CN111741629B - Unmanned aerial vehicle control platform heat dissipation protection equipment - Google Patents

Abstract

The invention relates to a heat dissipation device, in particular to a heat dissipation protection device for an unmanned aerial vehicle control platform, which comprises a shell mechanism, an adjustable supporting mechanism and a heat dissipation mechanism, wherein platforms with different sizes are installed on the device, the device can replace ventilation holes, the device can clean the ventilation holes, the device can guarantee positive pressure heat dissipation, the shell mechanism is connected with the adjustable supporting mechanism, the adjustable supporting mechanism is connected with the heat dissipation mechanism, and the heat dissipation mechanism is connected with the shell mechanism.

Description

Unmanned aerial vehicle control platform heat dissipation protection equipment

Technical Field

The invention relates to a heat dissipation device, in particular to a heat dissipation protection device for an unmanned aerial vehicle control platform.

Background

In unmanned aerial vehicle's control platform uses, it is very high to the stability requirement, because in case the platform goes wrong, a large amount of unmanned aerial vehicle lose control, and the loss is very heavy, and to the platform, service environment should dispel the heat well, and traditional platform often rotates through simple fan and realizes the heat dissipation, can not guarantee the steady operation of platform, so designed this kind of unmanned aerial vehicle control platform heat dissipation protective equipment.

Disclosure of Invention

The invention mainly solves the technical problem of providing the radiating protection equipment for the unmanned aerial vehicle control platform, the equipment is provided with platforms with different sizes, the equipment can replace ventilation holes, the equipment can clean the ventilation holes, and the equipment can ensure positive pressure radiating.

In order to solve the technical problem, the invention relates to a heat dissipation device, in particular to a heat dissipation protection device for an unmanned aerial vehicle control platform.

The machine shell mechanism is connected with the adjustable supporting mechanism, the adjustable supporting mechanism is connected with the heat dissipation mechanism, and the heat dissipation mechanism is connected with the machine shell mechanism.

As a further optimization of the technical scheme, the housing mechanism of the heat dissipation protection device for the unmanned aerial vehicle control platform comprises a groove seat with a triangular cross section, a triangular interface limiting block, a sliding rod, a spring, a sliding hole, a fixed seat, a connecting plate with a handle, an outer shell, a platform with a support leg, a stepped groove, a rack with a stepped slider, a bearing seat, a rack with a stepped slider, a threaded hole, a lead screw, a coupler, a servo motor, a sliding groove I, a plate seat with a rack, a gear with a shaft, a stepped driving rod, a drawing box and an inner shell, wherein the groove seat with the triangular cross section is in sliding connection with the triangular interface limiting block, the triangular interface limiting block is symmetrically connected with two sliding rods, the spring is sleeved on the sliding rod, the spring abuts against the triangular interface limiting block and the fixed seat, the sliding hole is arranged on the fixed seat, the sliding rod is in sliding connection with the sliding hole, the connecting plate with the handle is connected with the sliding rod, and the connecting plate with the fixed seat, the fixed seat is connected with the outer shell, the outer shell is connected with the platform with the supporting legs, the stepped groove is symmetrically arranged on the platform with the supporting legs, the rack with the stepped slider is connected with the stepped groove in a sliding manner, the bearing seat is connected with the platform with the supporting legs, the rack A with the stepped slider is connected with the stepped groove in a sliding manner, the rack A with the stepped slider is provided with a threaded hole, the threaded hole is connected with a lead screw in a threaded manner, the lead screw is connected with the platform with the supporting legs in a bearing manner, the lead screw is connected with a servo motor through a coupler, the sliding chutes I are symmetrically arranged on two sides of the platform with the supporting legs, the rack with the stepped slider and the rack A are respectively provided with a rack plate seat, the rack plate seat with the sliding chute I is connected in a sliding manner, the rack plate seat is meshed with a shaft gear, the shaft gear is connected with a stepped driving rod, the drawing box is connected with the groove seat with a triangular section, the drawing box is connected with the outer shell in a sliding manner, the outer shell is connected with the inner shell, and is connected with the drawing box in a sliding manner, the connection mode of the gear with the shaft and the platform with the supporting legs is bearing connection.

As a further optimization of the technical scheme, the adjustable support mechanism of the heat dissipation protection device for the unmanned aerial vehicle control platform comprises a slide rod I, a belt groove driving seat, a support with holes, a connecting seat I, a support platform, a slide valve groove, a pressing seat, a step limiting rod, a spring I, a seat with a cleaning rod, a cleaning hole, a screw rod with a twisting head, a support clamping seat, a limiting matching hole, a one-way valve, an air outlet, a ventilation channel, a bearing seat I, a ventilation hole, a step rod A, a clamping spring and a threaded hole A, wherein the slide rod I is arranged on two sides of the belt groove driving seat, the slide rod I is in sliding connection with the support with holes, the support with holes is connected with the support platform, the support platform is connected with a shell, the slide rod I is connected with the connecting seat I, the connecting seat I is connected with the slide valve, the slide valve groove is arranged on the support platform, the lower pressing seat is provided with a limiting matching hole which is connected with a stepped limiting rod in a sliding manner, a spring I is sleeved on the stepped limiting rod, the spring I is abutted against the lower pressing seat and a supporting platform, a belt cleaning rod seat is symmetrically connected on the lower pressing seat and is connected with a cleaning opening in a sliding manner, the cleaning opening is arranged on the supporting platform, a screw rod with a twisting head is in threaded connection with a threaded hole A, the threaded hole A is arranged on the supporting platform, a supporting clamping seat is connected with a stepped rod A, the stepped rod A is in sliding connection with the stepped hole, the stepped hole is arranged on the supporting platform, a clamping spring is sleeved on the stepped rod A, the clamping spring is abutted against the supporting platform and the stepped rod A, a one-way valve is arranged in an air outlet, the air outlet is communicated with a ventilation channel, the ventilation channel is arranged on the supporting platform, a bearing seat I is arranged on the supporting platform, the ventilation opening is arranged on a sliding valve, and the ventilation channel is communicated with a ventilation opening at the middle position, the ventilation openings on the two sides are concentric with the cleaning opening respectively, the screws with the screwing heads on the two sides of the supporting platform are meshed with the rack with the stepped sliding block and the rack A with the stepped sliding block respectively, and the stepped driving rods 1-21 are connected with the driving seat 2-2 with the belt groove in a sliding mode.

As a further optimization of the technical scheme, the heat dissipation mechanism of the heat dissipation protection device for the unmanned aerial vehicle control platform of the invention comprises a wind wheel driving motor, a coupling a, a wind wheel shaft, a wind box, a bending pipe, a wind hole, a wind pipe outlet and a wind wheel, wherein the wind wheel driving motor is connected with a shell, the wind wheel driving motor is connected with the coupling a, the coupling a is connected with the wind wheel shaft, the wind wheel shaft is connected with a bearing seat in a bearing manner, the wind wheel shaft is connected with a bearing seat I in a bearing manner, the wind wheel shaft is connected with the wind box in a bearing manner, the wind box is connected with a support platform, the wind box is connected with the bending pipe and communicated with the bending pipe, the bending pipe is provided with the wind hole, the bending pipe is provided with the wind pipe outlet, the wind pipe outlet is communicated with a ventilation channel, the bending pipe is connected with the support platform, and the wind wheel is connected with the wind wheel shaft.

As a further optimization of the technical scheme, the bent pipe of the unmanned aerial vehicle control platform heat dissipation protection device is made of stainless steel.

The heat dissipation protection equipment for the unmanned aerial vehicle control platform has the beneficial effects that:

according to the heat dissipation protection equipment for the unmanned aerial vehicle control platform, the equipment is provided with the platforms with different sizes, the ventilation holes can be replaced by the equipment, the ventilation holes can be cleaned by the equipment, and the equipment can ensure positive pressure heat dissipation.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural diagram of a heat dissipation protection device of an unmanned aerial vehicle control platform according to the present invention.

Fig. 2 is a schematic structural diagram of a heat dissipation protection device of an unmanned aerial vehicle control platform according to the present invention.

Fig. 3 is a schematic structural diagram of a heat dissipation protection device of an unmanned aerial vehicle control platform according to the present invention.

Fig. 4 is a schematic structural diagram of a heat dissipation protection device of an unmanned aerial vehicle control platform according to the present invention.

Fig. 5 is a first structural schematic diagram of a housing mechanism 1 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 6 is a second schematic structural diagram of the housing mechanism 1 of the unmanned aerial vehicle control platform heat dissipation protection device of the present invention.

Fig. 7 is a third schematic structural diagram of the housing mechanism 1 of the unmanned aerial vehicle control platform heat dissipation protection device of the present invention.

Fig. 8 is a fourth schematic structural diagram of the housing mechanism 1 of the unmanned aerial vehicle control platform heat dissipation protection device of the present invention.

Fig. 9 is a fifth structural schematic diagram of the housing mechanism 1 of the unmanned aerial vehicle control platform heat dissipation protection device of the present invention.

Fig. 10 is a first schematic structural diagram of an adjustable support mechanism 2 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 11 is a second schematic structural diagram of an adjustable support mechanism 2 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 12 is a third schematic structural diagram of an adjustable support mechanism 2 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 13 is a fourth schematic structural view of the adjustable support mechanism 2 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 14 is a fifth structural schematic view of the adjustable support mechanism 2 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 15 is a first schematic structural diagram of a heat dissipation mechanism 3 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 16 is a second schematic structural diagram of a heat dissipation mechanism 3 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 17 is a third schematic structural diagram of a heat dissipation mechanism 3 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

Fig. 18 is a fourth schematic structural diagram of the heat dissipation mechanism 3 of the heat dissipation protection device for the unmanned aerial vehicle control platform of the present invention.

In the figure: a housing mechanism 1; a groove seat 1-1 with a triangular section; a triangular interface limiting block 1-2; 1-3 of a slide bar; 1-4 of a spring; 1-5 of a slide hole; fixing seats 1-6; 1-7 of a connecting plate with a handle; 1-8 parts of a shell; 1-9 of a platform with supporting legs; 1-10 parts of a stepped groove; a sliding block rack 1-11 with steps; 1-12 of a bearing seat; a slide block rack A1-13 with steps; threaded holes 1-14; 1-15 parts of a screw rod; 1-16 of a coupler; 1-17 of servo motor; chute I1-18; 1-19 of a plate base with a rack; 1-20 parts of a gear with a shaft; step driving rods 1-21; a pull box 1-22; inner shells 1-23; an adjustable support mechanism 2; a slide bar I2-1; a belt groove driving seat 2-2; 2-3 of a support with holes; connecting seat I2-4; 2-5 of a support platform; 2-6 of a slide valve; 2-7 of a sliding valve groove; 2-8 of a pressing seat; 2-9 parts of a stepped limiting rod; a spring I2-10; 2-11 parts of a cleaning rod seat; cleaning the open pores 2-12; 2-13 of screw with screw head; supporting clamping seats 2-14; 2-15 parts of limit matching holes; 2-16 parts of a one-way valve; 2-17 of air outlet; ventilation channels 2-18; bearing seats I2-19; 2-20 parts of ventilation opening; 2-21 parts of a stepped hole; step bar a 2-22; 2-23 parts of a clamping spring; a threaded hole A2-24; a heat dissipation mechanism 3; a wind wheel driving motor 3-1; a coupler A3-2; 3-3 of a wind wheel shaft; 3-4 of an air box; bending the pipe 3-5; 3-6 of air holes; 3-7 of an air pipe outlet; and 3-8 of wind wheels.

Detailed Description

The first embodiment is as follows:

the invention relates to a heat dissipation device, in particular to a heat dissipation protection device for an unmanned aerial vehicle control platform, which comprises a shell mechanism 1, an adjustable supporting mechanism 2 and a heat dissipation mechanism 3, wherein the shell mechanism is provided with platforms with different installation sizes, the device can replace ventilation holes, can clean the ventilation holes, and can ensure positive pressure heat dissipation.

The machine shell mechanism 1 is connected with the adjustable supporting mechanism 2, the adjustable supporting mechanism 2 is connected with the heat dissipation mechanism 3, and the heat dissipation mechanism 3 is connected with the machine shell mechanism 1.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the present embodiment further describes the present embodiment, where the casing mechanism 1 includes a groove seat 1-1 with a triangular cross section, a stopper 1-2 with a triangular interface, a slide rod 1-3, a spring 1-4, a slide hole 1-5, a fixed seat 1-6, a connecting plate 1-7 with a handle, a housing 1-8, a platform 1-9 with a support leg, a stepped groove 1-10, a sliding block rack 1-11 with a step, a bearing seat 1-12, a sliding block a1-13 with a step, a threaded hole 1-14, a lead screw 1-15, a coupling 1-16, a servo motor 1-17, a screw, and a screw rod, A sliding chute I1-18, a plate seat with a rack 1-19, a gear with a shaft 1-20, a ladder driving rod 1-21, a drawing box 1-22, an inner shell 1-23, a groove seat 1-1 with a triangular section and a triangular interface limiting block 1-2 which are connected in a sliding way, two sliding rods 1-3 are symmetrically connected on the triangular interface limiting block 1-2, a spring 1-4 is sleeved on the sliding rod 1-3, the spring 1-4 is abutted on the triangular interface limiting block 1-2 and a fixed seat 1-6, a sliding hole 1-5 is arranged on the fixed seat 1-6, the sliding rod 1-3 is connected with the sliding hole 1-5 in a sliding way, a connecting plate with a handle 1-7 is connected with the sliding rod 1-3, a connecting plate with a handle 1-7 is contacted with the fixed seat 1-6, and the fixed seat 1-6 is connected with an outer shell 1-8, the shell 1-8 is connected with the landing platform 1-9 with the landing legs, the stepped grooves 1-10 are symmetrically arranged on the landing platform 1-9 with the landing legs, the sliding block rack with the steps 1-11 is connected with the stepped grooves 1-10 in a sliding mode, the bearing seats 1-12 are connected with the landing platform 1-9 with the landing legs, the sliding block rack with the steps A1-13 is connected with the stepped grooves 1-10 in a sliding mode, the sliding block rack with the steps A1-13 is provided with threaded holes 1-14, the threaded holes 1-14 are connected with the lead screws 1-15 in a threaded mode, the lead screws 1-15 are connected with the landing platform 1-9 with the landing legs in a bearing mode, the lead screws 1-15 are connected with the servo motors 1-17 through the couplers 1-16, the sliding grooves I1-18 are symmetrically arranged on two sides of the landing platform 1-9 with the landing legs, and the sliding block racks with the steps 1-11, The racks A1-13 with the ladder sliders are respectively provided with a rack plate seat 1-19, the rack plate seats 1-19 with the racks are connected with the chutes I1-18 in a sliding manner, the rack plate seats 1-19 with the racks are meshed with the gears 1-20 with the shafts, the gears 1-20 with the shafts are connected with the ladder driving rods 1-21, the drawing boxes 1-22 are connected with the groove seats 1-1 with the triangular cross sections, the drawing boxes 1-22 are connected with the outer shells 1-8 in a sliding manner, the outer shells 1-8 are connected with the inner shells 1-23, the inner shells 1-23 are connected with the drawing boxes 1-22 in a sliding manner, and the gears 1-20 with the shafts are connected with the platforms 1-9 with the supporting legs in a bearing manner.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, and the embodiment further describes the embodiment, and the embodiment describes the first embodiment, and the adjustable support mechanism 2 includes a slide bar I2-1, a grooved drive seat 2-2, a perforated support 2-3, a connecting seat I2-4, a support platform 2-5, a slide valve 2-6, a slide valve groove 2-7, a press seat 2-8, a step limit rod 2-9, a spring I2-10, a belt cleaning rod seat 2-11, a cleaning opening 2-12, a belt screw with a screw head 2-13, a support clamping seat 2-14, a limit fitting hole 2-15, a check valve 2-16, an air outlet 2-17, fig, 2-18 parts of ventilation channel, 2-19 parts of bearing seat I2-19 parts, 2-20 parts of ventilation opening, 2-21 parts of stepped hole, 2-22 parts of stepped rod A2-22 parts, 2-23 parts of clamping spring, 26-24 parts of threaded hole A2-24 parts, 2-2 parts of slotted driving seat I2-1 parts, 2-3 parts of perforated support I2-1 parts, 2-3 parts of perforated support 2-5 parts of supporting platform 2-5 parts, 1-8 parts of supporting platform 2-5 parts of shell, 1 part of sliding rod I2-1 parts of connecting seat I2-4 parts, 2-6 parts of connecting seat I2-4 parts of sliding valve, 2-6 parts of sliding valve 2-7 parts of sliding valve groove 2-5 parts of supporting platform, 2-8 parts of lower pressing seat 2-8 parts of limiting matching hole 2-15 parts, the limiting matching holes 2-15 are connected with the step limiting rods 2-9 in a sliding mode, the springs I2-10 are sleeved on the step limiting rods 2-9, the springs I2-10 are abutted against the lower pressing seats 2-8 and the supporting platforms 2-5, the belt cleaning rod seats 2-11 are symmetrically connected on the lower pressing seats 2-8, the belt cleaning rod seats 2-11 are connected with the cleaning openings 2-12 in a sliding mode, the cleaning openings 2-12 are arranged on the supporting platforms 2-5, the screw rods 2-13 with screwing heads are in threaded connection with the threaded holes A2-24, the threaded holes A2-24 are arranged on the supporting platforms 2-5, the supporting clamping seats 2-14 are connected with the step rods A2-22, the step rods A2-22 are connected with the step holes 2-21 in a sliding mode, the step holes 2-21 are arranged on the supporting platforms 2-5, clamping springs 2-23 are sleeved on the step rods A2-22, the clamping springs 2-23 are abutted against a supporting platform 2-5 and the step rods A2-22, one-way valves 2-16 are arranged in air outlets 2-17, the air outlets 2-17 are communicated with ventilation channels 2-18, the ventilation channels 2-18 are arranged on the supporting platform 2-5, bearing seats I2-19 are arranged on the supporting platform 2-5, ventilation openings 2-20 are arranged on sliding valves 2-6, the ventilation channels 2-18 are communicated with ventilation openings 2-20 in the middle, the ventilation openings 2-20 on two sides are concentric with cleaning openings 2-12, screw rods 2-13 with screwing heads on two sides of the supporting platform 2-5 are respectively communicated with racks 1-11 with step sliders, The racks A1-13 with the stepped sliders are meshed, the stepped driving rods 1-21 are connected with the driving seats 2-2 with the grooves in a sliding mode, the couplers 1-16 are driven to rotate by operating the servo motors 1-17, the couplers 1-16 drive the lead screws 1-15 to rotate, the rotating direction is clockwise rotation seen from the couplers 1-16 to the lead screws 1-15, the lead screws 1-15 drive the racks A1-13 with the stepped sliders to move towards the couplers 1-16 through the matching of the threaded holes 1-14, the racks A1-13 with the stepped sliders drive the screws 2-13 with the screwing heads meshed with the racks A1-13 to rotate, the screws 2-13 with the screwing heads are driven to move by matching with the threaded holes A2-24, thus, the screw rod 2-13 with the screwing head can be jacked to support the clamping seat 2-14 to enable the supporting clamping seat 2-14 to move, meanwhile, the rack A1-13 with the stepped slider can move through the rack plate seat 1-19 with the stepped slider connected with the rack A1-13, the rack plate seat 1-19 with the rack can drive the gear 1-20 with the shaft to rotate, the gear 1-20 with the shaft can drive the rack 1-11 with the stepped slider to move through the rack plate seat 1-19 with the rack 1-11 with the stepped slider connected with the rack 1-11 with the stepped slider, the rack 1-11 with the stepped slider is opposite to the rack A1-13 with the stepped slider, the rack 1-11 with the stepped slider can drive the screw rod 2-13 with the stepped slider engaged with the stepped slider to rotate, the screw rod 2-13 with the screwing head can be jacked to the supporting clamping seat 2-14 at the side of the rack 1-11 with the stepped, therefore, the supporting clamping seats 2-14 on the two sides are close to each other, platforms with different sizes can be supported, the step driving rods 1-21 can be driven to rotate by the belt shaft gears 1-20 when the belt shaft gears rotate, the step driving rods 1-21 can drive the belt groove driving seats 2-2 to move, the belt groove driving seats 2-2 can drive the sliding valves 2-6 to move through the sliding rods I2-1 and the connecting seats I2-4, and the sliding valves 2-6 can drive the ventilation openings 2-20 to move, so that the different ventilation openings 2-20 are communicated with the ventilation channels 2-18.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the embodiment further describes the embodiment, where the heat dissipation mechanism 3 includes a wind wheel driving motor 3-1, a coupling A3-2, a wind wheel shaft 3-3, a wind box 3-4, a bending pipe 3-5, a wind hole 3-6, a wind pipe outlet 3-7, and a wind wheel 3-8, the wind wheel driving motor 3-1 is connected to a housing 1-8, the wind wheel driving motor 3-1 is connected to a coupling A3-2, a coupling A3-2 is connected to a wind wheel shaft 3-3, a connection manner of the wind wheel shaft 3-3 to a bearing seat 1-12 is a bearing connection, the connection mode of the wind wheel shaft 3-3 and the bearing seat I2-19 is bearing connection, the connection mode of the wind wheel shaft 3-3 and the wind box 3-4 is bearing connection, the wind box 3-4 is connected with the supporting platform 2-5, the wind box 3-4 is connected and communicated with the bending pipe 3-5, the bending pipe 3-5 is provided with a wind hole 3-6, the bending pipe 3-5 is provided with a wind pipe outlet 3-7, the wind pipe outlet 3-7 is communicated with the ventilation channel 2-18, the bending pipe 3-5 is connected with the supporting platform 2-5, the wind wheel 3-8 is connected with the wind wheel shaft 3-3, the wind wheel driving motor 3-1 operates to drive the coupling A3-2 to rotate, the coupling A3-2 drives the wind wheel 3-8 to rotate, the wind wheel 3-8 rotates to form wind towards the direction of the bending pipe 3-5, wind diffuses out from the wind holes 3-6, cools the console needing cooling and blows out dust, if the joint degree of the platform and the equipment is high, the wind enters from the ventilation channels 2-18 and then blows out by opening the one-way valves 2-16, and therefore the dust is prevented from entering the interior.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the first embodiment will be further described in the present embodiment, in which the material of the bent pipe 3-5 is stainless steel.

The working principle of the device is as follows: the equipment is provided with platforms with different sizes, a coupler 1-16 is driven to rotate by operating a servo motor 1-17, a lead screw 1-15 is driven to rotate by the coupler 1-16, the rotation direction is clockwise rotation seen from the coupler 1-16 to the lead screw 1-15, the lead screw 1-15 drives a rack A1-13 with a step slider to move towards the direction close to the coupler 1-16 by the matching of a threaded hole 1-14, the rack A1-13 with the step slider drives a screw 2-13 with a screwing head engaged with the rack A1-13 to rotate, the screw 2-13 with the screwing head drives the screw 2-13 with the screwing head to move by itself by the matching with a threaded hole A2-24, so that the screw 2-13 with the screwing head can be lifted to support a clamping seat 2-14, the supporting clamping seats 2 to 14 move, meanwhile, the stepped sliding block rack A1-13 moves through the rack plate seats 1 to 19 connected with the supporting clamping seats, the rack plate seats 1 to 19 drive the belt shaft gears 1 to 20 to rotate, the belt shaft gears 1 to 20 drive the stepped sliding block racks 1 to 11 to move through the rack plate seats 1 to 19 connected with the stepped sliding block racks 1 to 11, the directions of the stepped sliding block racks 1 to 11 and the stepped sliding block racks A1-13 are opposite, the stepped sliding block racks 1 to 11 drive the screw rods 2 to 13 engaged with the stepped sliding block racks to rotate, the screw rods 2 to 13 with the screwing heads are pushed to support the clamping seats 2 to 14 at one side of the stepped sliding block racks 1 to 11, so that the supporting clamping seats 2 to 14 at the two sides are close to each other, platforms of different sizes can be supported; the device can replace ventilation openings, the belt shaft gears 1-20 can drive the step driving rods 1-21 to rotate when rotating, the step driving rods 1-21 can drive the belt groove driving seats 2-2 to move when rotating, the belt groove driving seats 2-2 can drive the sliding valves 2-6 to move through the sliding rods I2-1 and the connecting seats I2-4, and the sliding valves 2-6 can drive the ventilation openings 2-20 to move, so that different ventilation openings 2-20 can be communicated with the ventilation channels 2-18; the device can clean the ventilation open pore, when the ventilation open pore 2-20 is blocked, the pressing seat 2-8 can be pressed downwards, the pressing seat 2-8 can drive the belt cleaning rod seat 2-11 to move downwards, the belt cleaning rod seat 2-11 can clean the sludge in the ventilation open pore 2-20 into the drawing box 1-22, when more garbage is in the drawing box 1-22, the connecting plate 1-7 with the handle can be pulled, the connecting plate 1-7 with the handle can drive the triangular interface limiting block 1-2 to move through the sliding rod 1-3, and when the triangular interface limiting block 1-2 is separated from the groove seat 1-1 with the triangular interface, the groove seat 1-1 with the triangular interface can be pulled out to clean the drawing box 1-22; the device can guarantee positive pressure heat dissipation, the shaft coupling A3-2 is driven to rotate through the operation of the wind wheel driving motor 3-1, the shaft coupling A3-2 can drive the wind wheel 3-8 to rotate, the wind wheel 3-8 rotates to form wind towards the direction of the bent pipe 3-5, the wind is diffused out of the wind hole 3-6, dust is blown out while the console needing cooling is cooled, if the laminating degree of the platform and the device is high, the wind can enter from the ventilation channel 2-18 and then blow out through the one-way valve 2-16, and therefore the dust is prevented from entering the interior.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (2)

1. The utility model provides an unmanned aerial vehicle control platform heat dissipation protection equipment, includes casing mechanism (1), adjustable supporting mechanism (2), heat dissipation mechanism (3), its characterized in that: the shell mechanism (1) comprises a groove seat (1-1) with a triangular section, a triangular interface limiting block (1-2), a sliding rod (1-3), a spring (1-4), a sliding hole (1-5), a fixing seat (1-6), a connecting plate (1-7) with a handle, a shell (1-8), a platform (1-9) with supporting legs, a step groove (1-10), a rack (1-11) with a step sliding block, a bearing seat (1-12), a rack A (1-13) with a step sliding block, a threaded hole (1-14), a lead screw (1-15), a coupler (1-16), a servo motor (1-17), a sliding groove I (1-18), a plate seat (1-19) with a rack, a gear (1-20) with a shaft, a step driving rod (1-21), A drawing box (1-22) and an inner shell (1-23), a groove seat (1-1) with a triangular section is connected with a triangular interface limiting block (1-2) in a sliding way, the triangular interface limiting block (1-2) is symmetrically connected with two sliding rods (1-3), a spring (1-4) is sleeved on the sliding rods (1-3), the spring (1-4) is propped against the triangular interface limiting block (1-2) and a fixed seat (1-6), a sliding hole (1-5) is arranged on the fixed seat (1-6), the sliding rods (1-3) are connected with the sliding holes (1-5) in a sliding way, a connecting plate (1-7) with a handle is connected with the sliding rods (1-3), the connecting plate (1-7) with the handle is contacted with the fixed seat (1-6), the fixed seat (1-6) is connected with an outer shell (1-8), the shell (1-8) is connected with a platform (1-9) with supporting legs, the stepped grooves (1-10) are symmetrically arranged on the platform (1-9) with supporting legs, the racks (1-11) with stepped sliders are slidably connected with the stepped grooves (1-10), the bearing seats (1-12) are connected with the platform (1-9) with supporting legs, the racks A (1-13) with stepped sliders are slidably connected with the stepped grooves (1-10), the racks A (1-13) with stepped sliders are provided with threaded holes (1-14), the threaded holes (1-14) are in threaded connection with the lead screws (1-15), the lead screws (1-15) are connected with the platform (1-9) with supporting legs in a bearing connection mode, the lead screws (1-15) are connected with the servo motors (1-17) through couplings (1-16), the sliding chutes I (1-18) are symmetrically arranged at two sides of a platform (1-9) with supporting legs, rack bars (1-11) with stepped sliders and rack bars A (1-13) with stepped sliders are respectively provided with a rack plate seat (1-19), the rack plate seats (1-19) with racks are in sliding connection with the sliding chutes I (1-18), the rack plate seats (1-19) with racks are meshed with shaft gears (1-20), the shaft gears (1-20) with shafts are connected with stepped driving rods (1-21), the drawing boxes (1-22) are connected with groove seats (1-1) with triangular cross sections, the drawing boxes (1-22) are in sliding connection with outer shells (1-8), the outer shells (1-8) are connected with inner shells (1-23), the inner shells (1-23) are in sliding connection with the drawing boxes (1-22), the connection mode of the gear (1-20) with the shaft and the platform (1-9) with the supporting leg is bearing connection;

the adjustable supporting mechanism (2) comprises a sliding rod I (2-1), a belt groove driving seat (2-2), a support with a belt hole (2-3), a connecting seat I (2-4), a supporting platform (2-5), a sliding valve (2-6), a sliding valve groove (2-7), a pressing seat (2-8), a step limiting rod (2-9), a spring I (2-10), a belt cleaning rod seat (2-11), a cleaning hole (2-12), a belt screwing head screw rod (2-13), a supporting clamping seat (2-14), a limiting matching hole (2-15), a one-way valve (2-16), an air outlet (2-17), a ventilation channel (2-18), a bearing seat I (2-19), a ventilation hole (2-20), a step hole (2-21), The step rod A (2-22), the clamping spring (2-23) and the threaded hole A (2-24), a sliding rod I (2-1) is arranged on two sides of a belt groove driving seat (2-2), the sliding rod I (2-1) is in sliding connection with a perforated support (2-3), the perforated support (2-3) is connected with a supporting platform (2-5), the supporting platform (2-5) is connected with a shell (1-8), the sliding rod I (2-1) is connected with a connecting seat I (2-4), the connecting seat I (2-4) is connected with a sliding valve (2-6), the sliding valve (2-6) is in sliding connection with a sliding valve groove (2-7), the sliding valve groove (2-7) is arranged on the supporting platform (2-5), a limit matching hole (2-15) is arranged on a lower pressing seat (2-8), the limiting matching holes (2-15) are connected with the step limiting rods (2-9) in a sliding manner, the springs I (2-10) are sleeved on the step limiting rods (2-9), the springs I (2-10) are abutted against the lower pressing seats (2-8) and the supporting platforms (2-5), the rod seats with cleaning rods (2-11) are symmetrically connected on the lower pressing seats (2-8), the rod seats with cleaning rods (2-11) are connected with the cleaning holes (2-12) in a sliding manner, the cleaning holes (2-12) are arranged on the supporting platforms (2-5), the screw rods (2-13) with screwing heads are connected with the threaded holes A (2-24) in a threaded manner, the threaded holes A (2-24) are arranged on the supporting platforms (2-5), the supporting clamping seats (2-14) are connected with the step rods A (2-22), the ladder rod A (2-22) is connected with the ladder hole (2-21) in a sliding mode, the ladder hole (2-21) is arranged on a supporting platform (2-5), a clamping spring (2-23) is sleeved on the ladder rod A (2-22), the clamping spring (2-23) abuts against the supporting platform (2-5) and the ladder rod A (2-22), a one-way valve (2-16) is arranged in an air outlet (2-17), the air outlet (2-17) is communicated with a ventilation channel (2-18), the ventilation channel (2-18) is arranged on the supporting platform (2-5), a bearing seat I (2-19) is arranged on the supporting platform (2-5), a ventilation opening hole (2-20) is arranged on a sliding valve (2-6), the ventilation channel (2-18) is communicated with the ventilation opening hole (2-20) in the middle position, the ventilation openings (2-20) on the two sides are concentric with the cleaning openings (2-12) respectively, the screw rods (2-13) with the twisting heads on the two sides of the supporting platform (2-5) are meshed with the racks (1-11) with the stepped sliders and the racks A (1-13) with the stepped sliders respectively, and the stepped driving rods (1-21) are connected with the driving seats (2-2) with the grooves in a sliding manner;

the heat dissipation mechanism (3) comprises a wind wheel driving motor (3-1), a coupler A (3-2), a wind wheel shaft (3-3), an air box (3-4), a bent pipe (3-5), an air hole (3-6), an air pipe outlet (3-7) and a wind wheel (3-8), wherein the wind wheel driving motor (3-1) is connected with a shell (1-8), the wind wheel driving motor (3-1) is connected with the coupler A (3-2), the coupler A (3-2) is connected with the wind wheel shaft (3-3), the wind wheel shaft (3-3) is connected with a bearing seat (1-12) in a bearing connection mode, the wind wheel shaft (3-3) is connected with a bearing seat I (2-19) in a bearing connection mode, and the wind wheel shaft (3-3) is connected with the air box (3-4) in a bearing connection mode, the air box (3-4) is connected with the supporting platform (2-5), the air box (3-4) is connected and communicated with the bent pipe (3-5), an air hole (3-6) is formed in the bent pipe (3-5), an air pipe outlet (3-7) is formed in the bent pipe (3-5), the air pipe outlet (3-7) is communicated with the ventilation channel (2-18), the bent pipe (3-5) is connected with the supporting platform (2-5), and the wind wheel (3-8) is connected with a wind wheel shaft (3-3);

the machine shell mechanism (1) is connected with the adjustable supporting mechanism (2), the adjustable supporting mechanism (2) is connected with the heat dissipation mechanism (3), and the heat dissipation mechanism (3) is connected with the machine shell mechanism (1).

2. The unmanned aerial vehicle control platform heat dissipation protection device of claim 1, characterized in that: the bent pipes (3-5) are made of stainless steel.

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