CN211702233U - Solar thermal imaging device - Google Patents

Abstract

The utility model discloses a solar thermal imaging device, shoot the module including thermal imagery casing, solar energy receiving module and thermal imagery, the thermal imagery casing is polyhedral structure, thermal imagery shoot the module assemble in inside the thermal imagery casing, solar energy receiving module sets up thermal imagery casing surface, solar energy receiving module absorbs solar energy, does the power supply of thermal imagery shooting module. The utility model discloses a solar energy supplies power to battery module, and the energy is high-efficient clean, and is pollution-free, accords with the environmental protection requirement, and after the electric power tower used the solar energy power supply, solar energy camera simple to operate reduced simultaneously because of costs such as the outage loss that traditional power supply mode caused to adopt multiple mounting means, reduce because of the solar energy absorption efficiency of ice and snow cover scheduling problem influence, improved power supply efficiency.

Description

Solar thermal imaging device

Technical Field

The utility model belongs to the control field relates to a solar thermal energy image device.

Background

Along with the development of the technology, people pay more attention to the safety of the people and the society, so that more and more cameras are monitored and are applied to the fields of security protection and production, the cameras such as a thermal image monitoring solar power supply generally adopt independent solar panels, and in partial application fields, the problems of troublesome installation, influence of an installation angle on a solar energy effect, coverage of solar energy by ice and snow and the like exist.

For example, the solar camera installed on the power tower needs to be installed conveniently because the installation position of the power tower is as high as dozens of meters; the angle of the monitoring equipment and other influences cannot definitely determine the installation angle of the camera; the current solar panel is easily covered by ice and snow in severe weather, so that the power supply efficiency of the solar panel is also influenced after the solar panel is clear in the following days, and the equipment effectively solves the problem.

Disclosure of Invention

The utility model provides a solar thermal imaging device for overcoming the defects of the prior art.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a solar thermal imaging apparatus, characterized in that: the thermal image shooting device comprises a thermal image shell (101), a solar energy receiving module (102) and a thermal image shooting module, wherein the thermal image shell (101) is of a polyhedral structure, the thermal image shooting module is assembled inside the thermal image shell (101), the solar energy receiving module (102) is arranged on the outer surface of the thermal image shell (101), and the solar energy receiving module (102) absorbs solar energy and supplies power for the thermal image shooting module.

Further, the method comprises the following steps of; the thermal image shooting module comprises an infrared optical lens (103), a thermal image detector (104) and a processing circuit (105), wherein the solar energy receiving module (102) supplies power to the processing circuit (105), and monitoring is carried out through the thermal image detector (104) and the infrared optical lens (103).

Further, the method comprises the following steps of; the solar energy receiving module (102) can be arranged as a solar panel or a solar film.

Further, the method comprises the following steps of; the solar energy receiving modules (102) are arranged on two or more planes or curved surfaces in the polyhedral structure of the thermal imagery shell (101).

Further, the method comprises the following steps of; the thermal image shooting system is characterized in that the thermal image shell (101) is of a three-bin structure, a thermal image detector (104) and a processing circuit (105) in the thermal image shooting module, a battery module (107) and a charge and discharge control module are arranged in a bin of the thermal image shell (101), and the battery module (107) is located in a bin between the thermal image detector (104) and the processing circuit (105).

Further, the method comprises the following steps of; the two sides of the thermal image shell (101) are designed to be inwards inclined, the solar energy receiving module (102) is arranged on the thermal image shell (101), the included angle between the solar energy receiving module and the upper side of the thermal image shell (101) is smaller than 90 degrees, and the included angle between the solar energy receiving module and the lower side of the thermal image shell (101) is larger than 90 degrees.

Further, the method comprises the following steps of; and a rotating mechanism is arranged in the thermal image shell (101) and is connected with the outside.

Further, the method comprises the following steps of; the thermal image shell (101) is arranged to be of a two-bin structure.

Further, the method comprises the following steps of; when the thermal image shell (101) is of a two-bin structure, a thermal image shooting module and a battery module (107) are respectively arranged, and the processing circuit (105) is arranged in any one of the two bins.

To sum up, the utility model discloses a solar energy supplies power to battery module, and the energy is high-efficient clean, and is pollution-free, accords with the environmental protection requirement, and after the electric power tower used the solar energy power supply, and solar energy camera simple to operate reduced simultaneously because of the outage loss cost such as that traditional power supply mode caused to adopt multiple mounting means, reduce because of the solar energy absorption efficiency that ice and snow covers the scheduling problem influence, improved power supply efficiency.

Drawings

Fig. 1a is a front view of the schematic diagram of the device in embodiment 1 of the present invention.

Fig. 1b is a left side view of the schematic diagram of the apparatus according to embodiment 1 of the present invention.

Fig. 2a is a front view of a thermal imagery housing three-bin structure in embodiment 2 of the present invention.

Fig. 2b is a left side view of the three-bin structure of the thermal imagery housing in embodiment 2 of the present invention.

Fig. 3 is a schematic view of the manner in which the thermal image shell is tilted inward in the lateral surface in example 3 of the present invention.

Fig. 4 is a schematic diagram of another embodiment of a solar energy receiving module in example 4 of the present invention.

The labels in the figure are: the system comprises a thermal image housing 101, a solar energy receiving module 102, an infrared optical lens 103, a thermal image detector 104, a processing circuit 105 and a battery module 107.

Detailed Description

In order to make the technical field personnel understand the utility model discloses the scheme, will combine the drawing in the embodiment of the utility model below, to the technical scheme in the embodiment of the utility model carries out clear, complete description.

All directional indicators (such as upper, lower, left, right, front, rear, horizontal, vertical … …) in the embodiments of the present invention are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture, if the specific posture changes, the directional indicator changes accordingly.

The solar thermal imaging device is provided with a thermal imaging sensor, and in addition, the solar thermal imaging device is provided with one or more of a wireless communication module, a positioning module, a voice module, a light module, other optical shooting modules, a temperature module, a humidity module, a wind speed module, an inclination module, a temperature control module, a startup and shutdown module, a wind energy module, a timing shooting module, a battery electric quantity measuring module and an alarm module, wherein one or more of the wireless communication module, the positioning module, the voice module, the light module and the other optical shooting modules are; various optical sensors may also be provided, such as ultraviolet imaging, gas imaging, visible light sensors, etc.; the utility model discloses also can be deformed into, only have thermal imaging, ultraviolet formation of image, gaseous formation of image, visible light sensor etc. one or more's combination wherein.

Example 1:

as shown in fig. 1, a solar thermal imaging device comprises a thermal image housing 101, a solar energy receiving module 102 and a thermal image shooting module, wherein the thermal image housing 101 is of a polyhedral structure, the thermal image shooting module is assembled inside the thermal image housing 101, the solar energy receiving module 102 is arranged on the outer surface of the thermal image housing 101, and the solar energy receiving module 102 absorbs solar energy to supply power to the thermal image shooting module.

The thermal image shooting module comprises an infrared optical lens 103, a thermal image detector 104 and a processing circuit 105, the solar energy receiving module 102 supplies power to the processing circuit 105, the thermal image detector 104 and the infrared optical lens 103 are used for monitoring, and the working principle of the infrared optical lens 103, the thermal image detector 104 and the processing circuit 105 can refer to the existing thermal image shooting device.

The thermal image housing 101 is of a polyhedral structure, in this example, the solar receiving modules 102 are arranged on four planes, namely, the upper side, the left side, the right side and the front side, of the outer surface of the thermal image housing 101, and the solar receiving modules 102 are located in the direction of receiving different sunshine, so that the solar receiving capability of the equipment is avoided when the sun faces different, and the solar receiving efficiency of the equipment is improved. In addition, in the case of ice and snow weather or heavily polluted flying dust, the solar energy receiving module is prevented from being affected by the ice and snow or dust accumulated on the upper part, and the solar energy receiving efficiency of the device is improved.

The thermal image shell 101 can be internally provided with a rotating mechanism, and the monitoring range of the camera shooting mechanism is enlarged and the receiving direction of the solar receiving module 102 can be adjusted to improve the solar receiving efficiency through the connection arrangement of the rotating mechanism and the camera shooting mechanism.

Example 2:

as shown in fig. 2, the difference between this embodiment and embodiment 1 is that the thermal image housing 101 is configured to have at least three-bin structure, the thermal image detector 104, the battery module 107, the processing circuit 105 and the charge and discharge control module in the thermal image capturing module are arranged from left to right according to the visual angle of fig. 2, and the battery module 107 is located in the bin between the thermal image detector 104 and the processing circuit 105, so as to prevent the heat of the processing circuit 105 from being conducted to the thermal image detector 104 and affecting temperature measurement and the like.

Preferably, if the power consumption and heat of the processing circuit 105 are not large, the thermal image housing 101 may be configured as a two-compartment structure, and the thermal image capturing module and the battery module 107 are respectively configured, and at this time, the processing circuit 105 is disposed in any one of the two compartments.

The solar energy receiving module 102 is arranged on the thermal image housing 101, and the surface of the thermal image housing 101 can be used as a substrate of the solar energy receiving module 102; preferably, the battery module 107 is configured inside the thermal image housing 101, and is configured to supply power when the electric quantity generated by the solar energy receiving module 102 is insufficient, and to be charged by the electric quantity generated by the solar energy receiving module 102, and preferably, an optical sensor is configured inside the thermal image housing 101.

Example 3:

as shown in fig. 3, this embodiment is a modification direction of embodiment 1, in this embodiment, two sides of the thermal image housing 101 are designed to be inclined inward to avoid ice and snow accumulation, and the two side solar energy receiving modules 102 are arranged in an inclined inward manner, and make an angle smaller than 90 ° with the upper side of the thermal image housing 101, preferably between 70 ° and 90 °, for example, 80 ° in this embodiment. The included angle between the solar receiving modules 102 and the lower side of the thermal image housing 101 is greater than 90 degrees, for example, the included angle is set to 100 degrees in this example, so that when the solar receiving modules 102 on the upper side are covered by ice and snow, the solar receiving modules 102 on the left side and the right side can also continue to receive solar energy, the influence of ice and snow or dust accumulated on the upper portion on the solar receiving modules 102 is avoided, and the solar receiving efficiency of the device is improved.

Example 4:

as shown in fig. 4, this embodiment is another modification direction of embodiment 1, in this embodiment, the size of the solar energy receiving module 102 located on the upper side of the thermal image housing 101 slightly exceeds the edges of the solar energy receiving modules 102 on the front side and the left and right sides, and the thermal image housing 101 and the solar energy receiving modules 102 located on the side surfaces of the thermal image housing 101 are covered, so that the influence of the covering of ice and snow and the like on the solar energy receiving modules 102 on the front side and the left and right sides can be reduced, and the influence on the solar absorption efficiency of the solar energy receiving modules 102 on the sun can be avoided.

In each of the above embodiments, a rotation mechanism may be provided, and the connection between the rotation mechanism and the camera mechanism increases the monitoring range of the camera mechanism and can adjust the receiving direction of the solar receiving module 102 to improve the solar receiving efficiency.

In addition, in the above embodiments, the solar energy receiving module 102 may be configured as a solar panel, a solar film, or the like for receiving sunlight. The solar energy receiving module 102 is arranged on the thermal image housing 101, and the thermal image housing 101 is used as a substrate of the solar energy receiving module 102.

In other examples, a shield shell may be disposed outside the thermal image housing 101 for protection, and the solar energy receiving module 102 may be disposed on the shield shell for absorbing solar energy, in which case the shield shell serves as a substrate of the solar energy receiving module 102.

It is obvious that the described embodiments are only some of the embodiments of the present invention, and not all of them. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts shall belong to the protection scope of the present invention.

Claims (8)

1. A solar thermal imaging apparatus, characterized in that: the thermal image shooting device comprises a thermal image shell (101), a solar energy receiving module (102) and a thermal image shooting module, wherein the thermal image shell (101) is of a polyhedral structure, the thermal image shooting module is assembled inside the thermal image shell (101), the solar energy receiving module (102) is arranged on the outer surface of the thermal image shell (101), and the solar energy receiving module (102) absorbs solar energy and supplies power for the thermal image shooting module.

2. A solar thermal imaging apparatus according to claim 1, wherein: the thermal image shooting module comprises an infrared optical lens (103), a thermal image detector (104) and a processing circuit (105), wherein the solar energy receiving module (102) supplies power to the processing circuit (105), and monitoring is carried out through the thermal image detector (104) and the infrared optical lens (103).

3. A solar thermal imaging apparatus according to claim 1, wherein: the solar energy receiving module (102) can be arranged as a solar panel or a solar film.

4. A solar thermal imaging apparatus according to claim 1, wherein: the solar energy receiving modules (102) are arranged on two or more planes or curved surfaces in the polyhedral structure of the thermal imagery shell (101).

5. A solar thermal imaging apparatus according to claim 1 or 2, wherein: the thermal image shooting system is characterized in that the thermal image shell (101) is of a three-bin structure, a thermal image detector (104) and a processing circuit (105) in the thermal image shooting module, a battery module (107) and a charge and discharge control module are arranged in a bin of the thermal image shell (101), and the battery module (107) is located in a bin between the thermal image detector (104) and the processing circuit (105).

6. A solar thermal imaging apparatus according to claim 1, wherein: the two sides of the thermal image shell (101) are designed to be inwards inclined, the solar energy receiving module (102) is arranged on the thermal image shell (101), the included angle between the solar energy receiving module and the upper side of the thermal image shell (101) is smaller than 90 degrees, and the included angle between the solar energy receiving module and the lower side of the thermal image shell (101) is larger than 90 degrees.

7. A solar thermal imaging apparatus according to claim 1, wherein: and a rotating mechanism is arranged in the thermal image shell (101) and is connected with the outside.

8. A solar thermal imaging apparatus according to claim 5, wherein: the thermal image shell (101) is of a two-bin structure, the thermal image shooting module and the battery module (107) are respectively arranged, and the processing circuit (105) is arranged in any bin of the two bins.

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