CN113482832A - Intelligent ignition clamp and starting device - Google Patents

Abstract

The utility model provides an intelligence ignition presss from both sides, includes power incoming end and two ignition clips, and the power incoming end is used for external start power supply, and two ignition clips are used for being connected with the storage battery of a load. The intelligence ignition presss from both sides still includes: the device comprises a main controller, a clamp polarity detection module and a clamp connection module. The main controller is connected with the clamp polarity detection module and the clamp connection module, and the clamp polarity detection module and the clamp connection module are further connected with the two ignition clamps. When two ignition clips are connected with the storage battery, the clip polarity detection module is used for detecting the polarity of the storage battery connected with the two ignition clips respectively, the main controller is used for acquiring the detection result signal of the clip polarity detection module, and controlling the clip switch-on module to correspond to the polarity of the two ignition clips according to the polarity of the storage battery according to the detection result signal, and the power supply access end and the two paths of the ignition clips are switched on, so that the storage battery is switched on.

Description

Intelligent ignition clamp and starting device

Technical Field

The invention belongs to the technical field of electronics, and particularly relates to an intelligent ignition clamp and a starting device.

Background

The automobile adopts an ignition system controlled by a microprocessor, and because the displacement of the automobile is different, the current, the voltage and the power required by ignition start are also different, and the undervoltage and the damage degree of a storage battery on the automobile are also different, so that ignition clamps with different functions appear. There are a Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET) control type, a power diode type, a pass-through type, and the like.

However, the ignition clips of the above types have respective technical defects, and the ignition clips of the MOS tube control type have the technical defects that the ignition clips are difficult to start for a large-displacement vehicle, are easy to generate heat to cause over-temperature burning of the MOS tube, ignition cannot be completed after ignition is successful, an ignition loop cannot be disconnected, and an ignition function cannot be normally started after a storage battery is dead; the power diode control type ignition clamp is difficult to start for a large-displacement vehicle, is easy to generate heat to cause over-temperature diode burning, has no short-circuit protection, cannot detect the completion of ignition after successful ignition, and cannot disconnect an ignition loop; the straight-through type ignition clamp has no reverse connection protection and short-circuit protection, and the ignition clamp and the storage battery cannot be successfully ignited even resulting in potential safety hazards such as short circuit ignition and the like due to wrong connection.

Disclosure of Invention

The invention provides an intelligent ignition clamp and a starting device, and aims to solve one or more technical problems in the conventional ignition clamp.

The embodiment of the invention provides an intelligent ignition clamp which comprises a power supply access end and two ignition clamps, wherein the power supply access end is externally connected with a starting power supply, the two ignition clamps are used for being connected with a loaded storage battery, and the intelligent ignition clamp further comprises a main controller, a clamp polarity detection module and a clamp connection module;

the main controller is connected with the clamp polarity detection module and the clamp connection module, and the clamp polarity detection module and the clamp connection module are also connected with the two ignition clamps;

two ignition clips with when the storage battery is connected, clip polarity detection module is used for detecting two ignition clips are connected respectively the polarity of storage battery, main control unit is used for acquireing clip polarity detection module's testing result signal, and according to testing result signal control clip switch-on module follows the polarity of storage battery corresponds the affirmation two polarity of ignition clips, and switch-on the power incoming end with the route of two ignition clips, thereby the switch-on the storage battery.

The embodiment of the invention also provides a starting device which comprises a starting power supply and the intelligent ignition clamp, wherein the starting power supply comprises an output port, and a power supply access end of the intelligent ignition clamp can be connected with the output port of the starting power supply in a plugging manner.

According to the embodiment of the invention, the intelligent ignition clamp comprises a power supply access end, two ignition clamps, a main controller, a clamp polarity detection module and a clamp connection module, wherein the main controller is connected with the clamp polarity detection module and the clamp connection module, the clamp polarity detection module and the clamp connection module are also connected with the two ignition clamps, when the two ignition clamps are connected with the storage battery, the clamp polarity detection module detects the polarities of the storage battery respectively connected with the two ignition clamps, the main controller acquires a detection result signal of the clamp polarity detection module, controls the clamp connection module to correspondingly determine the polarities of the two ignition clamps according to the polarity of the storage battery according to the detection result signal, and connects the two ignition clamps and the storage battery. Because the polarity of two ignition clips is according to the polarity automatic determination of storage battery, consequently need not to confirm in advance whether the polarity of storage battery and ignition clip corresponds, can realize two ignition clips through above-mentioned intelligence ignition clip according to the polarity and the storage battery intercommunication of storage battery, realize normally igniteing, improve the success rate of igniting, and because ignition clip has realized the nonpolarity with being connected of storage battery and has been connected, avoid the harm that the transposition leads to, improved the reliability and the life of ignition clip.

Drawings

In order to more clearly illustrate the embodiments of the present invention 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, and it is obvious that the drawings in the following description are only some embodiments of the present invention.

FIG. 1 is a functional block diagram of an intelligent ignition clip provided in accordance with an embodiment of the present invention;

FIG. 2 is a functional block diagram of an intelligent ignition clip provided in accordance with another embodiment of the present invention;

FIG. 3 is a schematic diagram of a circuit structure of a main controller and a connection relationship in an intelligent ignition clamp according to an embodiment of the present invention;

FIG. 4 is a schematic diagram illustrating the structure and connection relationship of a clip polarity detection module in the smart ignition clip according to an embodiment of the present invention;

fig. 5 is a schematic circuit diagram illustrating the configuration and connection relationship of the input polarity detection module, the clip-on module, and the relay detection module in the intelligent ignition clip according to the embodiment of the present invention;

fig. 6 is a schematic circuit structure diagram of the structures and connection relations of the input polarity control module, the voltage stabilizing module and the alarm module in the intelligent ignition clamp according to the embodiment of the present invention;

fig. 7 is a schematic diagram of the structure and connection relationship of the indicating module in the intelligent ignition clamp according to the embodiment of the invention.

FIG. 8 is a schematic flow chart illustrating an implementation of an ignition control method provided by an embodiment of the invention;

fig. 9 is a perspective view of an activation device according to an embodiment of the present invention.

Fig. 10 is an enlarged partial view of the smart ignition clip of the starting device of fig. 9.

Fig. 11 is a partially enlarged view of the starting power supply of the starting apparatus shown in fig. 9.

Fig. 12 is a perspective view of an ignition clip of the smart ignition clip provided in accordance with an embodiment of the present invention.

Fig. 13 is a schematic structural view of the body of the smart ignition clamp shown in fig. 12.

Detailed Description

In order to make the objects, features and advantages of the present invention more obvious and understandable, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only a part of the embodiments of the present invention, and not all of the 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 invention.

Referring to fig. 1, fig. 1 is a schematic structural diagram of an intelligent ignition clip according to an embodiment of the present invention, which can be used in an electronic system requiring ignition starting, such as an automobile or a yacht, for connecting an external starting power source (e.g., a portable or handheld power source) to a battery of the automobile or the yacht to start an engine thereof. The following description takes the example of an automobile ignition, and the smart ignition clip includes two ignition clips: a first ignition clamp 11 and a second ignition clamp 12. The two ignition clamps 11 and 12 are used for being connected with a storage battery of the automobile. The intelligent ignition clamp further comprises a power supply access end (not shown) for plugging and connecting with the output port of the starting power supply. This intelligence ignition presss from both sides still includes:

the main controller 13, the clamp polarity detection module 14 and the clamp connection module 15;

the main controller 13 specifically includes a main control chip and peripheral circuits, the main control chip is specifically an mcu (microcontroller unit), and the specific model may be HT66F018, and has 20 pins.

The main controller 13 connects the clip polarity detection module 14 and the clip connection module 15, and the clip polarity detection module 14 and the clip connection module 15 are also connected to the first ignition clip 11 and the second ignition clip 12.

The storage battery of the automobile is divided into a positive pole and a negative pole. When the intelligent ignition clamp connects the starting power supply with the automobile battery, one of the first ignition clamp 11 and the second ignition clamp 12 is a positive ignition clamp, and the other is a negative ignition clamp. However, when the two ignition clamps in the embodiment of the application are connected with the battery, the anode and the cathode do not need to be distinguished. That is, for any ignition clamp, there is no difference between the positive and negative electrodes before the circuit is turned on, and it can be connected to the positive electrode of the battery or the negative electrode of the battery. That is, the first ignition clamp 11 may be connected to the positive electrode of the battery, and the second ignition clamp 12 may be connected to the negative electrode of the battery to achieve conduction. Or the first ignition clamp 11 is connected with the cathode of the battery, and the second ignition clamp 12 is connected with the anode of the battery to realize conduction. When the two ignition clamps are connected with the battery, the clamp polarity detection module 14 is used for detecting the polarities of the battery respectively connected with the two ignition clamps. Namely, the two ignition clamps are respectively connected to the anode or the cathode of the battery. The main controller 13 is configured to obtain a detection result signal of the clamp polarity detection module 14, where the detection result signal is specifically a level signal. Preferably, the detection result signal is a low level signal.

Referring to fig. 2, fig. 2 is a schematic structural diagram of an intelligent ignition clamp according to another embodiment of the present invention. Compared to the first embodiment, the clip polarity detection module 14 of the present embodiment can be specifically divided into a first clip polarity detection module 141 and a second clip polarity detection module 142. The first clip polarity detection module 141 and the second clip polarity detection module 142 are connected to the first ignition clip 11 and the second ignition clip 12, respectively, and to different pins of the main controller 13, respectively. When the two ignition clamps are connected to the battery, if the pin connected to the first clamp polarity detection module 141 in the main controller 13 detects that the high level signal is pulled down to be a low level signal, it is determined that the second ignition clamp 12 is connected to the positive electrode of the battery. On the contrary, when the pin connected to the second clamp polarity detection module 142 in the main controller 13 detects that the high level signal is pulled low to be a low level signal, it is determined that the first ignition clamp 11 is connected to the positive electrode of the battery.

Further, the main controller 13 controls the clip connection module 15 according to the detection result signal to correspondingly determine the polarities of the two ignition clips according to the detected polarities of the battery cells connected with the two ignition clips, and the two ignition clips are connected in the same polarity. Namely, the ignition clamp connected with the positive electrode of the storage battery is a positive electrode ignition clamp, the ignition clamp connected with the negative electrode of the storage battery is a negative electrode ignition clamp, the first ignition clamp 11 and the second ignition clamp 12 are connected with the positive electrode and the negative electrode of the starting power supply, and ignition is started. Therefore, the polarity of the ignition clamp in the embodiment of the application is automatically determined according to the polarity of the storage battery connected with the two ignition clamps, whether the polarity of the storage battery corresponds to that of the ignition clamp or not does not need to be confirmed in advance, and the starting of an automobile is not influenced.

In the embodiment of the application, intelligence ignition clamp includes power incoming end, two ignition clips, main control unit, clip polarity detection module and clip switch-on module, wherein, clip polarity detection module and clip switch-on module are connected to main control unit, two ignition clips are still connected to clip polarity detection module and clip switch-on module, when two ignition clips are connected with the storage battery, clip polarity detection module detects the polarity of the storage battery that two ignition clips are connected respectively, main control unit acquires clip polarity detection module's testing result signal, and the polarity of confirming two ignition clips is corresponded according to the polarity of storage battery according to testing result signal control clip switch-on module, and switch-on starting power supply to the route of two ignition clips and storage battery. Because the polarity of two ignition clips is according to the polarity automatic determination of storage battery, consequently need not to confirm in advance whether the polarity of storage battery and ignition clip corresponds, can realize two ignition clips through above-mentioned intelligence ignition clip according to the polarity and the storage battery intercommunication of storage battery, realize normally igniteing, improved ignition clip's ignition success rate, and because ignition clip has realized the nonpolarity with being connected of storage battery and has been connected, improved ignition clip's life.

Further, with continued reference to fig. 2, the smart ignition clip further comprises: an input polarity detection module 16, an input polarity control module 17 and a voltage stabilization module 18. Specifically, the input polarity detection module 16 is connected to the main controller 13. The input polarity detection module 16 includes two polarity terminals connected to the power input. When the power supply access end is plugged into a socket of a starting power supply, two polarity terminals of the power supply access end are respectively connected with two electrodes of the starting power supply through the power supply access end to generate a level signal, the main controller 13 acquires the level signal through the input polarity detection module 16, and judges the polarity of the starting power supply respectively connected with the two polarity terminals according to the level signal, so that the polarities of the two polarity terminals are determined.

The input polarity control module 17 is connected with the input polarity detection module 16 and the voltage stabilizing module 18, and the voltage stabilizing module 18 is connected with the main controller 11;

the input polarity control module 17 is configured to rectify the power supply signal input by the input polarity detection module 16 and send the power supply signal to the voltage stabilization module 18, and the voltage stabilization module 18 is configured to perform voltage stabilization processing on the rectified power supply signal and send the power supply signal to the main controller 13 to supply power to the main controller 13.

In a specific embodiment, the input polarity control module 17 may include two sets of diodes, each set includes two diodes, each of the two polarity terminals is connected to one set of diodes, and the two diodes in each set are connected end to end, that is, the negative electrode is connected to the positive electrode, so that no matter whether the polarity of the start power supply connected to the polarity terminal is the positive electrode or the negative electrode, the input power supply can be input to the voltage stabilizing module 18 through the rectification of the input polarity control module 17, and is not affected by the polarity of the start power supply connected to the polarity terminal, and the two polarity terminals at the power supply connection end of the input polarity detection module 16 can be connected to the start power supply arbitrarily without dividing the positive electrode and the negative electrode, and does not affect the power supply to the main controller 13.

Therefore, based on the above embodiment, the embodiment of the present invention further provides an intelligent ignition clip, in which the two conductive terminals in the power access end are not separated into positive and negative electrodes.

It can be understood that the conductive terminal without dividing the positive and negative electrodes provided in the embodiment of the present invention may be implemented in combination with the ignition clip without dividing the positive and negative electrodes provided in the above embodiment.

Specifically, the clip closing module 15 includes a plurality of switch control modules and a plurality of switches. In this embodiment, the switch is a relay switch, and the switch control module is a relay control module. In other embodiments, the switch may also be a MOS transistor or the like. The clip closing module 15 includes a plurality of relay control modules 151 and a plurality of relay switches 152. The plurality of relay control modules 151 are respectively connected with different pins of the main controller 13 in a one-to-one correspondence manner, and are respectively connected with the plurality of relay switches 152 in a one-to-one correspondence manner, and the plurality of relay switches 152 are respectively connected with the first ignition clamp 11 and the second ignition clamp 12;

the main controller 13 is used for the polarity of the starting power supply that two polarity terminals that detect according to input polarity detection module 16 connect respectively, and, the polarity of this storage battery that these two ignition clips that clip polarity detection module 14 detected connect respectively, control switching on of a plurality of relay control modules 151 to a plurality of relay switches 152, in order to switch on the route of these two polarity terminals and storage battery according to the polarity correspondence, two polarity terminals in the input polarity detection module confirm the polarity according to the polarity of the starting power supply who inserts promptly, these two ignition clips confirm the polarity according to the polarity of this storage battery, link to each other according to the positive pole, the principle that the negative pole links to each other, link to each other the route between two polarity terminals and two ignition clips, and then be connected with the storage battery.

Further, the intelligent ignition clamp further comprises a plurality of relay detection modules 19 for detecting whether the relay switches 152 are stuck. The sticking of the relay switch refers to the out-of-control of the relay switch, and the switch state can not be normally switched along with the sticking of the relay switch when the relay switch is electrified and not electrified, for example, the relay switch state is not changed when the relay switch is not electrified compared with the relay switch state when the relay switch is electrified.

Specifically, each relay detection module 19 includes two diodes, a transistor, and two resistors; the positive electrode of one of the diodes is connected with one pin of the main controller 13 and the collector of one triode, the negative electrode of the diode is connected with the fifth pin of the relay switch to be detected, the base of one triode is respectively connected with one end of two resistors, the other end of one resistor is connected with the negative electrode of the other diode, and the positive electrode of the other diode is connected with the first pin of the relay switch;

when the pin of the main controller 13 detects that the level signal is increased to a high level signal, it is determined that the relay switch connected with the pin correspondingly is adhered.

This intelligence ignition presss from both sides still includes: an alarm module 20 and an indication module 21;

the alarm module 20 is connected with the main controller 13 and the voltage stabilizing module 18, and the alarm module 20 comprises a buzzer and is used for finishing buzzing alarm according to the instruction of the main controller 13;

the indication module 21 is connected to the main controller, and the indication module 21 includes two light emitting diodes with different colors for lighting or extinguishing the light indication according to the instruction of the main controller 13. The light colors of the two light emitting diodes are not limited, and normal and abnormal light emitting diodes can be distinguished.

This intelligence ignition presss from both sides still includes: starting a power supply communication module;

the start power communication module includes: a DATA-1 network, and a resistor R11. The DATA-1 network is connected to one pin of the host controller and to one end of the resistor R11, the other end of the resistor R11 being connected to ground. The starting power supply communication module is used for the system communication connection between the main controller and the starting power supply end, when the starting power supply end has a fault, the fault signal can be transmitted to the main controller through the DATA-1 network, and the main controller outputs an alarm signal to the alarm module to make a corresponding alarm prompt and/or outputs an indication signal to the indication module to prompt an abnormality. Specifically, the fault signal includes that the voltage of the starting power supply is too low, namely is lower than a preset voltage; and/or the temperature of the start-up power supply is too high, i.e. above a predetermined temperature.

Further, referring to fig. 3, fig. 3 is a schematic circuit structure diagram of a structure and connection relationship of a main controller of an intelligent ignition clip, where the main controller includes a chip U4, a 2 nd pin is connected to an input polarity detection module 16, a 3 rd pin and a 4 th pin are respectively connected to a first clip polarity detection module 14 and a second clip polarity detection module 142, a 8 th pin to an 11 th pin are respectively connected to four relay control modules 141, a 12 th pin is connected to a DATA-1 network for starting a power supply communication module, a 16 th pin to a 19 th pin are respectively connected to four relay detection modules 19, a 13 th pin is connected to an alarm module 20, and a 5 th pin and a 7 th pin are respectively connected to two indication modules 21. Further, the 14 th pin of the main controller chip U4 may be connected to a temperature detection module for detecting the main body temperature of the smart ignition clamp. Pin 15 of the chip U4 may be connected to a voltage detection module that detects the input voltage (i.e., the voltage of the start-up power supply) and the ignition live voltage of the smart ignition clamp. The temperature detection module and the voltage detection module may be implemented by using the prior art, and will not be described in detail herein.

Specifically, referring to fig. 4, fig. 4 is a schematic diagram illustrating a structure and a connection of the clip polarity detection module 14, and the clip polarity detection module 14 includes a first clip polarity detection module and a second clip polarity detection module. The first clamp polarity detection module comprises a first optical coupler PC1 and a first resistor R19, and the second clamp polarity detection module comprises a second optical coupler PC2 and a second resistor R20;

the first optical coupler PC1 comprises 1-4 pins, wherein the pins 1-2 are arranged on the side of a PC1-A, the pins 3-4 are arranged on the side of a PC1-B, and the PC1-A and the PC1-B can be connected into a complete first optical coupler PC 1. The second optical coupler PC2 comprises 1-4 pins, wherein the pins 1-2 are arranged on the side of a PC2-A, the pins 3-4 are arranged on the side of a PC2-B, and the PC2-A and the PC2-B can be connected to form a complete second optical coupler PC 2.

A first pin of the first optical coupler PC1 is connected with one end of a first resistor R19. The other end of the first resistor R19 is connected to the first ignition clamp 11. The second pin of the first optocoupler PC1 is connected to the second ignition clamp 12. The third pin of the first optocoupler PC1 is grounded. A fourth pin of the first optocoupler PC1 is connected with a 4 th pin of the main controller, namely a 4 th pin of the main controller chip U4;

a first pin of the second optical coupler PC2 is connected with one end of a second resistor R20. The other end of the second resistor R20 is connected to the second firing clip 12. The second pin of the second optocoupler PC2 is connected to the first ignition clamp 11. And a third pin of the second optical coupler PC2 is grounded. And a fourth pin of the second optical coupler PC2 is connected with a 3 rd pin of the main controller, namely a 3 rd pin of the main controller chip U4.

And identifying the output polarity of the clamp: when the pin 3 of the main controller chip detects that the level signal is pulled down, determining that OUT-1 is connected with the positive electrode of the storage battery; when the 4 pins of the main controller chip detect that the level signal is pulled down, the connection of OUT + -1 with the positive electrode of the battery is confirmed.

Further, referring to fig. 5 and 6, fig. 5 is a schematic circuit structure diagram of the structures and connection relations of the input polarity detection module 16, the clip-on module and the relay detection module of the intelligent ignition clip, fig. 6 is a schematic circuit structure diagram of the structures and connection relations of the input polarity control module 17, the voltage stabilizing module 18 and the alarm module 20 of the intelligent ignition clip, and the input polarity detection module 16 includes a first polarity terminal CE5-1-1, a second polarity terminal CE5-2-1, a third optical coupler PC3 and a third resistor R28. The first polarity terminal CE5-1-1 and the second polarity terminal CE5-2-1 are respectively connected to two conductive terminals of the power input terminal. The input polarity control module 17 includes a first diode D3, a second diode D4, a third diode D1, a fourth diode D5, and a fourth resistor R8. The voltage stabilization module 18 includes a voltage stabilization chip U3.

Specifically, the third optocoupler PC3 comprises 1-4 pins, wherein 1-2 pins are arranged on the PC3-A side, and 3-4 pins are arranged on the PC3-B side. The diode is preferably IN4148 IN type.

A first pin of the third optocoupler PC3 is connected to the first polarity terminal CE5-1-1 and to the anode of the first diode D3 and the cathode of the second diode D4. A second pin of the third optocoupler PC3 is connected to the second polarity terminal CE5-2-1 and to the anode of the third diode D1 and the cathode of the fourth diode D5. The third pin of the third optical coupler PC3 is grounded, and the fourth pin of the third optical coupler PC3 is connected with the 2 nd pin of the main controller, namely the 2 nd pin of the main controller chip U4.

The cathode of the first diode D3 and the cathode of the third diode D1 are connected to the input terminal of the regulator chip U3 through a fourth resistor R8. The output terminal of the regulator chip U3 is connected to the 20 th pin of the main controller, i.e. the 20 th pin of the main controller chip U4.

Input polarity recognition: when the starting power supply is connected to the power supply access end, if the second pin of the main controller detects that the level signal is a low level signal, the first polarity terminal CE5-1-1 is connected to the positive electrode of the starting power supply, and the second polarity terminal CE5-2-1 is connected to the negative electrode of the starting power supply; if the second pin of the main controller detects that the level signal is a high level signal, the first polarity terminal CE5-1-1 is connected to the negative electrode of the power supply, and the second polarity terminal CE5-2-1 is connected to the positive electrode of the starting power supply.

Two polarity terminals in the EC5 power supply access end do not distinguish positive and negative poles, and the input polarity detection module can automatically identify the polarity of the starting power supply respectively connected with the two polarity terminals, so that the positive and negative poles do not need to be distinguished when the starting power supply is inserted into the power supply access end, misoperation is prevented, and the power supply success rate is improved.

The positions of the first diode D3 and the second diode D4 in the input polarity control module, which are connected with the first polarity terminal CE5-1-1, are opposite in polarity, and the positions of the third diode D1 and the fourth diode D5, which are connected with the first polarity terminal CE5-2-1, are opposite in polarity, so that the power supply signals output by the CE5-1-1 and the CE5-2-1 can be always input into the voltage stabilizing module through the four diodes for voltage stabilization, and stable power supply of the main controller is realized.

Further, the clamp switch-on module comprises four RELAY control modules and four RELAY switches, and the four RELAY control modules comprise a first RELAY control module, a second RELAY control module, a third RELAY control module and a fourth RELAY control module, which are respectively connected with the four RELAY switches and respectively connected with 8-11 pins of U4, namely RELAY 1-4 in the figure. The four relay switches comprise a first relay switch RK3, a second relay switch RK1, a third relay switch RK2 and a fourth relay switch RK4, and each relay switch is provided with 5 pins such as 1-5 pins shown in figure 5.

Each relay control module comprises two relay control submodules, each relay control submodule comprises at least one resistor and a triode, one end of each resistor is connected with one pin of the main controller, and the other end of each resistor is connected with the base of the triode. The collector of the triode is connected with one pin of the relay switch.

Specifically, as shown in fig. 5, the first relay control module includes a first relay control sub-module and a second relay control sub-module. The first relay control submodule includes at least: the resistor R6 and the transistor Q1 further comprise resistors R7 and R51, a capacitor C18 and a transistor Q23. One end of the resistor R6 is connected with the pin 8 of the U4 of the main controller, and the other end is connected with the base electrode of the triode Q1. The collector of the transistor Q1 is connected to the fourth pin of the first relay switch RK3, i.e., pin 4 of RK3 in fig. 5. The second relay control sub-module includes at least: the resistor R48 and the transistor Q21 further comprise resistors R49 and R50, a capacitor C17 and a transistor Q22. One end of the resistor R48 is connected with the pin 8 of the U4 of the main controller, and the other end is connected with the base electrode of the triode Q21. The collector of the transistor Q21 is connected to the third pin of the first relay switch RK3, i.e., pin 3 of RK3 in fig. 5.

The structures and connections of the second relay control module, the third relay control module and the fourth relay control module are similar to those of the first relay control module, and the specific structures and connection modes are based on those shown in fig. 5, which is not described herein again.

Further, the first ignition clamp 11 is connected to the first pin of the second relay switch RK1 (i.e., pin 1 of RK 1) and the first pin of the third relay switch RK2 (i.e., pin 1 of RK 2). The second ignition clamp 12 connects the first leg of the first relay switch RK3 (i.e. 1 pin of RK 3) and the first leg of the fourth relay switch RK4 (i.e. 1 pin of RK 4).

The main controller controls the four relay control modules to control the four relay switches to be opened and closed according to the detection results of the input polarity detection module and the clamp polarity detection module, so that the polarity of a starting power supply inserted into the power supply access end and the polarity of a storage battery connected with the two ignition clamps are connected, and the two polarity terminals and the two ignition clamps are respectively communicated and connected with the storage battery according to the principle that the same polarity ends are connected.

Specifically, the first case: when the pin 2 of the main controller chip U4 detects a low level signal, the pin 3 detects a low level signal, and the pin 4 detects a high level signal, according to the method for judging the connection polarity of the polarity terminal and the starting power supply, it can be known that the first polarity terminal CE5-1-1 is connected with the anode of the starting power supply, and the second ignition clip OUT-1 is connected with the anode of the battery, the main controller chip controls the second relay control module and the fourth relay control module to respectively close the relay switches RK1 and RK4, so that the CE5-1-1 is communicated with the OUT-1, and the CE5-2-1 is communicated with the OUT + -1.

In the second case: when the pin 2 of the main controller chip U4 detects a low level signal, the pin 3 detects a high level signal, and the pin 4 detects a low level signal, according to the connection polarity determination method of the polarity terminal and the starting power supply, it can be known that the first polarity terminal CE5-1-1 is connected with the anode of the starting power supply, and the first ignition clip OUT + -1 is connected with the anode of the battery, the main controller chip controls the first relay control module and the third relay control module to respectively close the relay switches RK3 and RK2, so that the CE5-1-1 is communicated with the OUT + -1, and the CE5-2-1 is communicated with the OUT-1.

In the third case: when 2 feet of the main control chip U4 detect a low level signal, 3 feet detect a high level signal, 4 feet detect a high level signal, and the clamp is not connected with the storage battery or the ignition clamp is in fault or the storage battery is in fault, the main control chip does not turn on any relay switch and does not conduct a starting power supply and the storage battery.

In a fourth case: when the pin 2 of the main controller chip U4 detects a high level signal, the pin 3 detects a low level signal, and the pin 4 detects a high level signal, according to the method for judging the connection polarity of the polarity terminal and the starting power supply, it can be known that the second polarity terminal CE5-2-1 is connected with the anode of the starting power supply, and the second ignition clip OUT-1 is connected with the anode of the battery, the main controller chip controls the first relay control module and the third relay control module to respectively close the relay switches RK3 and RK2, so that the CE5-2-1 is communicated with the OUT-1, and the CE5-1-1 is communicated with the OUT + -1.

In the fifth case: when the pin 2 of the main controller chip U4 detects a high level signal, the pin 3 detects a high level signal, and the pin 4 detects a low level signal, according to the connection polarity determination method of the polarity terminal and the starting power supply, it can be known that the second polarity terminal CE5-2-1 is connected with the anode of the starting power supply, the first ignition clip OUT + -1 is connected with the anode of the battery, the main controller chip controls the second relay control module and the fourth relay control module to respectively close the relay switches RK1 and RK4, so that the CE5-2-1 is communicated with the OUT + -1, and the CE5-2-1 is communicated with the OUT-1.

In the sixth case: when 2 feet of the main control chip U4 detect a high level signal, 3 feet detect the high level signal, 4 feet detect the high level signal, and the clamp is not connected with the storage battery or the ignition clamp is in fault or the storage battery is in fault, the main control chip does not turn on any relay switch, and the starting power supply and the storage battery are not conducted.

Furthermore, the first relay control submodule and the second relay control submodule simultaneously form two magnetic field polarity switching modules.

Further, the intelligent ignition clamp also comprises four relay detection modules which are connected with 16-19 pins of a main controller chip U4, namely a P1-P4 network in figure 5, and are used for detecting whether the four relay switches are adhered or not.

Each relay detection module comprises two diodes, a triode and two resistors, wherein the positive electrode of one diode is connected with one pin of the main controller and the collector electrode of one triode, the negative electrode of one diode is connected with the fifth pin of the relay switch to be detected, and the base electrode of one triode is connected with one end of each resistor. The other end of one resistor is connected with the cathode of the other diode. The anode of the other diode is connected with the first pin of the relay switch. The four relay detection modules include: diodes D10-D17, triodes Q5-Q8, and resistors R9 and R21-R27.

Specifically, the first relay detection module includes: the relay switch comprises diodes D13 and D17, a triode Q8 and resistors R26 and R27, wherein the cathode of the diode D13 is connected with the fifth pin (namely the 5 pin of PK 3) of the first relay switch PK3, the anode of the diode D13 is connected with the collector of the triode Q8, and the base of the triode Q8 is connected with one ends of the resistors R26 and R27. The other end of the resistor R26 is connected with the cathode of the diode D17, and the other end of the resistor R27 is grounded. The anode of the diode D17 is connected to the first pin of the first relay switch PK3 (i.e., pin 1 of PK 3).

The second relay detection module includes: the diodes D12 and D16, the triode Q7, and the resistors R24 and R25 are connected in the same manner as the first relay detection module, based on the connection relationship shown in fig. 5, and are not described again.

The third relay detection module includes: the diodes D10 and D15, the triode Q5, and the resistors R9 and R21 are connected in the same manner as the first relay detection module, based on the connection relationship shown in fig. 5, and are not described again.

The fourth relay detection module includes: the diodes D11 and D14, the triode Q6, and the resistors R22 and R23 are connected in the same manner as the first relay detection module, based on the connection relationship shown in fig. 5, and are not described again.

If 4 pins respectively connected with the four relay detection modules by the main controller detect that the level signal is increased to be a high level signal, the relay switch correspondingly connected with the pins is determined to be adhered.

Taking the first relay detection module and the first relay switch RK3 as an example, the second pin (i.e., pin 2 of RK3 in fig. 5) and the fifth pin (pin 5 of RK 3) are turned on when the first relay switch RK3 is not powered. However, if the second pin (i.e. pin 2 of RK 3) of RK3 and the first pin (i.e. pin 1 of RK 3) are connected, the first relay switch RK3 is not sprung open, i.e. the connection between the first relay switch RK3 and the fifth pin is not disconnected, it is determined that the first relay switch PK3 is stuck.

Further, in fig. 5, an alarm module 20 is connected to the main controller and the voltage regulator module 19. The alarm module 20 comprises a buzzer BZ, a pin 13 connected with a main controller chip U4, and is used for completing the buzzer alarm according to the instruction of the main controller.

Further, referring to fig. 7, fig. 7 is a schematic diagram of a circuit structure of the configuration and connection relationship of the indicating module of the intelligent ignition clamp. The indicating module is connected with the 5 pin and the 7 pin of the main controller chip U4. The indicating module comprises two light emitting diodes (LED 1 and LED 6) with different colors, and is used for lighting up or off according to an instruction of the main controller to finish light indication. One of the light emitting diodes is turned on to indicate a fault, and the other light emitting diode is turned on to indicate that the circuit connection is normal.

In the embodiment of the application, the intelligent ignition clamp comprises a power supply access end, two ignition clamps, a main controller, an input polarity detection module, an input polarity control module, a clamp polarity detection module and a clamp connection module. The main controller is connected with the input polarity detection module, the clamp polarity detection module and the clamp connection module, and the input polarity detection module and the input polarity control module can be connected into the starting power supply to supply power normally for the main controller without distinguishing polarities. The clamp polarity detection module and the clamp connection module are also connected with two ignition clamps. When two ignition clips are connected with the storage battery, the clip polarity detection module detects the polarity of the storage battery respectively connected with the two ignition clips, the main controller acquires a detection result signal of the clip polarity detection module, controls the clip switch-on module to correspond to the polarity of the two ignition clips according to the polarity of the storage battery according to the detection result signal, and switches on the starting power supply and the storage battery. Because the polarity of the two ignition clamps is automatically determined according to the polarity of the battery, whether the polarity of the battery and the polarity of the ignition clamps correspond or not does not need to be confirmed in advance. Through above-mentioned intelligence ignition clamp can realize that two ignition clamps communicate with the storage battery according to the polarity of storage battery, realize normally igniteing, have improved ignition clamp's ignition success rate. And because the input and output of the power supply are realized without distinguishing the positive electrode and the negative electrode of the power supply, the problem of non-polar connection of input and output is solved, the whole ignition process is safely and effectively detected and controlled, and the service life of the ignition clamp is prolonged.

Referring to fig. 8, fig. 8 is a flowchart of a start-up ignition control method provided in an embodiment of the present invention, the intelligent ignition method is applied to the intelligent ignition clamp described above, the intelligent ignition clamp includes a power supply input terminal and two ignition clamps, and further includes a main controller, a clamp polarity detection module, and a clamp connection module, where the main controller connects the clamp polarity detection module and the clamp connection module, and the clamp polarity detection module and the clamp connection module also connect the two ignition clamps, respectively.

As shown in fig. 8, the execution subject of the intelligent ignition method is a main control module, and the method can be implemented by executing a specific computer program through a main control chip inside the main control module, and the method can include the following steps:

s801, when the two ignition clamps are connected with a storage battery, detecting the polarity of the storage battery respectively connected with the two ignition clamps through a clamp polarity detection module;

s802, obtaining a detection result signal of the clamp polarity detection module;

and S803, controlling the clamp connection module to correspondingly determine the polarities of the two ignition clamps according to the polarity of the storage battery according to the detection result signal, and connecting the power supply access end and the paths of the two ignition clamps so as to connect the storage battery.

For the technical details of the above steps, reference is made to the related description of the foregoing embodiments, and details are not repeated here.

In the embodiment of the application, utilize the ignition of intelligence ignition clamp, when two ignition clamps are connected with the storage battery, clamp polarity detection module detects the polarity of the storage battery that two ignition clamps are connected respectively, and main control unit acquires the testing result signal of clamp polarity detection module to according to the polarity correspondence of testing result signal control clamp switch-on module according to the storage battery and confirm the polarity of two ignition clamps, and switch-on starting power supply to the route of two ignition clamps and storage batteries. Because the polarity of two ignition clips is according to the polarity automatic determination of storage battery, consequently need not to confirm in advance whether the polarity of storage battery and ignition clip corresponds, can realize two ignition clips through above-mentioned intelligence ignition clip according to the polarity and the storage battery intercommunication of storage battery, realize normally igniteing, improved ignition clip's ignition success rate, and because ignition clip has realized the nonpolarity with being connected of storage battery and has been connected, improved ignition clip's life.

Embodiments of the present invention further provide a starting apparatus, including a starting power supply and the above-mentioned smart ignition clamp connected to the starting power supply, where the starting power supply is preferably a portable (handheld) power supply.

Fig. 9 is a perspective view illustrating an actuating device according to an embodiment of the present invention. The starting device includes a starting power supply 50 and a smart ignition clip 60. The startup power supply 50 has an output port 52.

The smart ignition clip 60 has a body 62, a power inlet 64 connected to the body 62, a first ignition clip 66 and a second ignition clip 67. The power inlet 64 of the smart ignition clip 60 can be plugged into and electrically connected to the output port 52 of the start-up power supply 50. Specifically, the power supply access end and the output port are a first connector and a second connector which are matched.

Referring to fig. 10 and 11, the power inlet 64 of the smart ignition clip 60 is configured as a plug, and includes a first base 641, and the first base 641 forms an insertion portion 642. In this embodiment, two insertion portions 642 are provided, and the two insertion portions 642 are provided at an interval. The insertion portions 642 are cylindrical, a first insertion hole 644 is formed in each insertion portion 642, and a conductive terminal 646 is disposed on an inner wall of each first insertion hole 644, in this embodiment, the conductive terminal 646 is annular. Correspondingly, the output port 52 of the starting power supply 50 is configured as a socket, and includes a second base 542, a second insertion hole 544 is formed in the second base 542, and two power terminals 546 are disposed in the second insertion hole 544. In this embodiment, two second insertion holes 544 are provided at intervals, and the power terminals 546 are cylindrical. One of the two power supply terminals 546 is a positive terminal, and the other is a negative terminal.

When plugging, the two insertion portions 642 of the first base 641 of the power receiving end 64 are respectively inserted into the second insertion holes 544 of the output port 52, and the two power terminals 546 of the output port 52 are respectively inserted into the two first insertion holes 644 of the power receiving end 64 and are respectively in contact with the conductive terminals 646 in the two first insertion holes 644 to form electrical connection. Preferably, the insertion end 642 of the power inlet 64 is at least partially form-fitted with the second receptacle 544 so as to be adapted to be inserted into the second receptacle 544.

As shown in the figure, the periphery of the power input end 64 of the intelligent ignition clamp 60 of the present invention is a symmetric structure, and correspondingly, the inner side of the output port 52 of the starting power supply 50 is also a symmetric structure, so that the power input end 64 of the intelligent ignition clamp 60 can be inserted into the output port 52 of the starting power supply 50 along both the forward direction (the first direction) and the reverse direction (the second direction), and the two conductive terminals 646 of the intelligent ignition clamp 60 and the two power terminals 546 of the starting power supply 50 are electrically connected. That is, the power inlet 64 of the smart ignition clip 60 can be inserted into the output port 52 of the starting power supply 50 in the direction shown in the figure, or can be inserted into the output port 52 of the starting power supply 50 in the opposite direction (i.e., the power inlet 64 of the smart ignition clip 60 is turned 180 degrees in the direction shown in the figure). In other words, the insertion direction of the power inlet 64 of the smart ignition clip 60 is not differentiated, and the two conductive terminals have no polarity, and either conductive terminal can be connected to the positive terminal of the starting power supply 50 or the negative terminal of the starting power supply 50.

In this embodiment, the two insertion portions 642 of the power inlet 64 of the smart ignition clamp 60 are disposed at an interval, but in other embodiments, the two insertion portions may also be connected into a whole, that is, an integral insertion portion, in which two first insertion holes disposed at an interval are formed. Accordingly, the second insertion holes of the output port 52 of the starting power supply 50 are provided as one for the insertion portion of the power supply inlet 64 to be inserted. Two power terminals are spaced apart in the single second receptacle. When the insertion portion of the smart ignition clip 60 is inserted into the second receptacle of the starting power supply 50, the two power terminals are inserted into the two first receptacles, respectively, and are in contact with the corresponding conductive terminals to form an electrical connection.

In this embodiment, the number of the power terminals 546 of the output port 52 of the starting power supply 50 is two, and the number of the conductive terminals of the power supply inlet 64 of the smart ignition clamp 60 is also two. In other embodiments, the starting power supply may further include a first signal terminal, and correspondingly, the smart ignition clip may further include a second signal terminal, and the two signal terminals may be connected to transmit a signal, for example, a fault signal of the starting power supply described in the above embodiments.

In the present embodiment, the connector of the power inlet 64 of the smart ignition clamp 50 is configured as a male socket, and the connector of the output port 52 of the starting power supply 50 is configured as a female socket, but in other embodiments, the connector of the power inlet of the smart ignition clamp may be configured as a female socket, and accordingly, the connector of the output port of the starting power supply is configured as a male socket.

The first connector of the intelligent ignition clamp provided by the embodiment of the invention can be in plug connection with the second connector of the starting power supply along two directions, a foolproof design is not needed, and the plug connection is more convenient and rapid.

Referring also to fig. 12, the first ignition clips 66 and 67 of the smart ignition clip 60 have the same shape and configuration. The first ignition clip 66 will be described below as an example.

The first ignition clamp 66 is in the form of a clamp including a gripping portion 662 at a rear end and a gripping portion 664 at a front end. The two clamping parts 664 can be driven to be opened and closed relatively by operating the holding part 662, so that the holding part can be clamped on an automobile battery. The inner surfaces of the two holding portions 664 facing each other are provided with teeth 666, and the teeth 666 extend in the longitudinal direction of the holding portion 624 and have saw-toothed tips. The tooth 666 is provided to facilitate the ignition clip 66 to be securely connected to the vehicle battery to prevent the connection from being broken due to the release caused by vibration. In this embodiment, two sets of teeth 666 are disposed in parallel in the first ignition clip 66, and the two sets of teeth 666 are spaced apart and spaced apart by a first distance. Each set of teeth 666 includes two parallel rows of teeth 666. The two rows 666 of teeth in each set are adjacently disposed and spaced apart a second distance therebetween that is less than the first distance. In this embodiment, each set of teeth 666 includes two rows of teeth 666, that is, 4 rows of teeth 666 are provided inside each clamping portion 664, and the 4 rows of teeth 666 of the two clamping portions 664 are aligned up and down, so that the clamping stability of the ignition clip 66 can be improved, and the reliability of the smart ignition clip 60 can be enhanced.

The shape and construction of the second ignition clip 67 is described above with reference to the first ignition clip and will not be described further herein.

It is to be understood that the first and second ignition clips 66, 67 of the present embodiment can be used as the first and second ignition clips 11, 67 of any of the above embodiments.

Referring to fig. 13, the body 62 of the smart ignition clip 60 includes a housing 622 and a control 624 disposed within the housing 622. The control device 624 includes the main controller 13, the input polarity detection module 16, the input polarity control module 17, and the voltage regulator module 18 in the above embodiments.

In some embodiments, the power inlet 64 of the smart ignition clip 60 according to this embodiment that does not distinguish the insertion direction may be implemented in combination with the ignition clips of the above embodiments that do not distinguish the positive and negative poles. In that case, the control device 624 further includes the clip polarity detection module 14 and the clip closing module 15 described above. The specific structure and operation principle of the present invention can refer to the related description of the above embodiments, and thus are not described in detail herein.

In the above embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments.

In view of the above description of the intelligent ignition clip, the intelligent ignition method and the starting device provided by the present invention, those skilled in the art will recognize that there may be variations in the embodiments and applications of the concepts according to the embodiments of the present invention.

Claims (12)

1. The utility model provides an intelligence ignition presss from both sides, includes power incoming end and two ignition clips, power incoming end is used for an external start power supply, two ignition clips are used for being connected with the storage battery of a load, its characterized in that still includes:

the clamp polarity detection module is connected with the clamp connection module;

the main controller is connected with the clamp polarity detection module and the clamp connection module, and the clamp polarity detection module and the clamp connection module are also connected with the two ignition clamps;

two ignition clips with when the storage battery is connected, clip polarity detection module is used for detecting two ignition clips are connected respectively the polarity of storage battery, main control unit is used for acquireing clip polarity detection module's testing result signal, and according to testing result signal control clip switch-on module follows the polarity of storage battery corresponds the affirmation two polarity of ignition clips, and switch-on the power incoming end with the route of two ignition clips, thereby the switch-on the storage battery.

2. The smart ignition clip of claim 1, wherein the clip polarity detection module comprises: the clamp polarity detection device comprises a first clamp polarity detection module and a second clamp polarity detection module;

the first clamp polarity detection module and the second clamp polarity detection module are both connected with the main controller and respectively connected with a first ignition clamp and a second ignition clamp in the two ignition clamps;

the main control unit is still used for passing through when first clip polarity detection module detects level signal and is drawn down for low level signal, confirms second ignition clip is connected the positive pole of storage battery, and, still be used for passing through when second clip polarity detection module detects level signal and is drawn down for low level signal, confirms first ignition clip is connected the positive pole of storage battery.

3. The intelligent ignition clamp of claim 2, wherein the main controller is further configured to confirm that the battery is not connected to the first ignition clamp and the second ignition clamp when the first clamp polarity detection module and the second clamp polarity detection module detect that the level signals are high level signals.

4. The smart ignition clip of claim 3, wherein the first clip polarity detection module comprises a first optocoupler and a first resistor, and the second clip polarity detection module comprises a second optocoupler and a second resistor;

a first pin of the first optocoupler is connected with one end of the first resistor, the other end of the first resistor is connected with the first ignition clamp, a second pin of the first optocoupler is connected with the second ignition clamp, a third pin of the first optocoupler is grounded, and a fourth pin of the first optocoupler is connected with the first pin of the main controller;

the first pin of second opto-coupler is connected the one end of second resistance, the other end of second resistance is connected the second ignition clip, the second pin of second opto-coupler is connected first ignition clip, the third pin ground connection of second opto-coupler, the fourth pin of second opto-coupler is connected the second pin of main control unit.

5. The smart ignition clip of claim 1, further comprising: the input polarity detection module is connected with the power supply access end and the main controller;

the input polarity detection module comprises two polarity terminals connected with the power supply access end, when a starting power supply is accessed to the power supply access end, the two polarity terminals are electrically connected to generate a level signal, and the main controller acquires the level signal through the input polarity detection module and judges the polarities of the starting power supply respectively connected with the two polarity terminals according to the level signal.

6. The smart ignition clip of claim 5, further comprising: inputting a polarity control module and a voltage stabilizing module;

the input polarity control module is connected with the input polarity detection module and the voltage stabilization module, and the voltage stabilization module is connected with the main controller;

the input polarity control module comprises two groups of diodes, each group of diodes comprises two diodes with anodes connected with cathodes, each group of diodes is connected with one of the two polarity terminals in the input polarity detection module and used for rectifying the power supply signal input by the input polarity detection module and sending the power supply signal to the voltage stabilizing module, and the voltage stabilizing module is used for performing voltage stabilizing processing on the rectified power supply signal and then sending the power supply signal to the main controller to supply power to the main controller.

7. The smart ignition clamp of claim 6, wherein the input polarity detection module comprises a third optocoupler and a third resistor, the input polarity control module comprises a first diode, a second diode, a third diode, a fourth diode and a fourth resistor, and the voltage regulation module comprises a voltage regulation chip;

a first pin of the third optocoupler is connected with a first polarity terminal of the two polarity terminals, and is connected with an anode of the first diode and a cathode of the second diode, a second pin of the third optocoupler is connected with a second polarity terminal of the two polarity terminals, and is connected with an anode of the third diode and a cathode of the fourth diode, a third pin of the third optocoupler is grounded, and a fourth pin of the third optocoupler is connected with a third pin of the master controller;

the cathode of the first diode and the cathode of the third diode are connected to the input end of the voltage stabilizing chip through the fourth resistor, and the output end of the voltage stabilizing chip is connected with a fourth pin of the main controller;

when the starting power supply is connected to the power supply access end, if the third pin of the main controller detects that the level signal is a low level signal, the first polarity terminal is connected to the positive electrode of the starting power supply, and the second polarity terminal is connected to the negative electrode of the starting power supply; if the third pin of the main controller detects that the level signal is a high level signal, the first polarity terminal is connected to the negative electrode of the starting power supply, and the second polarity terminal is connected to the positive electrode of the starting power supply.

8. The smart ignition clip of claim 5 wherein the clip closing module comprises a plurality of switch control modules and a plurality of switches;

the switch control modules are respectively connected with different pins of the main controller in a one-to-one corresponding manner, and are respectively connected with the switches in a one-to-one corresponding manner, and the switches are respectively connected with the first ignition clamp and the second ignition clamp;

the main control unit is used for detecting according to the input polarity detection module two polarity terminals are connected respectively the polarity of the starting power supply, and, the clip polarity detection module detects two ignition clips are connected respectively the polarity of the storage battery controls the switch-on of a plurality of switches control modules to switch on according to polarity correspondence the power supply access end with the passage of the storage battery.

9. The smart ignition clip of claim 5, wherein the clip closing module comprises a plurality of relay control modules and a plurality of relay switches;

the plurality of relay control modules are respectively connected with different pins of the main controller in a one-to-one corresponding manner, and are respectively connected with the plurality of relay switches in a one-to-one corresponding manner, and the plurality of relay switches are respectively connected with the first ignition clamp and the second ignition clamp;

the main control unit is used for detecting according to the input polarity detection module two polarity terminals are connected respectively the polarity of the starting power supply, and, the clip polarity detection module detects two ignition clips are connected respectively the polarity of the storage battery controls the conduction of the relay switches to switch on the power supply access end and the passage of the storage battery according to polarity correspondence.

10. The smart ignition clip of claim 9, wherein the plurality of relay switches comprises a first relay switch, a second relay switch, a third relay switch, and a fourth relay switch;

each relay control module comprises two relay control submodules, and each relay control submodule comprises at least one resistor and one triode;

one end of the resistor is connected with one pin of the main controller, the other end of the resistor is connected with the base electrode of the triode, and the collector electrode of the triode is connected with one pin of the relay switch;

the first ignition clamp is connected with a first pin of the second relay switch and a first pin of the third relay switch;

the second ignition clip is connected to the first pin of the first relay switch and the first pin of the fourth relay switch.

11. The smart ignition clip of claim 10, further comprising a plurality of relay detection modules for detecting whether the relay switch is stuck;

each relay detection module comprises two diodes, a triode and two resistors;

the anode of one of the diodes is connected with one pin of the main controller and the collector of one triode, the cathode of the one triode is connected with the fifth pin of the relay switch to be detected, the base of the one triode is respectively connected with one end of the two resistors, the other end of one of the resistors is connected with the cathode of the other diode, and the anode of the other diode is connected with the first pin of the relay switch;

and when the pins of the main controller detect that the level signal is increased to a high level signal, determining that the relay switches correspondingly connected with the pins are adhered.

12. An initiator device comprising an initiator power supply and the smart ignition clamp of any one of claims 1 to 11, wherein the initiator power supply comprises an output port, and wherein a power inlet of the smart ignition clamp is pluggable to the output port of the initiator power supply.

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