damage elements in the electric energy driving module.

In some possible embodiments, the electric energy driving module includes a transformer winding, the transformer winding includes a primary winding and a secondary winding, the primary winding is connected to the vehicle-mounted energy supply unit, an anode of the secondary winding is connected to the switching unit, a cathode of the secondary winding is grounded, and the electric energy driving module is configured to convert an output voltage of the vehicle-mounted energy supply unit into a driving voltage and output the driving voltage to the switching unit.

In some possible embodiments, the secondary winding further includes an intermediate tap, the intermediate tap is connected to the forward conducting unit, and the intermediate tap is configured to output a reference voltage to the forward conducting unit when the switching unit is turned on.

In some possible embodiments, the power driving module further includes a first rectifying diode D1, a second rectifying diode D2, a third rectifying diode D3, a first voltage-stabilizing capacitor C1, and a second voltage-stabilizing capacitor C2, wherein: a negative electrode of the first rectifying diode D1 is connected to a negative electrode of the secondary winding, and a positive electrode of the first rectifying diode D1 is grounded; a negative electrode of the second rectifier diode D2 is connected to a positive electrode of the secondary winding, and a positive electrode of the second rectifier diode D2 is grounded; an anode of the third rectifying diode D3 is connected to an anode of the secondary winding, and a cathode of the third rectifying diode D3 is connected to the switching unit and the second voltage stabilizing capacitor C2; one end of the voltage stabilizing capacitor C1 is connected to the center tap and the forward conducting unit, and the other end of the voltage stabilizing capacitor C1 is grounded; one end of the second voltage stabilizing capacitor C2 is connected to the switching unit, and the other end of the second voltage stabilizing capacitor C2 is grounded.

In some possible embodiments, the power driving module further includes a fourth rectifying diode D4, an anode of the fourth rectifying diode D4 is connected to a cathode of the secondary winding and a cathode of the first rectifying diode D1, and an anode of the fourth rectifying diode D4 is connected to a cathode of the third rectifying diode D3 and the second voltage stabilizing capacitor C2. The fourth rectifying diode D4 enhances the voltage applied to the second voltage stabilizing capacitor C2, further increasing the stability of the power driving module.

In some possible embodiments, the switching unit includes a transistor Q2, wherein: an emitter E of the transistor Q2 is connected to a negative electrode of the third rectifying diode, a base B of the transistor Q2 is grounded through a first protection resistor, and a collector C of the transistor Q2 is connected to the forward conducting unit.

In some possible embodiments, the forward conducting unit includes a field effect transistor Q1, where: the gate G of the fet Q1 is connected to the collector C of the transistor Q2 of the switching unit through a second protection resistor R2, the source S of the fet Q1 is connected to the external battery pack, and the drain D of the fet Q1 is connected to the center tap, and is configured to generate a turn-on voltage between the gate G of the fet Q1 and the source S of the fet Q1 to turn on the switching unit when the switching unit is turned on.

In some possible embodiments, when the external battery pack is turned on in the forward direction, the power driving module starts to operate, and the first rectifying diode D1, the second rectifying diode D2 and the voltage stabilizing capacitor C1 stabilize the ac voltage at the center tap to be the dc voltage VOUT. The voltage of VOUT is the same as that of the vehicle-mounted storage battery, and can be equal to the output voltage of the electric energy driving module. And the third rectifying diode D3 and the second voltage stabilizing capacitor C2 stabilize the ac voltage at the anode of the secondary winding to a dc voltage V1, and the voltage magnitude of V1 may be 2 times VOUT. The direct-current voltage V1 acts on the emitter E of the transistor Q2 through the protection resistor R1, so that a bias current is formed between the emitter E and the base B of the transistor Q2, and the emitter E and the collector C of the transistor Q2 are turned on. The V1 is applied to the grid G of the field effect transistor Q1 through the triode Q2 and the second protection resistor R2, so that the field effect transistor Q1 is conducted, and the requirement of low impedance of an anti-reverse circuit in normal work is met.

When the external battery pack is reversely connected, the anode of the external battery pack is connected with the cathode of the electric energy driving module and is grounded with one end of the second voltage-stabilizing capacitor C2. The negative electrode of the external battery pack is also connected to the other end of the second voltage stabilizing capacitor C2 through the secondary winding, the first rectifying diode D1, the second rectifying diode D2 and the third rectifying diode D3. Therefore, the voltage across the second voltage-stabilizing capacitor C2 is equal, i.e., V1 is 0. No bias current can be formed between the emitter E and the collector C of the transistor Q2, and the transistor Q2 cannot conduct. Therefore, the grid G of the field-effect transistor Q1 is lower than the turn-on voltage, the field-effect transistor Q1 is in the cut-off state, and the forward impedance is very large, so that a large current cannot be formed through the secondary winding, the first rectifier diode D1, the second rectifier diode D2, the third rectifier diode D3 and the field-effect transistor Q1 after the external battery pack is reversely connected, and elements in the electric power driving module are protected.

In some possible embodiments, VOUT is equal to the output voltage of the power driving module, which is between 10-14V, and V1 is 2 times higher than VOUT, so that the voltage applied between the gate G and the source S of fet Q1 is equal to VOUT, which is enough to drive fet Q1 into a low impedance state.

In some possible embodiments, the forward conducting unit further includes a clamping diode ZD1, a cathode of the clamping diode ZD1 is connected to the gate G of the fet Q1, and an anode of the clamping diode is connected to the source S of the fet Q1, and the clamping diode ZD1 is configured to limit a voltage between the gate G and the source S of the fet to prevent the fet Q1 from breaking down.

The embodiment of the application comprises an electric energy driving module and an anti-reverse connection module, wherein: the reverse connection prevention module comprises a switch unit and a forward conduction unit; the electric energy driving module is used for providing driving voltage for the switch unit; one end of the switch unit is connected with the forward conduction unit, and the other end of the switch unit is grounded and is used for conducting when the driving voltage provided by the electric energy driving module is greater than or equal to a conduction threshold value and stopping when the driving voltage provided by the electric energy driving module is less than the conduction threshold value; the forward conduction unit is connected with an external battery pack and used for forming a closed loop with the external battery pack when the switch unit is conducted. The triode is used as a switch unit, the field effect tube is used as a forward conduction unit, damage to internal devices of the driving device due to reverse connection of an external battery is effectively avoided, and safety of the driving device is enhanced. In addition, a method of adding a tap in the middle of the transformer winding is utilized to provide conduction voltage for the triode and the field effect transistor, so that an anti-reverse connection circuit is effectively simplified, and the design and maintenance cost is reduced.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.