CN112752006A

CN112752006A - Multifunctional field infrared camera device

Info

Publication number: CN112752006A
Application number: CN202110041190.1A
Authority: CN
Inventors: 陈鹏; 胡绍湘; 王晨阳; 侯蓉; 杨恒毅; 刘鹏; 廖志武; 吴永胜
Original assignee: CHENGDU RESEARCH BASE OF GIANT PANDA BREEDING; University of Electronic Science and Technology of China
Current assignee: CHENGDU RESEARCH BASE OF GIANT PANDA BREEDING; University of Electronic Science and Technology of China
Priority date: 2021-01-13
Filing date: 2021-01-13
Publication date: 2021-05-04

Abstract

The invention discloses a multifunctional field infrared camera device which comprises a shell front cover, a shell rear cover, an outer box bottom cover, a GPS antenna, a WIFI antenna, a radio frequency antenna, a COMS circuit board, a first optical lens, a second optical lens, a main board, a power panel, a front battery jar, a first lithium battery, a second lithium battery, a battery partition board, a first solar cell panel, a second solar cell panel and a third solar cell panel. The camera device provided by the invention has a space for installing the solar panel, the lithium battery and the microstrip antenna, is provided with the independent power panel, and supports the solar panel to assist the lithium battery power supply scheme. The lithium battery can be repeatedly used, so that the camera is more environment-friendly; the easily damaged structures such as a rubber bar antenna and the like arranged outside the camera are avoided, and the structure is stable; the single-time endurance of the camera is longer, and the use cost is lower; wireless communication is supported, and the timeliness of data is improved; the sensor is accommodated by a special structure, and the acquired environmental information is richer.

Description

Multifunctional field infrared camera device

Technical Field

The invention belongs to the technical field of camera devices, and particularly relates to a multifunctional field infrared camera device.

Background

Wild animals are a valuable resource given by nature to humans. In order to better protect wild animals, measure the benefit of a protected area and carry out scientific research related to the wild animals, in the research of wild animal species resources, an infrared camera in a field environment is often used for acquiring videos and images of the animals so as to investigate species resources, provide decision reference and serve the protection of the wild animals.

At present, an infrared camera in the mainstream of the market adopts a five-number dry battery, so that the energy density is low, the endurance time is short, the electric quantity cannot be supplemented in the field, and meanwhile, the infrared camera does not have the high-speed remote communication capability, and is also limited by an infrared trigger mechanism to cause more false triggers and invalid data accumulation, so that frequent maintenance is needed, and finally, the acquired information is single. These shortcomings lead to the camera data being recovered through manual field work, which is difficult to process, has many invalid data and single data type, and is not favorable for the development of subsequent scientific research.

Disclosure of Invention

The invention aims to solve the problem of field shooting and provides a multifunctional field infrared camera device.

The technical scheme of the invention is as follows: a multifunctional field infrared camera device comprises a shell front cover, a shell rear cover, an outer box bottom cover, a GPS antenna, a WIFI antenna, a radio frequency antenna, a COMS circuit board, a first optical lens, a second optical lens, a main board, a power board, a front battery jar, a first lithium battery, a second lithium battery, a battery partition board, a first solar cell panel, a second solar cell panel and a third solar cell panel;

the front cover, the back cover and the bottom cover of the outer box form the camera shell of the infrared camera device; the COMS circuit board, the first optical lens, the second optical lens, the mainboard, the power panel, the front battery jar, the first lithium battery, the second lithium battery and the battery separator are all fixedly installed inside the camera shell, and the mainboard, the power panel, the front battery jar, the first lithium battery pack, the second lithium battery pack and the battery separator are fixedly arranged inside the rear cover of the shell;

the first optical lens and the second optical lens are fixedly arranged on the COMS circuit board; the first lithium battery is fixedly arranged in a gap formed by the front battery jar and the battery separator; the second lithium battery is fixedly arranged in a gap formed by the battery separator and the rear cover of the shell;

a WIFI antenna and a radio frequency antenna are respectively and fixedly arranged on two sides of the front cover of the shell, and a GPS antenna is fixedly arranged on the top of the front cover of the shell; the both sides of lid are fixed respectively behind the shell and are provided with first solar cell panel and third solar cell panel, and its top is fixed and is provided with second solar cell panel.

The invention has the beneficial effects that: the camera device provided by the invention has a space for installing the solar panel, the lithium battery and the microstrip antenna, is provided with the independent power panel, and supports the solar panel to assist the lithium battery power supply scheme. The lithium battery can be repeatedly used, so that the camera is more environment-friendly; the easily damaged structures such as a rubber bar antenna and the like arranged outside the camera are avoided, and the structure is stable; the single-time endurance of the camera is longer, and the use cost is lower; wireless communication is supported, and the timeliness of data is improved; the sensor is accommodated by a special structure, and the acquired environmental information is richer.

Furthermore, the multifunctional field infrared camera device also comprises a first infrared light supplement lamp circuit board, a second infrared light supplement lamp circuit board, a first infrared LED lamp, a second infrared LED lamp, a third infrared LED lamp and a fourth infrared LED lamp;

the first infrared light supplement lamp circuit board and the second infrared light supplement lamp circuit board are respectively and fixedly arranged on two sides of the COMS circuit board, and the COMS circuit board, the first infrared light supplement lamp circuit board and the second infrared light supplement lamp circuit board are all fixedly arranged on the mainboard; the first infrared LED lamp and the second infrared LED lamp are both fixedly arranged on the first infrared light supplement lamp circuit board; and the third infrared LED lamp and the fourth infrared LED lamp are fixedly arranged on the second infrared light supplement lamp circuit board.

The beneficial effects of the further scheme are as follows: in the invention, the COMS circuit board is used for welding the COMS sensor and is connected with the mainboard through the FPC flat cable, so that the intelligent communication between the COMS circuit board and the mainboard is realized; two COMS and corresponding lenses are mounted, and double-shot simultaneous shooting can be selected for three-dimensional reconstruction.

Furthermore, two lens light through holes which are longitudinally arranged are fixedly arranged on the front cover of the shell; a first LED light supplement lamp light-passing hole, a second LED light supplement lamp light-passing hole, a third LED light supplement lamp light-passing hole and a fourth LED light supplement lamp light-passing hole are fixedly formed in two sides of the lens light-passing hole respectively; the two lens light through holes consist of a first outer light shielding plate, a second outer light shielding plate, a first light through hole, a second light through hole, a first inner light shielding plate and a second inner light shielding plate; the first outer light screen, the second outer light screen, the first light through hole and the second light through hole are all fixedly arranged on the outer surface of the front cover of the shell; the first inner shading plate and the second inner shading plate are fixedly arranged on the inner wall of the front cover of the shell; a solar panel and a Fresnel lens group are fixedly arranged below the lens light through hole in sequence; the Fresnel lens group comprises a Fresnel lens mounting table, a first Fresnel lens, a second Fresnel lens and a third Fresnel lens, and the first Fresnel lens, the second Fresnel lens and the third Fresnel lens are all mounted on the Fresnel lens mounting table; a first microphone induction hole and a second microphone induction hole are respectively and fixedly arranged on two sides of the Fresnel lens group; a first sensor mounting shell and a second sensor mounting shell are fixedly arranged at the bottom of the inner wall of the front cover of the shell; the bottom of shell protecgulum outer wall is fixed and is provided with first sensor response hole and second sensor response hole.

Further, first logical unthreaded hole, second logical unthreaded hole, the logical unthreaded hole of first LED light filling lamp, the logical unthreaded hole of second LED light filling lamp, the logical unthreaded hole of third LED light filling lamp and the logical unthreaded hole of fourth LED light filling lamp are covered by high transparent organic glass.

Further, a first CMOS circuit board mounting post, a second CMOS circuit board mounting post, a third CMOS circuit board mounting post, a fourth CMOS circuit board mounting post, a first infrared light supplement lamp circuit board mounting groove, a second infrared light supplement lamp circuit board mounting groove, a third infrared light supplement lamp circuit board mounting groove, a fourth infrared light supplement lamp circuit board mounting groove, a first main board power interface, a second main board power interface, a third main board power interface, a fourth main board power interface and a GPS module are fixedly arranged above the surface of the main board; a core board is fixedly arranged below the GPS module; one side of the core board is fixedly arranged on the gyroscope; a first infrared sensor, a second infrared sensor, an SD card slot and a radio frequency module are fixedly arranged below the core board; the gyroscope, the first infrared sensor, the second infrared sensor, the SD card slot and the radio frequency module are fixedly arranged on the mainboard in a bonding mode; a singlechip, a display interface, a USB interface and a communication module are fixedly arranged below the surface of the mainboard; the single chip microcomputer is in communication connection with the radio frequency module;

the communication module adopts a Wi-Fi routing module or a Wi-Fi module, the Wi-Fi routing module comprises a module main board, a radiating fin and a fixing device, a wired interface and an antenna interface, the radiating fin and the fixing device are fixedly arranged on the front surface of the module main board, the antenna interface is fixedly arranged on one side of the radiating fin and the fixing device, the wired interface is fixedly arranged on the back surface of the module main board, the antenna interface is in communication connection with a Wi-Fi antenna, and the wired interface is fixedly connected with the module main board,

the multifunctional field infrared camera device also comprises a network port chip, a network port transformer and a network cable interface; the network port chip, the network port transformer and the network cable interface are all fixedly arranged on the core board; the core board is in communication connection with the Wi-Fi routing module through the network port chip, the network port transformer and the network cable interface.

The beneficial effects of the further scheme are as follows: in the invention, the mainboard is positioned below the front casing of the camera, so that the CMOS sensor can be conveniently opposite to the light through hole and is connected with the power panel for power supply. The wired interface is fixedly connected with the module main board, so that the structure of the main board needs to be modified, the Wi-Fi module installed on the main board is removed, communication is achieved, when other or trusted equipment can receive Wi-Fi signals of the Wi-Fi routing module, the network can be accessed, working parameters of the camera are configured, and data stored in the camera can be acquired.

Furthermore, the first CMOS circuit board mounting column, the second CMOS circuit board mounting column, the third CMOS circuit board mounting column and the fourth CMOS circuit board mounting column are screw columns;

a first infrared light supplement lamp circuit board mounting groove, a second infrared light supplement lamp circuit board mounting groove, a third infrared light supplement lamp circuit board mounting groove and a fourth infrared light supplement lamp circuit board mounting groove are all 2.54mm sockets;

the core board comprises an SOC chip with neural network acceleration, a memory chip and an external memory chip; the SD card slot is a 9pin minSD card slot; the display interface adopts an FPC connecting line; the USB interface adopts a micro USB female socket;

the surface of the GPS module is provided with a shielding case which is in communication connection with the GPS antenna; the radio frequency module is provided with an IPEX female seat which is in communication connection with the radio frequency antenna; the WIFI module is provided with an IPEX female socket which is in communication connection with the WIFI antenna.

The beneficial effects of the further scheme are as follows: in the invention, the WiFi module, the radio frequency module and the GPS module are independently welded on the PCB, and are fixed on the edge of the mainboard through a 2.54mm pin header interface to realize communication, so as to provide better heat dissipation capability; the SD card slot is a 9pin minisD card slot, so that the projection of the edge of the inserted microsD card is not more than that of the mainboard.

Furthermore, the microcontroller and the solar charging chip are fixedly arranged in the center of the surface of the power panel in a bonding mode, and a first solar battery charging interface, a second solar battery charging interface, a third solar battery charging interface and a fourth solar battery charging interface are fixedly arranged above the surface of the power panel;

a charging chip, a charging interface, a first battery interface and a second battery interface are fixedly arranged on the left side of the surface of the power panel; the charging chip is in communication connection with the charging interface; the charging chip is in one-to-one corresponding communication connection with the first lithium battery and the second lithium battery through the first battery interface and the second battery interface respectively; a first voltage transformation chip, a second voltage transformation chip, a third voltage transformation chip and a fourth voltage transformation chip are fixedly arranged on the left lower side of the surface of the power panel in a sticking welding mode and form a voltage transformation array; and a first power output interface, a second power output interface, a third power output interface and a fourth power output interface are fixedly arranged below the voltage transformation array and are respectively in one-to-one corresponding communication connection with the first voltage transformation chip, the second voltage transformation chip, the third voltage transformation chip and the fourth voltage transformation chip.

The beneficial effects of the further scheme are as follows: in the invention, when the charging interface is externally connected with a 5V power supply, the lithium battery can be charged through the charging chip via the battery interface positioned on the upper left of the front side; the power output interface is connected with the voltage transformation chip and is used for outputting voltages of 1.8V, 3.3V, 5V and 19.2V to the mainboard power interface on the mainboard; the power panel can be led out to lead wires to be connected with the main board so as to improve the heat dissipation capacity and be convenient to disassemble and replace.

Furthermore, the first solar cell charging interface, the second solar cell charging interface, the third solar cell charging interface and the fourth solar cell charging interface are respectively connected with the first solar cell panel, the second solar cell panel, the third solar cell panel and the solar charging chip in a one-to-one correspondence manner;

the first power output interface, the second power output interface, the third power output interface and the fourth power output interface are respectively electrically connected with the first mainboard power interface, the second mainboard power interface, the third mainboard power interface and the fourth mainboard power interface in a one-to-one correspondence manner.

The beneficial effects of the further scheme are as follows: in the invention, the charging interface and the power output interface are used for providing stable power supply for the mainboard.

Further, a touch screen is fixedly arranged on the surface of the outer box bottom cover.

Furthermore, a first battery panel fixing column, a second battery panel fixing column, a third battery panel fixing column and a fourth battery panel fixing column are fixedly arranged on the inner wall of the rear cover of the shell;

preferably, the Wi-Fi routing module can be selectively installed on the device to replace the Wi-Fi module, the Wi-Fi routing module comprises a module main board, a radiating fin, a fixing device, a wired interface and an antenna interface, the radiating fin and the fixing device are positioned on the front surface of the module main board, the antenna interface is also positioned on one side of the radiating fin on the front surface, the wired interface is positioned on the back surface of the module main board, the antenna interface is connected with a Wi-Fi antenna, the wired interface is connected with the main board, the structure of the main board needs to be modified for the purpose, the Wi-Fi module installed on the main board is removed, the core board is connected with the Wi-Fi routing module through a net port chip, a net port transformer and a, when other or trusted devices are able to receive Wi-Fi signals from the Wi-Fi routing module, the network may be accessed to configure camera operating parameters, and may also acquire data stored on the camera.

The inner walls of the two sides of the rear cover of the shell are respectively and fixedly provided with a first main board fixing column, a second main board fixing column, a third main board fixing column, a fourth main board fixing column, a fifth battery panel fixing column and a sixth battery panel fixing column; a rear cover battery jar with salient points is fixedly arranged in the rear cover of the shell; the both sides of back lid battery jar are fixed battery jar fixed column before first, battery jar fixed column before second, battery jar fixed column before the third and battery jar fixed column before the fourth respectively.

The beneficial effects of the further scheme are as follows: in the invention, the battery panel fixing column is used for fixing the power panel; the main board fixing column is used for fixing the main board; a battery storage space surrounded by a rear cover battery jar is arranged at the middle position of the inner side of the rear cover, a protruding part on the rear cover battery jar is used for fixing a battery separator, and a space formed between the battery separator and the rear cover battery jar is used for accommodating a first lithium battery; the front battery jar fixing column is used for fixing the front battery jar; the space formed between the front battery can and the battery separator is used for accommodating the second lithium battery.

Drawings

Fig. 1 is a structural view of a camera apparatus;

FIG. 2 is a partial block diagram of an optional Wi-Fi routing module for a camera device;

FIG. 3 is a front view of the outside of the front cover of the housing;

FIG. 4 is a view of the inside of the front cover of the housing;

FIG. 5 is a structural view of a main board;

FIG. 6 is a block diagram of a motherboard with a Wi-Fi routing module;

FIG. 7 is a block diagram of a power strip;

FIG. 8 is a view of the inside of the rear cover of the housing;

FIG. 9 is a front view of the inside of the rear cover of the housing;

in the figure, 1, a front cover of a shell; 2-1, a first outer visor; 2-2, a second outer visor; 2-3, a first light through hole; 2-4, a second light through hole; 2-5, a first inner visor; 2-6, a second inner visor; 3-1, a light through hole of a first LED light supplement lamp; 3-2, a light through hole of a second LED light supplement lamp; 3-3, a light through hole of a third LED light supplement lamp; 3-4 a fourth LED light supplement lamp light through hole; 4. a solar panel; 5-1, a Fresnel lens mounting table; 5-2, a first Fresnel lens; 5-3, a second Fresnel lens; 5-4, a third Fresnel lens; 6-1, a first microphone induction hole; 6-2 second microphone sensing holes; 6-3, a first sensor mounting shell; 6-4, a second sensor mounting housing; 6-5, a first sensor sensing hole; 6-6 second sensor sensing holes; 7. a GPS antenna; 8. a WI-FI antenna; 9. a radio frequency antenna; 10. a CMOS circuit board; 11-1, a first optical lens; 11-2, a second optical lens; 12-1, a first infrared light supplement lamp circuit board; 12-2, a second infrared light supplement lamp circuit board; 13-1, a first infrared LED lamp; 13-2, a second infrared LED lamp; 13-3, a third infrared LED lamp; 13-4, a fourth infrared LED lamp; 14. a main board; 15-1, a first CMOS circuit board mounting post; 15-2, a second CMOS circuit board mounting post; 15-3, a third CMOS circuit board mounting post; 15-4, a fourth CMOS circuit board mounting post; 16-1, a first infrared light supplement lamp circuit board mounting groove; 16-2, a second infrared light supplement lamp circuit board mounting groove; 16-3, a third infrared light supplement lamp circuit board mounting groove; 16-4, a third infrared light supplement lamp circuit board mounting groove; 17-1, a first motherboard power interface; 17-2, a second motherboard power interface; 17-3, a third motherboard power interface; 17-4, a fourth motherboard power interface; 18. a GPS module; 19. a core board; 20. a gyroscope; 21. a single chip microcomputer; 22. an SD card slot; 23-1, a first infrared sensor; 23-2, a second infrared sensor; 24. a display interface; 25. a USB interface; 26-1, a radio frequency module; 26-2 network port chips; 26-3 network port transformers; 26-4 network cable interfaces; 27. a communication module; 28. a power panel; 29. a microcontroller; 30. a solar charging chip; 31-1, a first solar cell charging interface; 32-2, a second solar cell charging interface; 32-3, a third solar cell charging interface; 32-4, a fourth solar cell charging interface; 32-1, a first transformer chip; 32-2, a second transformer chip; 32-3, a third transformer chip; 32-4, a fourth transformer chip; 33-1, a first power output interface; 33-2, a second power output interface; 33-3, a third power output interface; 33-4 a fourth power output interface; 34. a charging chip; 35. a charging interface; 36-1, a first battery interface; 36-2, a second battery interface; 37. a front battery well; 38-1, a first lithium battery; 38-2, a second lithium battery; 39 a battery separator; 40-1, a first solar panel; 40-2, a second solar panel; 40-3, a third solar panel; 41. a housing rear cover; 42. a rear cover battery jar; 43-1, a first main board fixing column; 43-2, a second main board fixing column; 43-3, a third main board fixing column; 43-4, a fourth main board fixing column; 43-5, a fifth main board fixing column; 43-6 and a sixth main board fixing column; 44-1, a first front battery jar fixing post; 44-2, a second front battery jar fixing post; 44-3, a third front battery jar fixing post; 44-4, a fourth front battery jar fixing post; 45-1, a first battery panel fixing column; 45-2, a second battery panel fixing column; 45-3, third battery panel fixing columns; 45-4, a fourth battery panel fixing column; 46. an outer box bottom cover; 47. a touch screen; 48. a module main board; 49. a heat sink and a fixing device; 50-1, a wired interface; 50-2 antenna interface.

Detailed Description

The embodiments of the present invention will be further described with reference to the accompanying drawings.

In this apparatus, the normal direction of the camera front cover toward the outside of the camera is defined as the + X direction, which is referred to as the forward direction, and the opposite direction is defined as the-X direction, which is referred to as the backward direction, by using the XYZ rectangular coordinate system, and the + X direction and the-X direction are collectively referred to as the X direction. The Z direction is the normal direction of the bottom cover, the inward direction is taken as the + Z direction and is called as the upward direction, and the reverse direction is taken as the-Z direction and is called as the downward direction. The Y direction is a normal direction of a plane formed by the X direction and the Z direction.

The light through hole is covered by high transparent organic glass, and the center of the light through hole is positioned on a symmetrical axis in the Z direction on the front surface of the shell; a first LED light supplement lamp light through hole 3-1 and a second LED light supplement lamp light through hole are in a group, a third LED light supplement lamp light through hole 3-3 and a fourth LED light supplement lamp light through hole 3-4 are in a group, and are arranged along the Z axis; the microphone is fixed at the position where the first sensor induction hole 6-5 and the second sensor induction hole 6-6 are tightly attached to the shell along the-X direction; the main board 14 is the front surface of the main board 14 in the + X direction, and the first infrared sensor 23-1 and the first infrared sensor are arranged along the Z axis.

After the components are installed, the infrared sensor on the main board 14, the first optical lens 11-1, the second optical lens 11-2, the infrared LED lamp and the camera shell which are fixed on the main board 14 have the following position relations: the first optical lens 11-1 fixed on the main board 14 is over against the center of the first light through hole 2-3 along the X direction, the second optical lens 11-2 is over against the center of the second light through hole 2-4 along the X direction, the infrared LED lamp is over against the light through hole of the LED light supplement lamp along the X direction, the two infrared sensors on the main board 14, the center of the upper infrared sensor is over against the Fresnel lens on the front shell along the X direction, and the infrared sensor on the lower side is positioned at the normal intersection point of the circle centers of the two Fresnel lenses on the Fresnel lens mounting table 5-1. When the power supply board 28 is mounted, one surface facing the + X direction is a front surface, and transformer chips are attached to the left side of the front surface of the power supply board 28, and these chips are arranged along the Y direction.

As shown in fig. 1, the invention provides a multifunctional field infrared camera device, which comprises a shell front cover 1, a shell rear cover 41, a shell bottom cover 46, a GPS antenna 7, a WIFI antenna 8, a radio frequency antenna 9, a cmos circuit board 10, a first optical lens 11-1, a second optical lens 11-2, a main board 14, a power board 28, a front battery jar 37, a first lithium battery 38-1, a second lithium battery 38-2, a battery partition 39, a first solar panel 40-1, a second solar panel 40-2 and a third solar panel 40-3;

the front case cover 1, the rear case cover 41 and the outer case bottom cover 46 constitute a camera case of the infrared camera device; the COMS circuit board 10, the first optical lens 11-1, the second optical lens 11-2, the mainboard 14, the power panel 28, the front battery jar 37, the first lithium battery 38-1, the second lithium battery 38-2 and the battery separator 39 are all fixedly arranged inside the camera shell, and the mainboard 14, the power panel 28, the front battery jar 37, the first lithium battery pack 38-1, the second lithium battery pack 38-2 and the battery separator 39 are fixedly arranged inside the shell rear cover 41;

the first optical lens 11-1 and the second optical lens 11-2 are both fixedly arranged on the COMS circuit board 10; the first lithium battery 38-1 is fixedly disposed in the gap formed by the front battery case 37 and the battery separator 39; the second lithium battery 38-2 is fixedly disposed in a gap formed by the battery separator 39 and the case back cover 41;

a WIFI antenna 8 and a radio frequency antenna 9 are respectively and fixedly arranged on two sides of the shell front cover 1, and a GPS antenna 7 is fixedly arranged on the top of the shell front cover; the two sides of the shell rear cover 41 are respectively fixedly provided with a first solar cell panel 40-1 and a third solar cell panel 40-3, and the top of the shell rear cover is fixedly provided with a second solar cell panel 40-2.

In the embodiment of the invention, as shown in fig. 1, the multifunctional field infrared camera device further comprises a first infrared light supplement lamp circuit board 12-1, a second infrared light supplement lamp circuit board 12-2, a first infrared LED lamp 13-1, a second infrared LED lamp 13-2, a third infrared LED lamp 13-3 and a fourth infrared LED lamp 13-4;

the first infrared light supplement lamp circuit board 12-1 and the second infrared light supplement lamp circuit board 12-2 are respectively and fixedly arranged at two sides of the COMS circuit board 10, and the COMS circuit board 10, the first infrared light supplement lamp circuit board 12-1 and the second infrared light supplement lamp circuit board 12-2 are all fixedly arranged on the mainboard 14; the first infrared LED lamp 13-1 and the second infrared LED lamp 13-2 are both fixedly arranged on the first infrared light supplement lamp circuit board 12-1; the third infrared LED lamp 13-3 and the fourth infrared LED lamp 13-4 are both fixedly arranged on the second infrared light supplement lamp circuit board 12-2. In the invention, the COMS circuit board is used for welding the COMS sensor and is connected with the mainboard through the FPC flat cable, so that the intelligent communication between the COMS circuit board and the mainboard is realized.

In the embodiment of the present invention, as shown in fig. 2, a local structure of a Wi-Fi routing module is selectively installed for a selectively installed camera device, which is different from fig. 1 mainly in that a Wi-Fi routing module composed of a Wi-Fi routing module main board 48, a heat sink and fixing device 49, a wired interface 50-1 and an antenna interface 50-2 is added, the Wi-Fi routing module can be fixed on the back of a front cover of a housing through two screw holes of the heat sink and fixing device 49, so that the Wi-Fi routing module is located right below a solar panel 4 without affecting light entering, the Wi-Fi routing module is connected with a flat cable type network interface 26-4 of the main board through a network cable to communicate with the main board, and the wired interface 50-1 is connected with a Wi-Fi antenna 8, when other or trusted devices can receive Wi-Fi signals of the Wi-Fi routing module and can access to the network, and (3) configuring camera working parameters and acquiring data stored on the camera.

In the embodiment of the present invention, as shown in fig. 3, two lens light-passing holes arranged longitudinally are fixedly arranged on the front cover 1 of the housing; a first LED light supplement lamp light through hole 3-1, a second LED light supplement lamp light through hole 3-2, a third LED light supplement lamp light through hole 3-3 and a fourth LED light supplement lamp light through hole 3-4 are fixedly arranged on two sides of the lens light through hole respectively; the two lens light through holes consist of a first outer light shielding plate 2-1, a second outer light shielding plate 2-2, a first light through hole 2-3, a second light through hole 2-4, a first inner light shielding plate 2-5 and a second inner light shielding plate 2-6; the first outer light screen 2-1, the second outer light screen 2-2, the first light through hole 2-3 and the second light through hole 2-4 are all fixedly arranged on the outer surface of the front cover 1 of the shell; the first inner shading plate 2-5 and the second inner shading plate 2-6 are fixedly arranged on the inner wall of the front cover 1 of the shell; a solar panel 4 and a Fresnel lens group are fixedly arranged below the lens light through hole in sequence; the Fresnel lens group comprises a Fresnel lens mounting table 5-1, a first Fresnel lens 5-2, a second Fresnel lens 5-3 and a third Fresnel lens 5-4, and the first Fresnel lens 5-2, the second Fresnel lens 5-3 and the third Fresnel lens 5-4 are all mounted on the Fresnel lens mounting table 5-1; a first microphone induction hole 6-1 and a second microphone induction hole 6-2 are respectively and fixedly arranged on two sides of the Fresnel lens group; a first sensor mounting shell 6-3 and a second sensor mounting shell 6-4 are fixedly arranged at the bottom of the inner wall of the shell front cover 1; the bottom of the outer wall of the shell front cover 1 is fixedly provided with a first sensor induction hole 6-5 and a second sensor induction hole 6-6.

In the embodiment of the invention, as shown in fig. 2, the first light through hole 2-3, the second light through hole 2-4, the first light through hole 3-1 of the LED light supplement lamp, the second light through hole 3-2 of the LED light supplement lamp, the third light through hole 3-3 of the LED light supplement lamp and the fourth light through hole 3-4 of the LED light supplement lamp are all covered by high-transparency organic glass.

In the embodiment of the present invention, as shown in fig. 4, a first CMOS circuit board mounting post 15-1, a second CMOS circuit board mounting post 15-2, a third CMOS circuit board mounting post 15-3, a fourth CMOS circuit board mounting post 15-4, a first infrared light supplement lamp circuit board mounting groove 16-1, a second infrared light supplement lamp circuit board mounting groove 16-2, a third infrared light supplement lamp circuit board mounting groove 16-3, a fourth infrared light supplement lamp circuit board mounting groove 16-4, a first motherboard power interface 17-1, a second motherboard power interface 17-2, a third motherboard power interface 17-3, a fourth motherboard power interface 17-4, and a GPS module 18 are fixedly disposed above the surface of the motherboard 14; a core board 19 is fixedly arranged below the GPS module 18; one side of the core board 19 is fixedly provided with a gyroscope 20; a first infrared sensor 23-1, a second infrared sensor 23-2, an SD card slot 22 and a radio frequency module 26 are fixedly arranged below the core board 19; the gyroscope 20, the first infrared sensor 23-1, the second infrared sensor 23-2, the SD card slot 22 and the radio frequency module 26 are fixedly arranged on the mainboard 14 in a bonding mode; a singlechip 21, a display interface 24, a USB interface 25 and a communication module 27 are fixedly arranged below the surface of the mainboard 14; the singlechip 21 and the radio frequency module 26 are in communication connection with a communication module; the single chip microcomputer is in communication connection with the radio frequency module;

the communication module 27 adopts a Wi-Fi routing module or a Wi-Fi module 26-1, the Wi-Fi routing module comprises a module main board 48, a heat sink and fixing device 49, a wired interface 50-1 and an antenna interface 50-2, the heat sink and fixing device 49 is fixedly arranged on the front surface of the module main board 48, the antenna interface 50-2 is fixedly arranged on one side of the heat sink and fixing device 49, the wired interface 50-1 is fixedly arranged on the back surface of the module main board 48, the antenna interface 50-2 is in communication connection with a Wi-Fi antenna, the wired interface 50-1 is fixedly connected with the module main board 48,

the multifunctional field infrared camera device also comprises a network port chip 26-2, a network port transformer 26-3 and a network cable interface 26-4; the network port chip 26-2, the network port transformer 26-3 and the network cable interface 26-4 are all fixedly arranged on the core board 19; the core board 19 is in communication connection with the Wi-Fi routing module through the network port chip 26-2, the network port transformer 26-3 and the network cable interface 26-4.

In the invention, the mainboard is positioned below the front casing of the camera, so that the CMOS sensor can be conveniently opposite to the light through hole and is connected with the power panel for power supply. The wired interface is fixedly connected with the module main board, so that the structure of the main board needs to be modified, the Wi-Fi module installed on the main board is removed, communication is achieved, when other or trusted equipment can receive Wi-Fi signals of the Wi-Fi routing module, the network can be accessed, working parameters of the camera are configured, and data stored in the camera can be acquired. In the invention, the mainboard is positioned below the front casing of the camera, so that the CMOS sensor can be conveniently opposite to the light through hole and is connected with the power panel for power supply.

In the embodiment of the present invention, as shown in fig. 4, the first CMOS circuit board mounting post 15-1, the second CMOS circuit board mounting post 15-2, the third CMOS circuit board mounting post 15-3, and the fourth CMOS circuit board mounting post 15-4 are screw posts;

a first infrared light supplement lamp circuit board mounting groove 16-1, a second infrared light supplement lamp circuit board mounting groove 16-2, a third infrared light supplement lamp circuit board mounting groove 16-3 and a fourth infrared light supplement lamp circuit board mounting groove 16-4 are all 2.54mm sockets;

the core board 19 comprises an SOC chip with neural network acceleration, a memory chip and an external memory chip; the SD card slot 22 is a 9pin minSD card slot; the display interface 24 adopts an FPC connecting line; the USB interface 25 adopts a micro USB female socket;

the surface of the GPS module 18 is provided with a shielding case which is in communication connection with the GPS antenna 7; the radio frequency module 26-1 is provided with an IPEX female seat which is in communication connection with the radio frequency antenna 9; the communication module 27 is provided with an IPEX female socket which is in communication connection with the WIFI antenna 8. In the invention, the WiFi module, the radio frequency module and the GPS module are independently welded on the PCB, and are fixed on the edge of the mainboard through a 2.54mm pin header interface to realize communication, so as to provide better heat dissipation capability; the SD card slot 22 is a 9pin minisD card slot, so that the projection of the edge of the inserted microsD card is not more than that of the mainboard.

In the embodiment of the present invention, as shown in fig. 5, when a Wi-Fi routing module is selected, the radio frequency module is replaced by a 26-2 port chip RT8201F, a 26-3 port transformer, and a 26-4 cable type network interface, and the rest of the motherboard is unchanged, and through the network interface, the SOC chip may be connected to the Wi-Fi routing module to access a routing network;

in the embodiment of the present invention, as shown in fig. 6, the surface center of the power panel 28 is fixedly provided with the microcontroller 29 and the solar charging chip 30 by means of paste welding, and the surface thereof is fixedly provided with the first solar battery charging interface 31-1, the second solar battery charging interface 31-2, the third solar battery charging interface 31-3 and the fourth solar battery charging interface 31-4;

a charging chip 34, a charging interface 35, a first battery interface 36-1 and a second battery interface 36-2 are fixedly arranged on the left side of the surface of the power panel 28; the charging chip 34 is in communication connection with the charging interface 35; the charging chip 34 is in one-to-one corresponding communication connection with the first lithium battery 38-1 and the second lithium battery 38-2 through the first battery interface 36-1 and the second battery interface 36-2; a first transformer chip 32-1, a second transformer chip 32-2, a third transformer chip 32-3 and a fourth transformer chip 32-4 are fixedly arranged on the left lower side of the surface of the power panel 28 in a sticking welding mode to form a transformer array; a first power output interface 33-1, a second power output interface 33-2, a third power output interface 33-3 and a fourth power output interface 33-4 are fixedly arranged below the voltage transformation array and are in one-to-one corresponding communication connection with the first voltage transformation chip 32-1, the second voltage transformation chip 32-2, the third voltage transformation chip 32-3 and the fourth voltage transformation chip 32-4 respectively. In the invention, when the charging interface is externally connected with a 5V power supply, the lithium battery can be charged through the charging chip via the battery interface positioned on the upper left of the front side; the power output interface is connected with the voltage transformation chip and is used for outputting voltages of 1.8V, 3.3V, 5V and 19.2V to the mainboard power interface on the mainboard; the power panel can be led out to lead wires to be connected with the main board so as to improve the heat dissipation capacity and be convenient to disassemble and replace.

In the embodiment of the present invention, as shown in fig. 5, a first solar cell charging interface 31-1, a second solar cell charging interface 31-2, a third solar cell charging interface 31-3, and a fourth solar cell charging interface 31-4 are respectively connected to a first solar cell panel 40-1, a second solar cell panel 40-2, a third solar cell panel 40-3, and a solar charging chip 30 in a one-to-one correspondence manner;

the first power output interface 33-1, the second power output interface 33-2, the third power output interface 33-3 and the fourth power output interface 33-4 are electrically connected with the first main board power interface 17-1, the second main board power interface 17-2, the third main board power interface 17-3 and the fourth main board power interface 17-4 in a one-to-one correspondence manner. In the invention, the charging interface and the power output interface are used for providing stable power supply for the mainboard.

In the embodiment of the present invention, as shown in fig. 1, a touch screen 47 is fixedly disposed on a surface of the outer box bottom cover 46.

In the embodiment of the present invention, as shown in fig. 6, a first battery panel fixing column 45-1, a second battery panel fixing column 45-2, a third battery panel fixing column 45-3, and a fourth battery panel fixing column 45-4 are fixedly disposed on an inner wall of the rear cover 41 of the housing;

as shown in fig. 7, the inner walls of the two sides of the rear cover 41 of the housing are further respectively and fixedly provided with a first main board fixing column 43-1, a second main board fixing column 43-2, a third main board fixing column 43-3, a fourth main board fixing column 43-4, a fifth battery panel fixing column 45-5 and a sixth battery panel fixing column 45-6; a rear cover battery jar 42 with salient points is fixedly arranged inside the rear cover 41 of the shell; the first front battery jar fixing post 44-1, the second front battery jar fixing post 44-2, the third front battery jar fixing post 44-3 and the fourth front battery jar fixing post 44-4 are fixedly arranged on two sides of the rear cover battery jar 42 respectively. In the invention, the battery panel fixing column is used for fixing the power panel; the main board fixing column is used for fixing the main board; a battery storage space surrounded by a rear cover battery jar is arranged at the middle position of the inner side of the rear cover, a protruding part on the rear cover battery jar is used for fixing a battery separator, and a space formed between the battery separator and the rear cover battery jar is used for accommodating a first lithium battery; the front battery jar fixing column is used for fixing the front battery jar; the space formed between the front battery can and the battery separator is used for accommodating the second lithium battery.

The working principle and the process of the invention are as follows: the camera case comprises a case front cover 1, a case rear cover 41 and a case bottom cover 46, the front case faces a shooting target when in use, two camera light through holes are arranged above the front case, four LED light supplementing light through holes are distributed at two sides of a first light through hole 2-3 and a second light through hole 2-4, an infrared induction Fresnel lens facing to the front and two sides is arranged below the front case, a solar cell panel mounting groove is arranged between the second light through hole 2-4 and the Fresnel lens, a GPS antenna 7, a WIFI antenna 8 and a radio frequency antenna 9 are respectively arranged at the left side, the right side and the upper side of the front case, a first sensor mounting case 6-3 and a second sensor mounting case 6-4 are respectively arranged at the left lower corner and the right lower corner inside, holes are punched outside the mounting cases, cables are pulled out and sealed inside, ear handles are arranged at two sides of the back case, and are fixed on a rod-shaped object through a strap, the solar charging panel mounting grooves are respectively arranged on the left side, the right side and the upper side of the solar charging panel, a battery jar is arranged in the solar charging panel mounting grooves close to the lower side, the bottom cover is fixed on the back casing and can be connected to the front casing through a buckle.

The first optical lens 11-1 and the second optical lens 11-2 comprise lenses and infrared filters, the lenses use fixed focus lenses according to environments, the infrared filters and the motors are integrated above the fixed focus lenses, and the first optical lens 11-1 and the second optical lens 11-2 are installed right above two CMOS sensing chips of the main board 14.

The main board 14 is integrated with an animal detection chip, a memory chip, an SD card, a communication module 27, a radio frequency module 26, a GPS module 18, a first infrared sensor 23-1 and a second infrared sensor 23-2, the components are fixed on a PCB, a CMOS image sensor is independently fixed on a small PCB, and the main board 14 is positioned under a front shell so that the CMOS sensor is just opposite to a light through hole and fixed on a back shell of a camera, and a lead is led out to be connected with a power supply board for power supply.

The infrared LED lamps are divided into two groups and welded on the two PCB boards, the PCB boards welded with the light supplementing lamps are fixed on the main board 14 through screw posts, so that the infrared LED lamps are located under the light through holes, and lead-out wires are connected with the power panel for power supply.

The power panel 28 is a PCB integrated with an intelligent charging chip, a single chip microcomputer 21, a controllable switch array and a transformation chip, and the power panel 28 can be connected with the upper part of the back of the main board 14 through a pin header interface of 2.54mm and fixed on a back shell through screws and studs; the lithium battery pack consists of a first lithium battery 38-1 and a second lithium battery 38-2, and is connected with the power panel 28 through a wire, and the two batteries are fixed in a battery groove of the back shell; the antenna array is formed by a GPS antenna 7, a radio frequency antenna 9 and a WiFi antenna 8 together, microstrip antennas with the same frequency are adopted, embedded in an antenna slot of a camera shell and connected with corresponding communication modules through coaxial cables; the solar panel 4 is connected with the power panel 28 through a cable and only can be connected with a charging chip, and is embedded in a solar panel mounting groove of the camera shell. The power board 28 is fixed to the mounting post above the battery well of the rear case, and the lead wires are connected to the upper side of the rear surface of the main board 14 to improve the heat dissipation capability and facilitate the replacement and removal.

Meanwhile, the camera can be modularized, the camera module comprises a CMOS circuit board 10, a first optical lens 11-1, a second optical lens 11-2 and an infrared filter, the CMOS sensor is welded on the independent CMOS circuit board 10 and is connected with a mainboard 14 through an FPC (flexible printed circuit) flat cable, intelligent SoC (system on chip) communication between the CMOS and the mainboard 14 is realized, the first optical lens 11-1, the second optical lens 11-2 and the infrared filters are also fixed on the circuit board, and the first optical lens 11-1 and the second optical lens 11-2 are positioned right above the CMOS sensor chip, so that cameras of different models can be selected and installed according to specific use conditions.

It will be appreciated by those of ordinary skill in the art that the examples provided herein are intended to assist the reader in understanding the principles of the invention and are to be construed as being without limitation to such specifically recited examples and embodiments. Those skilled in the art can make various other specific changes and combinations based on the teachings of the present invention without departing from the spirit of the invention, and these changes and combinations are within the scope of the invention.

Claims

1. A multifunctional field infrared camera device is characterized by comprising a shell front cover (1), a shell rear cover (41), a shell bottom cover (46), a GPS antenna (7), a WIFI antenna (8), a radio frequency antenna (9), a COMS circuit board (10), a first optical lens (11-1), a second optical lens (11-2), a main board (14), a power panel (28), a front battery jar (37), a first lithium battery (38-1), a second lithium battery (38-2), a battery partition plate (39), a first solar panel (40-1), a second solar panel (40-2) and a third solar panel (40-3);

the shell front cover (1), the shell rear cover (41) and the outer box bottom cover (46) form a camera shell of the infrared camera device; the COMS circuit board (10), the first optical lens (11-1), the second optical lens (11-2), the mainboard (14), the power panel (28), the front battery jar (37), the first lithium battery (38-1), the second lithium battery (38-2) and the battery separator (39) are all fixedly installed inside the camera shell, and the mainboard (14), the power panel (28), the front battery jar (37), the first lithium battery pack (38-1), the second lithium battery pack (38-2) and the battery separator (39) are fixedly arranged inside the shell rear cover (41);

the first optical lens (11-1) and the second optical lens (11-2) are fixedly arranged on the COMS circuit board (10); the first lithium battery (38-1) is fixedly arranged in a gap formed by the front battery jar (37) and the battery separator (39); the second lithium battery (38-2) is fixedly arranged in a gap formed by the battery separator (39) and the shell rear cover (41);

a WIFI antenna (8) and a radio frequency antenna (9) are respectively and fixedly arranged on two sides of the shell front cover (1), and a GPS antenna (7) is fixedly arranged on the top of the shell front cover; and a first solar cell panel (40-1) and a third solar cell panel (40-3) are respectively fixedly arranged on two sides of the shell rear cover (41), and a second solar cell panel (40-2) is fixedly arranged on the top of the shell rear cover.

2. The multifunctional field infrared camera device according to claim 1, further comprising a first infrared fill light circuit board (12-1), a second infrared fill light circuit board (12-2), a first infrared LED lamp (13-1), a second infrared LED lamp (13-2), a third infrared LED lamp (13-3) and a fourth infrared LED lamp (13-4);

the first infrared light supplement lamp circuit board (12-1) and the second infrared light supplement lamp circuit board (12-2) are fixedly arranged on two sides of the COMS circuit board (10) respectively, and the COMS circuit board (10), the first infrared light supplement lamp circuit board (12-1) and the second infrared light supplement lamp circuit board (12-2) are fixedly arranged on the mainboard (14); the first infrared LED lamp (13-1) and the second infrared LED lamp (13-2) are fixedly arranged on the first infrared light supplement lamp circuit board (12-1); and the third infrared LED lamp (13-3) and the fourth infrared LED lamp (13-4) are both fixedly arranged on the second infrared light supplement lamp circuit board (12-2).

3. The multifunctional field infrared camera device as claimed in claim 1, wherein the front cover (1) of the housing is fixedly provided with two lens light-passing holes which are longitudinally arranged; a first LED light supplement lamp light through hole (3-1), a second LED light supplement lamp light through hole (3-2), a third LED light supplement lamp light through hole (3-3) and a fourth LED light supplement lamp light through hole (3-4) are fixedly arranged on two sides of the lens light through hole respectively; the two lens light through holes consist of a first outer light shielding plate (2-1), a second outer light shielding plate (2-2), a first light through hole (2-3), a second light through hole (2-4), a first inner light shielding plate (2-5) and a second inner light shielding plate (2-6); the first outer light screen (2-1), the second outer light screen (2-2), the first light through hole (2-3) and the second light through hole (2-4) are all fixedly arranged on the outer surface of the front cover (1) of the shell; the first inner shading plate (2-5) and the second inner shading plate (2-6) are fixedly arranged on the inner wall of the front cover (1) of the shell; a solar panel (4) and a Fresnel lens group are sequentially and fixedly arranged below the lens light through hole; the Fresnel lens group comprises a Fresnel lens mounting table (5-1), a first Fresnel lens (5-2), a second Fresnel lens (5-3) and a third Fresnel lens (5-4), and the first Fresnel lens (5-2), the second Fresnel lens (5-3) and the third Fresnel lens (5-4) are all mounted on the Fresnel lens mounting table (5-1); a first microphone induction hole (6-1) and a second microphone induction hole (6-2) are respectively and fixedly arranged on two sides of the Fresnel lens group; a first sensor mounting shell (6-3) and a second sensor mounting shell (6-4) are fixedly arranged at the bottom of the inner wall of the shell front cover (1); the bottom of the outer wall of the shell front cover (1) is fixedly provided with a first sensor induction hole (6-5) and a second sensor induction hole (6-6).

4. The multifunctional field infrared camera device according to claim 3, wherein the first light through hole (2-3), the second light through hole (2-4), the first LED fill light through hole (3-1), the second LED fill light through hole (3-2), the third LED fill light through hole (3-3) and the fourth LED fill light through hole (3-4) are all covered by high-transparency organic glass.

5. The multifunctional field infrared camera device of claim 1, a first CMOS circuit board mounting column (15-1), a second CMOS circuit board mounting column (15-2), a third CMOS circuit board mounting column (15-3), a fourth CMOS circuit board mounting column (15-4), a first infrared light supplement lamp circuit board mounting groove (16-1), a second infrared light supplement lamp circuit board mounting groove (16-2), a third infrared light supplement lamp circuit board mounting groove (16-3), a fourth infrared light supplement lamp circuit board mounting groove (16-4), a first mainboard power interface (17-1), a second mainboard power interface (17-2), a third mainboard power interface (17-3), a fourth mainboard power interface (17-4) and a GPS module (18) are fixedly arranged above the surface of the mainboard (14); a core board (19) is fixedly arranged below the GPS module (18); one side of the core plate (19) is fixedly provided with a gyroscope (20); a first infrared sensor (23-1), a second infrared sensor (23-2), an SD card slot (22) and a radio frequency module (26) are fixedly arranged below the core board (19); the gyroscope (20), the first infrared sensor (23-1), the second infrared sensor (23-2), the SD card slot (22) and the radio frequency module (26) are fixedly arranged on the main board (14) in a bonding mode; a singlechip (21), a display interface (24), a USB interface (25) and a communication module (27) are fixedly arranged below the surface of the mainboard (14); the single chip microcomputer (21) is in communication connection with the radio frequency module (26);

the Wi-Fi routing module or the Wi-Fi module (26-1) is adopted in the communication module (27), the Wi-Fi routing module comprises a module main board (48), a radiating fin and fixing device (49), a wired interface (50-1) and an antenna interface (50-2), the radiating fin and fixing device (49) is fixedly arranged on the front face of the module main board (48), the antenna interface (50-2) is fixedly arranged on one side of the radiating fin and fixing device (49), the wired interface (50-1) is fixedly arranged on the back face of the module main board (48), the antenna interface (50-2) is in communication connection with a Wi-Fi antenna, and the wired interface (50-1) is fixedly connected with the module main board (48),

the multifunctional field infrared camera device also comprises a network port chip (26-2), a network port transformer (26-3) and a network cable interface (26-4); the network port chip (26-2), the network port transformer (26-3) and the network cable interface (26-4) are all fixedly arranged on the core board (19); the core board (19) is in communication connection with the Wi-Fi routing module through the network port chip (26-2), the network port transformer (26-3) and the network cable interface (26-4).

6. The multifunctional field infrared camera device according to claim 5, characterized in that the first CMOS circuit board mounting post (15-1), the second CMOS circuit board mounting post (15-2), the third CMOS circuit board mounting post (15-3) and the fourth CMOS circuit board mounting post (15-4) are screw posts;

the first infrared light supplement lamp circuit board mounting groove (16-1), the second infrared light supplement lamp circuit board mounting groove (16-2), the third infrared light supplement lamp circuit board mounting groove (16-3) and the fourth infrared light supplement lamp circuit board mounting groove (16-4) are all 2.54mm sockets;

the core board (19) comprises an SOC chip with neural network acceleration, a memory chip and an external memory chip; the SD card slot (22) is a 9pin minSD card slot; the display interface (24) adopts an FPC connecting wire; the USB interface (25) adopts a micro USB female socket;

the surface of the GPS module (18) is provided with a shielding case which is in communication connection with the GPS antenna (7); the radio frequency module (26) is provided with an IPEX female seat which is in communication connection with the radio frequency antenna (9); an IPEX female socket is arranged on the communication module (27) and is in communication connection with the WIFI antenna (8).

7. The multifunctional field infrared camera device as claimed in claim 1, wherein the surface center of the power panel (28) is fixedly provided with a microcontroller (29) and a solar charging chip (30) by means of paste welding, and the surface sides of the power panel are fixedly provided with a first solar battery charging interface (31-1), a second solar battery charging interface (31-2), a third solar battery charging interface (31-3) and a fourth solar battery charging interface (31-4);

a charging chip (34), a charging interface (35), a first battery interface (36-1) and a second battery interface (36-2) are fixedly arranged on the left side of the surface of the power panel (28); the charging chip (34) is in communication connection with the charging interface (35); the charging chip (34) is in one-to-one corresponding communication connection with the first lithium battery (38-1) and the second lithium battery (38-2) through the first battery interface (36-1) and the second battery interface (36-2); a first transformer chip (32-1), a second transformer chip (32-2), a third transformer chip (32-3) and a fourth transformer chip (32-4) are fixedly arranged on the left lower side of the surface of the power panel (28) in a sticking welding mode and form a transformer array; and a first power output interface (33-1), a second power output interface (33-2), a third power output interface (33-3) and a fourth power output interface (33-4) are fixedly arranged below the voltage transformation array and are in one-to-one corresponding communication connection with the first voltage transformation chip (32-1), the second voltage transformation chip (32-2), the third voltage transformation chip (32-3) and the fourth voltage transformation chip (32-4) respectively.

8. The multifunctional field infrared camera device as claimed in claim 7, wherein the first solar cell charging interface (31-1), the second solar cell charging interface (31-2), the third solar cell charging interface (31-3) and the fourth solar cell charging interface (31-4) are respectively connected with the first solar cell panel (40-1), the second solar cell panel (40-2), the third solar cell panel (40-3) and the solar charging chip (30) in a one-to-one correspondence manner;

the first power output interface (33-1), the second power output interface (33-2), the third power output interface (33-3) and the fourth power output interface (33-4) are electrically connected with the first main board power interface (17-1), the second main board power interface (17-2), the third main board power interface (17-3) and the fourth main board power interface (17-4) in a one-to-one corresponding mode.

9. The multifunctional field infrared camera device as claimed in claim 1, wherein a touch screen (47) is fixedly arranged on the surface of the outer box bottom cover (46).

10. The multifunctional field infrared camera device as claimed in claim 1, wherein a first battery plate fixing column (45-1), a second battery plate fixing column (45-2), a third battery plate fixing column (45-3) and a fourth battery plate fixing column (45-4) are fixedly arranged on the inner wall of the housing rear cover (41);

the inner walls of the two sides of the shell rear cover (41) are respectively and fixedly provided with a first main board fixing column (43-1), a second main board fixing column (43-2), a third main board fixing column (43-3), a fourth main board fixing column (43-4), a fifth battery panel fixing column (45-5) and a sixth battery panel fixing column (45-6); a rear cover battery jar (42) with salient points is fixedly arranged in the rear cover (41) of the shell; and a first front battery jar fixing column (44-1), a second front battery jar fixing column (44-2), a third front battery jar fixing column (44-3) and a fourth front battery jar fixing column (44-4) are respectively and fixedly arranged on two sides of the rear cover battery jar (42).