CN211702159U - Monitoring devices based on solar energy guard shield - Google Patents

Abstract

The utility model discloses a monitoring device based on a solar energy shield, which comprises a solar energy camera mechanism and a shield shell, wherein the solar energy camera mechanism comprises a thermal image shell, a solar energy receiving module and a thermal image shooting module, the solar energy receiving module is arranged at the upper side of the shield shell, the shield shell is arranged on the thermal image shell, the thermal image shooting module is assembled in the thermal image shell, the solar energy receiving module absorbs solar energy to supply power for the thermal image shooting module, the utility model adopts clean and efficient solar energy to supply power for a camera, saves energy, protects environment, prolongs the service life of equipment, reduces the use cost, is easy to popularize, has simple structure, strong wind resistance and convenient installation, is suitable for high places such as an electric power tower, and simultaneously adopts a plurality of installation modes to reduce the solar energy absorption efficiency influenced by the problems of ice and snow coverage and the like, the power supply efficiency is improved.

Description

Monitoring devices based on solar energy guard shield

Technical Field

The utility model belongs to the control field relates to a monitoring devices based on solar energy guard shield.

Background

Along with the development of social productivity, people's requirement to camera control improves gradually, except small and exquisite, clear basic function, need camera control itself to satisfy more abominable service environment, for example, the solar camera that electric power tower installed, because electric power tower mounted position is up to tens meters, wind-force is stronger than ground, this needs can simple to operate and strong solar camera of anti-wind ability, and present solar panel is easily under the abominable weather, is covered by ice and snow, leads to the follow-up day after fine, also influences its power supply efficiency. Meanwhile, under the environments such as wind, snow and the like, the solar camera shell is easy to become brittle and corrode, internal parts are made to contact with the external environment, damage is caused, the working cost for replacement of workers is increased, and the device effectively solves the problem.

Disclosure of Invention

The utility model discloses an overcome prior art not enough, provide a monitoring devices based on solar energy guard shield.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a monitoring device based on solar energy guard shield which characterized in that: the solar thermal image shooting system comprises a solar thermal image mechanism and a shield shell (106), wherein the solar thermal image mechanism comprises a thermal image shell (101), a solar receiving module (102) and a thermal image shooting module, the solar receiving module (102) is arranged on the upper side of the shield shell (106), the shield shell (106) is arranged on the thermal image shell (101), the thermal image shooting module is assembled inside the thermal image shell (101), and the solar receiving module (102) absorbs solar energy to supply 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).

Further, the method comprises the following steps of; the shroud housing (106) may be configured in a polyhedral structure, a cambered surface structure, a bridge-type structure, a polyhedral column-type or a spherical structure.

Further, the method comprises the following steps of; the solar energy receiving module (102) is set to be a solar panel or a solar film, and the shield shell (106) is a substrate of the solar energy receiving module (102).

Further, the method comprises the following steps of; the shape of the solar receiving module (102) is matched with that of the shield shell (106), and the solar receiving module (102) is arranged on two or more planes or curved surfaces of the polyhedral structure of the shield shell (106).

Further, the method comprises the following steps of; the solar energy receiving module is characterized in that two sides of the shield shell (106) are designed to be inwards inclined, the solar energy receiving module (102) is arranged on the shield shell (106), the included angle between the solar energy receiving module and the upper side of the shield shell (106) is smaller than 90 degrees, and the included angle between the solar energy receiving module and the lower side of the shield shell (106) is larger than 90 degrees.

Further, the method comprises the following steps of; the protective cover shell (106) is of a bridge-type structure, the thermal image shell (101) is integrally covered by the protective cover shell (106), the solar receiving modules (102) are arranged on the outer side of the protective cover shell (106), and the width of the upper side of the protective cover shell (106) slightly exceeds the edge parts of the solar receiving modules (102) arranged on the left side and the right side of the protective cover shell (106), so that the solar receiving modules (102) on the left side and the right side are covered.

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

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; when 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 one of the two bins.

To sum up, the utility model discloses a clean, efficient solar energy supplies power to the camera, and is energy-concerving and environment-protective, has prolonged the life of equipment, has reduced use cost, easily promotes, and overall arrangement simple structure, and the anti-wind ability is strong, and the installation of being convenient for is applicable to eminence places such as electric power shaft tower, and the guard shield adopts multiple mounting means simultaneously, reduces because of the solar energy absorption efficiency that ice and snow covers the scheduling problem influence, has 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 three-bin structural schematic diagram of a thermal image housing according to embodiment 2 of the present invention.

Fig. 2b is a left side view of a three-bin structural schematic diagram of a thermal imagery housing according to embodiment 2 of the present invention.

Fig. 3a is a front view of a schematic diagram of an embodiment of a shield case according to embodiment 3 of the present invention.

Fig. 3b is a left side view of an embodiment of a shield case according to embodiment 3 of the present invention.

Fig. 4 is a schematic view of a side inward inclination mode of a shield shell in embodiment 4 of the present invention.

Fig. 5 is a schematic view of a shield case according to another embodiment of the present invention in example 5.

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, a shield housing 106 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 camera mechanism is provided with a thermal imaging sensor, and in addition, the solar camera mechanism 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 arranged; 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 monitoring device based on a solar energy shield comprises a solar thermal image mechanism and a shield shell 106, wherein the solar thermal image mechanism comprises a thermal image shell 101, a solar energy receiving module 102 and a thermal image shooting module, the solar energy receiving module 102 is arranged on the outer side of the shield shell 106, the shield shell 106 is arranged on the thermal image shell 101, the thermal image shooting module is assembled in the thermal image shell 101, and the solar energy receiving module 102 absorbs solar energy to supply power to the thermal image shooting module.

The solar thermal image mechanism comprises the thermal image housing 101, the solar energy receiving module 102 and the thermal image shooting module, the thermal image shooting module is assembled inside the thermal image housing 101, the thermal image shooting module comprises an infrared optical lens 103, a thermal image detector 104 and a processing circuit 105, 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 protective cover shell 106 is arranged on the outer side of the thermal image shell 101 and plays a protective role, the solar receiving module 102 is assembled on the outer side of the protective cover shell 106, the solar receiving module 102 is a solar panel or a solar film and other sunlight absorbing components, the solar receiving module 102 absorbs solar energy and supplies power to the thermal image shooting module, and smooth implementation of monitoring actions is guaranteed.

The shroud housing 106 is a polyhedron structure, the solar energy receiving module 102 is disposed on the upper side of the outer surface of the shroud housing 106, and three planes on the left and right sides of the outer surface of the shroud housing, and the solar energy receiving module 102 is located in the direction of receiving different sunshine, so as to avoid reducing the ability of receiving the sun when the sun faces the sun, and of course, in other embodiments, the solar energy receiving module may be redundant or less than three planes.

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.

The solar energy receiving module 102 is disposed on the shield casing 106, and the surface of the shield casing 106 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.

In other embodiments, if the power consumption and the heat of the processing circuit 105 are not large, the thermal image housing 101 may be configured as a two-bin 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 bins.

Example 3:

as shown in fig. 3, this embodiment is a deformation direction of the shroud housing 106 in embodiment 1, in this embodiment, the shroud housing 106 is configured as an arc surface, the size of the arc surface is larger than the width of the thermal image housing 101, the thermal image housing 101 is entirely covered by the shroud housing 106, the solar energy receiving module 102 is a solar panel or a solar film and other components for receiving sunlight, the solar energy receiving module 102 can be bent according to the curved surface of the shroud housing 106, the solar energy receiving module 102 is disposed on the outer surface of the shroud housing 106, the shape of the solar energy receiving module 102 is matched with the shroud housing 106, the solar energy receiving module 102 is located at a position for receiving the sun in different directions, and the arc surface prevents accumulation of ice and snow or dust, so as to further increase the solar energy receiving amount of the solar energy receiving module 102.

Example 4:

as shown in fig. 4, this embodiment is a modification of embodiment 1, in this embodiment, both sides of the shroud housing 106 are designed to be inclined inward so as to prevent ice and snow from accumulating, the solar energy receiving module 102 is disposed on the shroud housing 106, and has an angle smaller than 90 °, preferably between 70 ° and 90 °, for example, 80 ° in this embodiment, and has an angle larger than 90 °, for example, 100 ° in this embodiment, with respect to the lower side of the shroud housing 106, so that when the solar energy receiving module 102 on the upper side is covered with ice and snow, etc., the solar energy receiving modules 102 on the left and right sides can continue to receive solar energy, thereby preventing the ice and snow or dust accumulated on the upper side from affecting the solar energy receiving module 102 and improving the solar energy receiving efficiency of the device.

Example 5:

as shown in fig. 5, this embodiment is another deformation direction of the shroud housing 106 in embodiment 1, in this embodiment, the shroud housing 106 is configured as a bridge structure, the shroud housing 106 covers the entire thermal image housing 101 to perform a protection function, the solar energy receiving modules 102 are disposed outside the shroud housing 106, and the width of the upper side of the shroud housing 106 slightly exceeds the edge portions of the solar energy receiving modules 102 disposed on the left and right sides of the shroud housing 106 to cover the solar energy receiving modules 102 on the left and right sides, so as to reduce the influence of ice and snow and the like on the solar energy receiving modules 102 on the left and right sides, avoid influencing the absorption capability of the solar energy receiving modules 102 on the sun, and perform double protection on the camera mechanism, and improve the wind resistance of the entire camera mechanism.

In addition, in each of the above embodiments, a rotating mechanism may be disposed in the thermal image housing 101, and through the connection arrangement between the rotating mechanism and the camera, the monitoring range of the camera is enlarged, and the receiving direction of the solar receiving module 102 may be adjusted to improve the solar receiving efficiency.

In other examples, a housing structure without a shield may be disposed outside the thermal image housing 101, in which case the solar energy receiving module 102 may be disposed on the thermal image housing 101 to absorb solar energy, in which case the thermal image housing 101 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 (10)

1. A monitoring device based on solar energy guard shield which characterized in that: the solar thermal image shooting system comprises a solar thermal image mechanism and a shield shell (106), wherein the solar thermal image mechanism comprises a thermal image shell (101), a solar receiving module (102) and a thermal image shooting module, the solar receiving module (102) is arranged on the outer side of the shield shell (106), the shield shell (106) is arranged on the outer side of the thermal image shell (101), the thermal image shooting module is assembled inside the thermal image shell (101), and the solar receiving module (102) absorbs solar energy to supply power for the thermal image shooting module.

2. A solar-shield-based monitoring 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).

3. A solar-shield-based monitoring apparatus according to claim 1, wherein: the shroud housing (106) may be configured in a polyhedral structure, a cambered surface structure, a bridge-type structure, a polyhedral column-type or a spherical structure.

4. A solar-shield-based monitoring apparatus according to claim 1, wherein: the solar energy receiving module (102) is set to be a solar panel or a solar film, and the shield shell (106) is a substrate of the solar energy receiving module (102).

5. A solar-shield-based monitoring apparatus according to claim 4, wherein: the shape of the solar receiving module (102) is matched with that of the shield shell (106), and the solar receiving module (102) is arranged on two or more planes or curved surfaces of the polyhedral structure of the shield shell (106).

6. A solar-shield-based monitoring apparatus according to claim 1, wherein: the solar energy receiving module is characterized in that two sides of the shield shell (106) are designed to be inwards inclined, the solar energy receiving module (102) is arranged on the shield shell (106), the included angle between the solar energy receiving module and the upper side of the shield shell (106) is smaller than 90 degrees, and the included angle between the solar energy receiving module and the lower side of the shield shell (106) is larger than 90 degrees.

7. A solar-shield-based monitoring apparatus according to claim 1, wherein: the protective cover shell (106) is of a bridge-type structure, the thermal image shell (101) is integrally covered by the protective cover shell (106), the solar receiving modules (102) are arranged on the outer side of the protective cover shell (106), and the width of the upper side of the protective cover shell (106) slightly exceeds the edge parts of the solar receiving modules (102) arranged on the left side and the right side of the protective cover shell (106), so that the solar receiving modules (102) on the left side and the right side are covered.

8. A solar-shield-based monitoring apparatus according to claim 1, wherein: a rotating mechanism can be arranged in the thermal image shell (101), and the rotating mechanism is connected with an external mechanism.

9. A solar-shield-based monitoring 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).

10. A solar-shield-based monitoring apparatus according to claim 9, wherein: when 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 one of the two bins.

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