CN216700822U

CN216700822U - Multifunctional electronic radiator structure

Info

Publication number: CN216700822U
Application number: CN202220080788.1U
Authority: CN
Inventors: 陶勇
Original assignee: Jiangsu Haiding Electrical Technology Co ltd
Current assignee: Jiangsu Haiding Electrical Technology Co ltd
Priority date: 2022-01-13
Filing date: 2022-01-13
Publication date: 2022-06-07
Anticipated expiration: 2032-01-13

Abstract

A multifunctional electronic radiator structure comprises a radiating panel, radiating strips, a tracking radiating dust removal device and a position adjusting assembly; the tracking heat dissipation dust removal device and the position adjusting assembly are additionally arranged, so that dust on the heat dissipation plate strips can be quickly removed, the heat dissipation position can be adjusted, and the heat of a heating area can be dissipated in a targeted manner.

Description

Multifunctional electronic radiator structure

Technical Field

The utility model relates to an electronic radiator structure with multiple functions.

Background

The heat radiator is equipment for radiating and cooling a running machine, the machine can generate a large amount of heat during running, if the machine is not timely cooled, the machine can be damaged, the machine cannot work normally, and meanwhile, the continuous high temperature has potential safety hazards, so the heat radiator is required to timely radiate and cool the running machine; however, the existing radiator is not convenient to clean, dust can be generated to be attached to the radiating strips when the radiator works for a long time, if the dust is not processed in time, the radiating effect of the radiator can be influenced, the running machine cannot be effectively radiated, and in addition, the specific radiating needs to be carried out under the condition of overhigh local temperature.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model solves the problems that: the multifunctional electronic radiator structure can periodically clean attached dust and radiate heat locally in a targeted manner.

In order to solve the problems, the technical scheme adopted by the utility model is as follows:

a multifunctional electronic radiator structure comprises a radiating panel, radiating strips and a tracking radiating dust removal device; a plurality of radiating strips are uniformly arranged at the upper end of one side of the radiating panel; the plurality of radiating strips are uniformly distributed at equal intervals; the tracking heat dissipation dust removal device is arranged at the lower end of one side of the heat dissipation panel and is positioned at the lower ends of the plurality of heat dissipation plate strips; the tracking heat dissipation dust removal device comprises a positioning plate bar, a driving rod, a tracking block, an induced draft blade, an induced draft cover, a communicating pipeline, a transverse connecting pipe, a telescopic pipe and a dust removal box body; a positioning lath is arranged at the lower end of one side of the heat dissipation panel; the upper end of the positioning lath is slidably clamped with a tracking block; the driving rod is rotatably clamped and mounted on the positioning lath and drives the tracking block to slide on the positioning lath; the upper end of the tracking block is provided with a transverse connecting pipe; the outer end of the transverse connecting pipe is provided with a telescopic pipe; the outer end of the extension tube is connected with the dust removal box body; the dust removal box body is fixedly arranged on one side of the lower end of the heat dissipation panel; the upper end of the transverse connecting pipe is provided with an induced draft cover; an air inducing blade is arranged in the air inducing cover; two sides of the lower end of the induced draft cover are respectively provided with a communicating pipeline in a through way, and the lower end of the communicating pipeline is communicated with the transverse connecting pipe; the air inducing blades move under the plurality of radiating strips to absorb dust and induce air to dissipate heat.

Further, the device also comprises a position adjusting component; the position adjusting assembly comprises a limiting lath, a positioning block, an adjusting screw rod and a driving rod; the limiting plate strip is arranged at the upper end of the heat dissipation panel; the lower ends of the limiting battens are evenly clamped and connected with a plurality of radiating battens in a sliding and clamping manner; two positioning blocks are respectively arranged at the two ends of the middle of the heat dissipation panel; one end of the adjusting screw rod is rotatably clamped on the positioning block, and the other end of the adjusting screw rod is connected with one end of the driving rod; the other end of the driving rod is rotationally clamped on the positioning block; the adjusting screw rods are respectively screwed with a plurality of radiating strips in sequence; the inner side of the radiating plate strip is abutted against the plate surface of the radiating panel.

Further, the lower end of the limiting lath is provided with a transverse sliding chute; the upper end of the radiating plate strip is provided with a transverse sliding rod; the transverse sliding rod is connected to the transverse sliding groove in a sliding and clamping mode.

Furthermore, a temperature sensor is respectively arranged on the radiating plate strips.

Further, the device also comprises a control mechanism; the control mechanism comprises a reciprocating drive motor, a controller and a storage battery; one end of the driving rod extends to the outer side of one end of the positioning lath; a reciprocating driving motor, a controller and a storage battery are arranged on one side of the bottom of the heat dissipation panel; the reciprocating driving motor is connected to one end of the driving rod; the reciprocating driving motor is connected with the controller and the storage battery; the temperature sensor is electrically connected with the controller.

Furthermore, a clamping sliding groove is formed in the positioning lath; the lower end of the tracking block is slidably clamped on the clamping sliding chute; the driving rod is connected to the clamping sliding chute in a penetrating mode, and two ends of the driving rod are respectively clamped to two ends of the clamping sliding chute in a rotating mode; and external threads are arranged on the outer side of the periphery of the driving rod, and the driving rod is in threaded connection with the tracking block.

Further, an induced draft motor is arranged in the middle of the inside of the induced draft cover; the upper end of the induced draft motor is provided with an induced draft rotating shaft; and air-inducing blades are arranged around the upper end of the air-inducing rotating shaft.

Further, the radiating plate strips are made of an aluminum alloy material.

The utility model has the following beneficial effects:

the tracking heat dissipation dust removal device is additionally arranged, the tracking block is driven by the driving rod to slide on the positioning plate strips, so that the transverse connecting pipe is driven to transversely move, the telescopic pipe is synchronously extended and shortened, the air inducing blades and the air inducing cover are driven to transversely move, so that the plurality of heat dissipation plate strips are sequentially sucked with dust, the sucked dust enters the guide pipeline through the air inducing cover, enters the transverse connecting pipe from the guide pipeline, then enters the telescopic pipe, finally enters the dust removal box body, and the dust collection is realized.

According to the utility model, each radiating plate strip is respectively provided with a temperature sensor for detecting the temperature, when the temperature is too high, the tracking block can be driven by the driving rod to slide on the positioning plate strip, and then the induced air blade and the induced air cover are driven to move to the radiating plate strip with the too high temperature for induced air and radiating; the temperature sensor can be monitored in real time through the controller, when the temperature is too high, the controller sends a driving signal to the reciprocating driving motor, so that the reciprocating driving motor drives the driving rod to rotate, and the induced air blades and the induced air cover move to the radiating plate strips with the too high temperature to induce air and dissipate heat.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the tracking heat dissipation dust removal device of the present invention.

Fig. 3 is a partially enlarged structural view of fig. 2 according to the present invention.

Fig. 4 is a schematic structural diagram of the control mechanism of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 4, an electronic heat sink structure with multiple functions comprises a heat dissipation panel 1, heat dissipation slats 2, and a tracking heat dissipation dust removal device 3; a plurality of radiating strips 2 are uniformly arranged at the upper end of one side of the radiating panel 1; the plurality of radiating strips 2 are uniformly distributed at equal intervals; the tracking heat dissipation dust removal device 3 is arranged at the lower end of one side of the heat dissipation panel 1, and the tracking heat dissipation dust removal device 3 is positioned at the lower ends of the plurality of heat dissipation plate strips 2; the tracking heat dissipation dust removal device 3 comprises a positioning lath 32, a driving rod 31, a tracking block 33, an induced draft blade 38, an induced draft cover 37, a conduction pipeline 39, a transverse connection pipe 34, an extension pipe 35 and a dust removal box body 36; a positioning lath 32 is arranged at the lower end of one side of the heat dissipation panel 1; a tracking block 33 is slidably clamped and mounted at the upper end of the positioning lath 32; the driving rod 31 is rotatably clamped on the positioning lath 32 and drives the tracking block 33 to slide on the positioning lath 32; a transverse connecting pipe 34 is arranged at the upper end of the tracking block 33; an extension tube 35 is arranged at the outer end of the transverse connecting tube 34; the outer end of the extension tube 35 is connected with a dust removal box body 36; the dust removal box body 36 is fixedly arranged on one side of the lower end of the heat dissipation panel 1; an induced draft cover 37 is arranged at the upper end of the transverse connecting pipe 34; an air inducing blade 38 is arranged in the air inducing cover 37; two sides of the lower end of the induced draft cover 37 are respectively provided with a conduction pipeline 39 in a penetrating way, and the lower end of the conduction pipeline 39 is communicated with the transverse connecting pipe 34; the air inducing blades 38 move under the plurality of radiating strips 2 to absorb dust and induce air to dissipate heat.

As shown in fig. 1 to 4, it is further preferable that, in order to adjust the positions of the respective heat dissipating slats 2 simultaneously, and improve the flexibility of use, a position adjusting assembly 4 is further included; the position adjusting assembly 4 comprises a limiting strip 44, a positioning block 41, an adjusting screw 43 and a driving rod 42; the limiting strip 44 is arranged at the upper end of the heat dissipation panel 1; the lower ends of the limiting strips 44 are uniformly clamped with a plurality of radiating strips 2 in a sliding manner; two positioning blocks 41 are respectively arranged at the two ends of the middle of the heat dissipation panel 1; one end of the adjusting screw 43 is rotatably clamped on the positioning block 41, and the other end of the adjusting screw 43 is connected with one end of the driving rod 42; the other end of the driving rod 42 is rotatably clamped on the positioning block 41; a plurality of radiating strips 2 are screwed on the adjusting screw rods 43 in sequence; the inner side of the radiating strip 2 is abutted against the plate surface of the radiating panel 1. Further preferably, the lower end of the limiting lath 44 is provided with a transverse sliding 441 groove; the upper end of the radiating plate strip 2 is provided with a transverse sliding rod 21; the transverse sliding rod 21 is slidably clamped on the transverse sliding groove 441. Further, a temperature sensor is respectively arranged on the radiating plate strips. Further preferably, the device also comprises a control mechanism 5; the control mechanism 5 comprises a reciprocating drive motor 51, a controller 53 and a storage battery 52; one end of the driving rod 31 extends to the outside of one end of the positioning lath 32; a reciprocating driving motor 51, a controller 53 and a storage battery 52 are arranged on one side of the bottom of the heat dissipation panel 1; the reciprocating driving motor 51 is connected to one end of the driving rod 31; the reciprocating driving motor 51 is connected with a controller 53 and a storage battery 52; the temperature sensor is electrically connected to the controller 53. Further, a clamping sliding groove 321 is arranged on the positioning lath 32; the lower end of the tracking block 33 is slidably clamped on the clamping sliding groove 321; the driving rod 31 is connected to the clamping sliding groove 321 in a penetrating manner, and two ends of the driving rod 31 are respectively and rotatably clamped to two ends of the clamping sliding groove 321; and external threads are arranged on the outer side of the periphery of the driving rod 31, and the driving rod 31 is screwed on the tracking block 33. Further, an induced air motor 371 is arranged in the middle of the inside of the induced air cover 37; an induced air rotating shaft 372 is arranged at the upper end of the induced air motor 371; and the upper end of the induced air rotating shaft 372 is provided with induced air blades 38 all around. Further, the radiating fins 2 are made of an aluminum alloy material.

The tracking heat-dissipation dust removal device 3 is additionally arranged, the driving rod 31 drives the tracking block 33 to slide on the positioning plate 32, so that the transverse connecting pipe 34 is driven to transversely move, the extension pipe 35 is synchronously extended and shortened, the air-inducing blades 38 and the air-inducing cover 37 are driven to transversely move, the plurality of heat-dissipation plate strips 2 are sequentially sucked with dust, the sucked dust enters the guide pipeline 39 through the air-inducing cover 37, enters the transverse connecting pipe 34 from the guide pipeline 39, then enters the extension pipe 35 and finally enters the dust removal box body 36, and dust collection is achieved.

According to the utility model, each radiating slat 2 is respectively provided with a temperature sensor for detecting temperature, when the temperature is too high, the driving rod 31 can drive the tracking block 33 to slide on the positioning slat 32, and further drive the induced draft blades 38 and the induced draft cover 37 to move to the radiating slat 2 with the too high temperature for induced draft and heat dissipation; the temperature sensor can be monitored in real time through the controller 53, and when the temperature is too high, the controller 53 sends a driving signal to the reciprocating driving motor 51, so that the reciprocating driving motor 51 drives the driving rod 31 to rotate, and the induced air blade 38 and the induced air cover 37 move to the heat dissipation lath 2 with the too high temperature for induced air and heat dissipation.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A multifunctional electronic radiator structure is characterized by comprising a radiating panel, radiating battens, a tracking radiating dust removal device and a position adjusting assembly; a plurality of radiating strips are uniformly arranged at the upper end of one side of the radiating panel; the plurality of radiating strips are uniformly distributed at equal intervals; the tracking heat dissipation dust removal device is arranged at the lower end of one side of the heat dissipation panel, and the tracking heat dissipation dust removal device is positioned at the lower ends of the plurality of heat dissipation plate strips; the tracking heat dissipation dust removal device comprises a positioning plate bar, a driving rod, a tracking block, an induced draft blade, an induced draft cover, a communicating pipeline, a transverse connecting pipe, a telescopic pipe and a dust removal box body; a positioning lath is arranged at the lower end of one side of the heat dissipation panel; the upper end of the positioning lath is slidably clamped with a tracking block; the driving rod is rotatably clamped and mounted on the positioning lath and drives the tracking block to slide on the positioning lath; the upper end of the tracking block is provided with a transverse connecting pipe; the outer end of the transverse connecting pipe is provided with a telescopic pipe; the outer end of the extension tube is connected with the dust removal box body; the dust removal box body is fixedly arranged on one side of the lower end of the heat dissipation panel; the upper end of the transverse connecting pipe is provided with an induced draft cover; an air inducing blade is arranged in the air inducing cover; two sides of the lower end of the induced draft cover are respectively provided with a communicating pipeline in a through way, and the lower end of the communicating pipeline is communicated with the transverse connecting pipe; the air inducing blades move below the plurality of radiating strips to absorb dust and induce air to dissipate heat; the position adjusting component comprises a limiting lath, a positioning block, an adjusting screw and a driving rod; the limiting plate strip is arranged at the upper end of the heat dissipation panel; the lower ends of the limiting battens are evenly clamped and connected with a plurality of radiating battens in a sliding and clamping manner; two positioning blocks are respectively arranged at the two ends of the middle of the heat dissipation panel; one end of the adjusting screw rod is rotatably clamped on the positioning block, and the other end of the adjusting screw rod is connected with one end of the driving rod; the other end of the driving rod is rotationally clamped on the positioning block; the adjusting screw rods are respectively screwed with a plurality of radiating strips in sequence; the inner side of the radiating plate strip is abutted against the plate surface of the radiating panel; and the radiating plate strips are respectively provided with a temperature sensor.

2. The multifunctional electronic heat sink structure as recited in claim 1, wherein the lower end of the position-limiting lath is provided with a transverse sliding groove; the upper end of the radiating plate strip is provided with a transverse sliding rod; the transverse sliding rod is connected to the transverse sliding groove in a sliding and clamping mode.

3. The multifunctional electronic heat sink structure according to claim 1, further comprising a control mechanism; the control mechanism comprises a reciprocating drive motor, a controller and a storage battery; one end of the driving rod extends to the outer side of one end of the positioning lath; a reciprocating driving motor, a controller and a storage battery are arranged on one side of the bottom of the heat dissipation panel; the reciprocating driving motor is connected to one end of the driving rod; the reciprocating driving motor is connected with the controller and the storage battery; the temperature sensor is electrically connected with the controller.

4. The multifunctional electronic radiator structure of claim 1, wherein said positioning lathes are provided with clamping sliding grooves; the lower end of the tracking block is slidably clamped on the clamping sliding chute; the driving rod is connected to the clamping sliding chute in a penetrating mode, and two ends of the driving rod are respectively clamped to two ends of the clamping sliding chute in a rotating mode; and external threads are arranged on the outer side of the periphery of the driving rod, and the driving rod is in threaded connection with the tracking block.

5. The multifunctional electronic heat sink structure as recited in claim 1, wherein an air inducing motor is provided in the middle of the inside of the air inducing cover; the upper end of the induced draft motor is provided with an induced draft rotating shaft; and air-inducing blades are arranged around the upper end of the air-inducing rotating shaft.

6. The multifunctional electronic heat sink structure of claim 1, wherein the heat sink fins are made of an aluminum alloy material.