CN219876655U - Heat radiation structure of ultraviolet imager - Google Patents

Abstract

The utility model discloses a heat radiation structure of an ultraviolet imager, and belongs to the technical field of ultraviolet imagers. The utility model provides a heat radiation structure of ultraviolet imager, includes ultraviolet imager, display screen and second handle, and the display screen sets up in one side of ultraviolet imager, and the second handle sets up in the bottom of ultraviolet imager, and the both sides of ultraviolet imager correspond and are provided with two otter boards, and the motor is all installed to the inner wall of otter board, and the fan body is all installed to the output of motor, and the top of otter board all swing joint has trapezoidal piece. This heat radiation structure of ultraviolet imager produces the wind of convection current through two fan bodies and makes the circulation of air in the ultraviolet imager faster, realizes the quick cooling of ultraviolet imager for the inside components and parts of ultraviolet imager can keep running in good environment, has increased the life of the inside components and parts of ultraviolet imager, promotes first handle and makes movable rod drive fly leaf activity, makes the lens end of baffle with the ultraviolet imager shelter from, realizes the protection of the lens end of ultraviolet imager.

Description

Heat radiation structure of ultraviolet imager

Technical Field

The utility model relates to the technical field of ultraviolet imagers, in particular to a heat radiation structure of an ultraviolet imager.

Background

Ultraviolet imagers refer to corona discharge, which is a localized discharge phenomenon that occurs when the local voltage stress of a charged body exceeds a critical value, causing air to be dissociated. In particular high voltage power equipment, which often produces corona, flashover or arcing due to poor design, manufacturing, installation and maintenance work. In the discharge process, electrons in the air continuously acquire and release energy, and when the electrons release energy (namely discharge), ultraviolet rays are released, a high-sensitivity ultraviolet radiation receiver is adopted to record ultraviolet rays radiated in the corona and surface discharge processes, and then the ultraviolet rays are processed and analyzed to achieve the purpose of evaluating equipment conditions. Preventing and reducing the serious loss caused by equipment failure, and has great economic benefit.

The ultraviolet imager often needs to last long time when using, therefore the ultraviolet imager sets up solitary cooling mechanism and dispels the heat, current cooling mechanism is only through the heat dissipation of blowing to the inside components and parts of ultraviolet imager, lead to the inside some positions of ultraviolet imager can't be fine by blowing, cause the radiating effect relatively poor, in addition cooling mechanism makes the inside air of ultraviolet imager exchange with outside air can make fan surface attached with a lot of dust, consequently need often clean in order to guarantee the safety of the inside components and parts of ultraviolet imager, current cooling mechanism and ultraviolet imager fixed mounting, dismantle inconvenient, lead to the cleanness inconvenient.

Disclosure of Invention

1. Technical problem to be solved

The utility model aims to provide a heat dissipation structure of an ultraviolet imager, which solves the problems in the prior art:

the ultraviolet imager often needs to last long time when using, therefore the ultraviolet imager sets up solitary cooling mechanism and dispels the heat, current cooling mechanism is only through the heat dissipation of blowing to the inside components and parts of ultraviolet imager, lead to the inside some positions of ultraviolet imager can't be fine by blowing, cause the radiating effect relatively poor, in addition cooling mechanism makes the inside air of ultraviolet imager exchange with outside air can make fan surface attached with a lot of dust, consequently need often clean in order to guarantee the safety of the inside components and parts of ultraviolet imager, current cooling mechanism and ultraviolet imager fixed mounting, dismantle inconvenient, lead to the cleanness inconvenient.

2. Technical proposal

The utility model provides a heat radiation structure of ultraviolet imager, includes ultraviolet imager, display screen and second handle, the display screen sets up in one side of ultraviolet imager, the second handle sets up in the bottom of ultraviolet imager, the both sides of ultraviolet imager correspond and are provided with two otter boards, the motor is all installed to the inner wall of otter board, the fan body is all installed to the output of motor, the equal swing joint in top of otter board has trapezoidal piece, the top of otter board all is provided with the movable groove, the inside in movable groove all is provided with the spring, the tip of spring all is provided with trapezoidal piece, the top of ultraviolet imager is provided with the bayonet socket with trapezoidal piece assorted.

Preferably, ventilation grooves matched with the screen plates are formed in two sides of the ultraviolet imager, and the screen plates are arranged on the inner walls of the ventilation grooves.

Preferably, the inner wall of the movable groove is provided with a sliding groove, the side surface of the trapezoid block is provided with a sliding block matched with the sliding groove, and the trapezoid block is in sliding connection with the inner wall of the movable groove through the sliding block arranged in the sliding groove.

Preferably, the end of the ultraviolet imager is provided with a mounting frame, the top of the mounting frame is provided with a U-shaped frame, the inside of the U-shaped frame is movably connected with a movable plate, and the end of the movable plate is provided with a baffle.

Preferably, a movable rod connected with the movable plate is movably connected in the U-shaped frame, and a first handle is arranged at the outer end of the movable rod.

Preferably, the outer surface of the first handle is coated with a rubber sleeve.

3. Advantageous effects

Compared with the prior art, the utility model has the advantages that:

1) When the radiating structure of the ultraviolet imager is used, the two motors are rotated to drive the two fans to generate convection wind, the circulation of gas inside the ultraviolet imager is accelerated, the cooling of the ultraviolet imager is realized, when the motors and the fans are required to be cleaned or maintained, the trapezoidal blocks are only required to be pressed, the trapezoidal blocks can be separated from the bayonets to take down the screen, the scheme ensures that the air circulation in the ultraviolet imager is faster by the convection wind generated by the two fans, the rapid cooling of the ultraviolet imager is realized, the internal components of the ultraviolet imager can be kept to operate in a good environment, and the service life of the internal components of the ultraviolet imager is prolonged.

2) When the radiating structure of the ultraviolet imager is used, when the ultraviolet imager is not applicable, the movable rod is driven to move by pushing the first handle, so that the lens end of the ultraviolet imager is shielded by the baffle plate, and the lens end of the ultraviolet imager is protected.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is an enlarged view of a portion of FIG. 1A;

FIG. 3 is a schematic diagram of a screen structure according to the present utility model;

fig. 4 is a partial enlarged view of B in fig. 3.

The reference numerals in the figures illustrate: 1. an ultraviolet imager; 2. a display screen; 3. a screen plate; 4. a bayonet; 5. a U-shaped frame; 6. a movable plate; 7. a baffle; 8. a movable rod; 9. a first handle; 10. a motor; 11. a fan body; 12. a movable groove; 13. a spring; 14. a chute; 15. a slide block; 16. a second handle; 17. a mounting frame; 18. trapezoidal blocks.

Detailed Description

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "configured to," "engaged with," "connected to," and the like are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

Example 1:

the ultraviolet imager often needs to last long time when using, therefore the ultraviolet imager sets up solitary cooling mechanism and dispels the heat, current cooling mechanism carries out the heat dissipation of blowing to the inside components and parts of ultraviolet imager through solitary fan alone, lead to some inside parts of ultraviolet imager can't be fine by blowing, cause the radiating effect relatively poor, in addition cooling mechanism makes the inside air of ultraviolet imager exchange with outside air can make fan surface attached with a lot of dust, consequently, need often clean in order to guarantee the safety of the inside components and parts of ultraviolet imager, current cooling mechanism and ultraviolet imager fixed mounting, dismantle inconveniently, lead to cleaning inconvenience, solve this problem through following scheme.

Referring to fig. 1 to 4, a heat radiation structure of an ultraviolet imager comprises an ultraviolet imager 1, a display screen 2 and a second handle 16, wherein the second handle 16 is used for a user to hold the ultraviolet imager 1, the display screen 2 is arranged on one side of the ultraviolet imager 1, the second handle 16 is arranged at the bottom of the ultraviolet imager 1, two sides of the ultraviolet imager 1 are correspondingly provided with two screen plates 3, the ultraviolet imager 1 is communicated with the outside through the screen plates 3, motors 10 are all arranged on the inner walls of the screen plates 3, fan bodies 11 are all arranged at the output ends of the motors 10, the motors 10 are conventional motors in the prior art, the motors 10 can drive the fan bodies 11 to rotate to generate wind energy, trapezoidal blocks 18 are all movably connected to the top of the screen plates 3, movable grooves 12 are all arranged at the top of the screen plates 3, springs 13 are arranged at the inner sides of the movable grooves, trapezoidal blocks 18 are all arranged at the ends of the springs 13, bayonets 4 matched with the trapezoidal blocks 18 are arranged at the top of the ultraviolet imager 1, the two motors 10 are rotated to drive the two fan bodies 11 to generate a convection current motor, the fan bodies 11 are further accelerated, the fan bodies 11 are driven to generate a convection current, the fan bodies 1 can be cooled down through the fan bodies, the fan bodies 1 can be more rapidly cooled down, and the fan bodies 1 can be cooled down, and the inside the ultraviolet imager 1 can be more rapidly cooled down, and the ultraviolet imager 1 can be more effectively cooled down, and the inside the ultraviolet imager 1 can be more effectively cooled, and the inside the ultraviolet imager 1 can be more easily, and cooled down, and the inside the ultraviolet imager 1 can be more effectively, and the device can be cooled by the device can be cooled.

As a further aspect of the utility model: the two sides of the ultraviolet imager 1 are provided with ventilation grooves matched with the screen plates 3, and the screen plates 3 are arranged on the inner walls of the ventilation grooves, so that the screen plates 3 are installed.

As a further aspect of the utility model: the inner wall of the movable groove 12 is provided with a sliding groove 14, the side surface of the trapezoid block 18 is provided with a sliding block 15 matched with the sliding groove 14, and the trapezoid block 18 is in sliding connection with the inner wall of the movable groove 12 through the sliding block 15 arranged in the sliding groove 14, so that the movement of the trapezoid block 18 is more stable.

The utility model comprises the following steps: this heat radiation structure of ultraviolet imager is when using, rotatory through two motors 10, and then drive two fan bodies 11 and produce the wind of convection current, accelerate the circulation of the inside gas of ultraviolet imager 1, and then realize the cooling of ultraviolet imager 1, when needs are clean or the maintenance to motor 10 and fan body 11, only need press trapezoidal piece 18, make trapezoidal piece 18 break away from bayonet socket 4 can take off otter board 3, this scheme produces the wind of convection current through two fan bodies 11 and makes the circulation of air in the ultraviolet imager 1 faster, realized the quick cooling of ultraviolet imager 1, make the inside components and parts of ultraviolet imager 1 can keep running in good environment, the life of the inside components and parts of ultraviolet imager 1 has been increased.

Example 2:

referring to fig. 1 to 4, the difference of the basis of the combination embodiment 1 is that the end of the ultraviolet imager 1 is provided with a mounting frame 17, the top of the mounting frame 17 is provided with a U-shaped frame 5, the inside of the U-shaped frame 5 is movably connected with a movable plate 6, the end of the movable plate 6 is provided with a baffle 7, the inside of the U-shaped frame 5 is movably connected with a movable rod 8 connected with the movable plate 6, the outer end of the movable rod 8 is provided with a first handle 9, the outer surface of the first handle 9 is coated with a rubber sleeve, the rubber sleeve enables an operator to hold more comfortably, and when the ultraviolet imager is not applicable, only the first handle 9 is required to be pushed to enable the movable rod 8 to drive the movable plate 6 to move, and then the baffle 7 shields the lens end of the ultraviolet imager 1, thereby protecting the lens end of the ultraviolet imager 1.

The utility model comprises the following steps: when the radiating structure of the ultraviolet imager is used, when the ultraviolet imager is not applicable, the first handle 9 is pushed only to enable the movable rod 8 to drive the movable plate 6 to move, and then the baffle 7 shields the lens end of the ultraviolet imager 1, so that the protection of the lens end of the ultraviolet imager 1 is realized.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a heat radiation structure of ultraviolet imager, includes ultraviolet imager (1), display screen (2) and second handle (16), display screen (2) set up in one side of ultraviolet imager (1), second handle (16) set up in the bottom of ultraviolet imager (1), its characterized in that: two sides of ultraviolet imager (1) are provided with two otter board (3) corresponding, motor (10) are all installed to the inner wall of otter board (3), fan (11) are all installed to the output of motor (10), the top of otter board (3) is all swing joint has trapezoidal piece (18), the top of otter board (3) all is provided with movable groove (12), the inside of movable groove (12) all is provided with spring (13), the tip of spring (13) all is provided with trapezoidal piece (18), the top of ultraviolet imager (1) is provided with bayonet socket (4) with trapezoidal piece (18) assorted.

2. The radiation structure of an ultraviolet imager as set forth in claim 1, wherein: the ultraviolet imaging device is characterized in that ventilation grooves matched with the screen plate (3) are formed in two sides of the ultraviolet imaging device (1), and the screen plate (3) is arranged on the inner wall of the ventilation grooves.

3. The radiation structure of an ultraviolet imager as set forth in claim 1, wherein: the inner wall of the movable groove (12) is provided with a sliding groove (14), the side surface of the trapezoid block (18) is provided with a sliding block (15) matched with the sliding groove (14), and the trapezoid block (18) is in sliding connection with the inner wall of the movable groove (12) through the sliding block (15) arranged in the sliding groove (14).

4. The radiation structure of an ultraviolet imager as set forth in claim 1, wherein: the end of ultraviolet imager (1) is provided with installing frame (17), the top of installing frame (17) is provided with U type frame (5), the inside swing joint of U type frame (5) has fly leaf (6), the end of fly leaf (6) is provided with baffle (7).

5. The radiation structure of an ultraviolet imager as set forth in claim 4, wherein: the U-shaped frame (5) is internally and movably connected with a movable rod (8) connected with the movable plate (6), and a first handle (9) is arranged at the outer end of the movable rod (8).

6. The radiation structure of an ultraviolet imager as set forth in claim 5, wherein: the outer surface of the first handle (9) is coated with a rubber sleeve.