Be used for new forms of energy spare part heat conductivity detection device
Technical Field
The invention relates to the field related to heat conductivity detection, in particular to a heat conductivity detection device for new energy parts.
Background
New Energy (NE): the term "unconventional energy" refers to various forms of energy other than conventional energy, and refers to energy to be developed and utilized or actively studied to be popularized, such as solar energy, geothermal energy, wind energy, ocean energy, biomass energy, nuclear fusion energy, and the like.
When new forms of energy spare part production, often need detect the heat conductivity of spare part, but around detecting the spare part, often need cool off the spare part, guarantee the detection accuracy of heat conductivity afterwards, current new forms of energy spare part heat conductivity detection device is difficult for cooling down the detection transport to the spare part fast to be difficult for cooling down the spare part after detecting fast, influence detection efficiency.
Disclosure of Invention
Therefore, in order to solve the above-mentioned disadvantages, the present invention provides a thermal conductivity detection device for new energy components.
The invention is realized in such a way that the heat conductivity detection device for the new energy component is constructed, the device comprises supporting legs, a transverse plate, a detector body, a control button, a top cover, a power supply lead and a circulating conveying cooling mechanism, the supporting legs are connected with four corners at the bottom of the transverse plate, the circulating conveying cooling mechanism is arranged at the top of the transverse plate, the circulating conveying cooling mechanism comprises a driving mechanism, a rotating shaft, a swinging arm, a connecting block, a placing plate, a sealing mechanism and a heat dissipation mechanism, the driving mechanism is embedded and arranged at the upper end of the transverse plate and is connected with the bottom of the rotating shaft, the rotating shaft is fixed with the rear end of the swinging arm, the swinging arm is fixedly connected with the rear end of the connecting block, the connecting block is connected with the rear end of the placing plate, the placing plate is connected with the bottom of the sealing mechanism, and the heat dissipation mechanism is connected with the rear end of the driving mechanism.
Preferably, the transverse plate is connected with the bottom of the detector body, a control button is arranged at the front end of the detector body, a top cover is arranged at the top of the detector body, and a power supply lead is fixed at the rear end of the transverse plate.
Preferably, the driving mechanism comprises an installation frame, a gear, a rack, a guide rail, a moving block and a first telescopic cylinder, the installation frame is embedded in the upper end of the transverse plate, the gear is arranged in the installation frame and connected with the lower end of the rotating shaft, the gear is meshed with the front end of the rack, the rack is in sliding fit with the inner side of the guide rail, the rack is fixed with the front end of the moving block, the right end of the moving block is provided with the first telescopic cylinder, and the rear end of the first telescopic cylinder is fixedly connected with the installation frame.
Preferably, the sealing mechanism comprises a first connecting frame, a telescopic cover, a second connecting frame, a bearing sheet and a second telescopic cylinder, the bottom of the first connecting frame is connected with the placing plate, the first connecting frame is fixed with the bottom of the telescopic cover, the top of the telescopic cover is provided with the second connecting frame, the second connecting frame is fixed with the rear end of the bearing sheet, the bearing sheet is fixed with the top of the second telescopic cylinder, and the bottom of the second telescopic cylinder is connected with the first connecting frame.
Preferably, heat dissipation mechanism includes fixed arm, safety cover, heat dissipation fan and stop gear, the fixed arm front end is connected with actuating mechanism, the fixed arm is fixed with the safety cover front end, the inside embedded installation of safety cover has the heat dissipation fan, stop gear is installed to the safety cover right-hand member.
Preferably, stop gear includes support frame, riser, clamping bar, pressure spring, kicking block and blotter, support frame and safety cover right-hand member looks fixed connection, the support frame is fixed as an organic whole with the riser right-hand member, the riser is fixed mutually with the clamping bar right-hand member, the clamping bar passes through pressure spring, kicking block and upper end elastic connection, the blotter right-hand member is connected with the riser.
Preferably, the clamping rods are arranged in two, and the clamping rods are oppositely arranged along the upper side and the lower side of the left end of the vertical plate.
Preferably, the upper ends of the two clamping rods are provided with a pressure spring and a jacking block, and the jacking block is in sliding fit with the inner sides of the clamping rods.
Preferably, the fixed arm is flat long strip to the fixed arm is provided with two altogether, and the fixed arm sets up along the installing frame front and back both sides relatively.
Preferably, two fixed arm upper end all is provided with safety cover, heat dissipation fan and stop gear to the heat dissipation fan is located and places the board under the lower extreme.
Preferably, the gear is made of gear steel and has strong wear resistance.
Preferably, the moving block is made of carbon steel and has high hardness.
The invention has the following advantages: the invention provides a thermal conductivity detection device for new energy components through improvement, which has the following improvement compared with the same type of equipment:
the method has the advantages that: according to the device for detecting the heat conductivity of the new energy component, the circulating conveying cooling mechanism is arranged at the upper end of the transverse plate, the two placing plates are arranged, when the first placing plate is arranged on the inner side of the detector body, the other placing plate is arranged right above the heat dissipation fan to dissipate heat of the component, after the first component is detected, the driving mechanism drives the swing arm to swing, so that the detected component is arranged on the top of the heat dissipation fan to be cooled, the detected component is located on the inner side of the detector body at the moment, and the advantage that the component can be circularly conveyed, detected and cooled is achieved.
The method has the advantages that: according to the device for detecting the heat conductivity of the new energy part, the driving mechanism is arranged at the upper end of the circulating conveying cooling mechanism, the first telescopic cylinder contracts and drives the gear to rotate clockwise through the rack, so that the swing arm is driven to rotate ninety degrees through the rotating shaft, the swing arm rotates ninety degrees through positive and negative rotation of the gear, the positive and negative ninety degrees of the swing arm are realized, and therefore the two placing plates are always located on the inner side of the detector body and the top of the heat dissipation fan, and the advantage that the position of the placing plates can be quickly adjusted is achieved.
The method has the advantages that: according to the device for detecting the heat conductivity of the new energy component, the sealing mechanism is arranged at the upper end of the circulating conveying cooling mechanism, when the placing plate is located inside the detector body, the second telescopic cylinder extends to drive the second connecting frame to move towards the upper end, so that the second connecting frame drives the telescopic cover to extend, a gap between the detector body and the top cover is sealed, and the advantage that the detection sealing performance can be guaranteed is achieved.
The advantages are that: according to the device for detecting the heat conductivity of the new energy component, the heat dissipation mechanism is arranged at the upper end of the circulating conveying cooling mechanism, the component can be cooled and dissipated through the heat dissipation fan, meanwhile, when the placing plate swings, the placing plate can be in contact with the cushion pad, so that the impact force of the placing plate is reduced, then the placing plate presses the top block, the top block presses the pressure spring to deform and contract, the top block is embedded into the limiting groove to limit the placing plate, and the advantage that the placing plate can be prevented from shifting is achieved.
Drawings
FIG. 1 is a schematic structural view of the present invention;
FIG. 2 is a schematic perspective view of the circulating transport cooling mechanism of the present invention;
FIG. 3 is a schematic cross-sectional view of the driving mechanism of the present invention;
FIG. 4 is a schematic perspective view of the sealing mechanism of the present invention;
FIG. 5 is an enlarged view of the structure of FIG. 4 at A according to the present invention;
FIG. 6 is a schematic perspective view of a heat dissipation mechanism according to the present invention;
FIG. 7 is a schematic perspective view of a spacing mechanism of the present invention;
fig. 8 is a schematic sectional structure view of the limiting mechanism of the present invention.
Wherein: supporting foot-1, transverse plate-2, detector body-3, control button-4, top cover-5, power supply lead-6, circulating conveying cooling mechanism-7, driving mechanism-71, rotating shaft-72, swinging arm-73, connecting block-74, placing plate-75, sealing mechanism-76, heat dissipation mechanism-77, mounting frame-711, gear-712, rack-713, guide rail-714, moving block-715, first telescopic cylinder-716, first connecting frame-761, telescopic cover-762, second connecting frame-763, bearing sheet-764, second telescopic cylinder-765, fixing arm-771, protective cover-772, heat dissipation fan-773, limiting mechanism-774, supporting frame-7741, vertical plate-7742, A clamping rod-7743, a pressure spring-7744, a top block-7745, a cushion pad-7746 and a limit groove-751.
Detailed Description
The present invention will be described in detail below with reference to fig. 1 to 8, and the technical solutions in the embodiments of the present invention will be clearly and completely described, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
The first embodiment is as follows:
referring to fig. 1, the invention provides a device for detecting thermal conductivity of a new energy component by improvement, which comprises supporting legs 1, a transverse plate 2, a detector body 3, control buttons 4, a top cover 5, power supply wires 6 and a circulating conveying cooling mechanism 7, wherein the supporting legs 1 are connected with four corners of the bottom of the transverse plate 2, the circulating conveying cooling mechanism 7 is installed at the top of the transverse plate 2, the transverse plate 2 is connected with the bottom of the detector body 3, the control buttons 4 are arranged at the front end of the detector body 3, the top cover 5 is arranged at the top of the detector body 3, and the power supply wires 6 are fixed at the rear end of the transverse plate 2.
Referring to fig. 2, the present invention provides a thermal conductivity detection device for new energy components through improvement, wherein the circular transportation cooling mechanism 7 includes a driving mechanism 71, a rotating shaft 72, a swing arm 73, a connecting block 74, a placing plate 75, a sealing mechanism 76 and a heat dissipation mechanism 77, the driving mechanism 71 is embedded in the upper end of the horizontal plate 2, the driving mechanism 71 is connected to the bottom of the rotating shaft 72, the rotating shaft 72 is fixed to the rear end of the swing arm 73, the swing arm 73 is fixedly connected to the rear end of the connecting block 74, the connecting block 74 is connected to the rear end of the placing plate 75, the placing plate 75 is connected to the bottom of the sealing mechanism 76, and the heat dissipation mechanism 77 is connected to the rear end of the driving mechanism 71.
Referring to fig. 3, the driving mechanism 71 includes a mounting frame 711, a gear 712, a rack 713, a guide rail 714, a moving block 715 and a first telescopic cylinder 716, the mounting frame 711 is embedded in the upper end of the transverse plate 2, the gear 712 is arranged inside the mounting frame 711, the gear 712 is connected with the lower end of the rotating shaft 72, the gear 712 is meshed with the front end of the rack 713, the rack 713 is in sliding fit with the inner side of the guide rail 714 and is beneficial to achieving the effect of enabling the rack 713 to move stably, the rack 713 is fixed with the front end of the moving block 715, the first telescopic cylinder 716 is arranged at the right end of the moving block 715, the rear end of the first telescopic cylinder 716 is fixedly connected with the mounting frame 711, the gear 712 is made of gear steel, the wear resistance is high, and the moving block 715 is made of carbon steel and has high hardness.
Referring to fig. 4 and 5, the invention provides a device for detecting thermal conductivity of a new energy component by improvement, in which the sealing mechanism 76 includes a first connecting frame 761, a telescopic hood 762, a second connecting frame 763, a receiving piece 764, and a second telescopic cylinder 765, the bottom of the first connecting frame 761 is connected to the placing plate 75, the first connecting frame 761 is fixed to the bottom of the telescopic hood 762, the top of the telescopic hood 762 is provided with the second connecting frame 763, the second connecting frame 763 is fixed to the rear end of the receiving piece 764, the receiving piece 764 is fixed to the top of the second telescopic cylinder 765, and the bottom of the second telescopic cylinder 765 is connected to the first connecting frame 761, so as to fix and support the second telescopic cylinder 765.
Referring to fig. 6, the heat dissipation mechanism 77 includes a fixed arm 771, a protective cover 772, two heat dissipation fans 773 and a limiting mechanism 774, the front end of the fixed arm 771 is connected to the driving mechanism 71, the fixed arm 771 is fixed to the front end of the protective cover 772, the heat dissipation fan 773 is embedded in the protective cover 772, the limiting mechanism 774 is installed at the right end of the protective cover 772, the fixed arm 771 is flat and long, the fixed arms 771 are arranged in two numbers, the fixed arms 771 are arranged oppositely along the front side and the rear side of the mounting frame 711, the protective cover 772, the heat dissipation fans 773 and the limiting mechanism 774 are arranged at the upper ends of the two fixed arms 771, and the heat dissipation fans 773 are located at the lower end of the placement plate 75 to dissipate heat of the component.
Referring to fig. 7 and 8, the invention provides a device for detecting thermal conductivity of a new energy component by improvement, wherein a limiting mechanism 774 includes a support bracket 7741, a vertical plate 7742, a clamping bar 7743, a pressure spring 7744, a top block 7745 and a buffer 7746, the support bracket 7741 is fixedly connected with the right end of a protective cover 772, the support bracket 7741 is fixed with the right end of the vertical plate 7742 as a whole, the vertical plate 7742 is fixed with the right end of the clamping bar 7743, the clamping bar 7743 is elastically connected with the upper end through the pressure spring 7744 and the top block 7745, the right end of the buffer 7746 is connected with the vertical plate 7742, the clamping bar 7743 is provided with two clamping bars 7743, the clamping bars 7743 are oppositely arranged along the upper and lower sides of the left end of the vertical plate 7742, the upper ends of the two clamping bars 7743 are both provided with the pressure spring 7744 and the top block 7745, and the inner sides of the top block 7743 are in sliding fit, which is beneficial to the effect of stably moving the top block 7745.
Example two:
the invention provides a device for detecting the heat conductivity of new energy parts through improvement, two swing arms 73 are arranged, the swing arms 73 form a right angle shape, the upper ends of the swing arms 73 are respectively provided with a connecting block 74, a placing plate 75 and a sealing mechanism 76, the effect of circulating conveying is facilitated, two guide rails 714 are arranged, the guide rails 714 are oppositely arranged along the upper side and the lower side of a rack 713, the upper end of the placing plate 75 is provided with a limiting groove 751, and the limiting groove is in snap fit with the inner side of a top block 7745.
The invention provides a device for detecting the heat conductivity of new energy parts through improvement, and the working principle is as follows;
firstly, before use, horizontally placing a device for detecting the heat conductivity of new energy components, so that the device is fixedly supported by supporting legs 1;
secondly, when in use, an external power supply is connected through the power lead 6 to provide power for the device, and then the parts are placed on the inner side of the placing plate 75;
thirdly, pressing the control button 4 next, starting the device, when the first placing plate 75 is positioned at the inner side of the detector body 3, the other placing plate 75 is positioned at the right upper end of the heat dissipation fan 773, dissipating heat of the parts, after the first parts are detected, the driving mechanism 71 drives the swinging arm 73 to swing, so that the detected parts are positioned at the top of the heat dissipation fan 773 for cooling, and the detected parts are positioned at the inner side of the detector body 3 for detection at the moment, so that the parts are circularly conveyed, detected and cooled;
fourthly, after the detection is finished, the first telescopic cylinder 716 contracts, the gear 712 is driven by the rack 713 to rotate clockwise, the swing arm 73 is driven by the rotating shaft 72 to rotate ninety degrees, the swing arm 73 rotates ninety degrees in the positive and negative directions by the positive and negative rotation of the gear 712, and therefore two placing plates 75 are always positioned on the inner side of the detector body 3 and the top of the heat dissipation fan 773;
fifthly, when the placing plate 75 is positioned inside the detector body 3, the second telescopic cylinder 765 extends to drive the second connecting frame 763 to move upwards, so that the second connecting frame 763 drives the telescopic hood 762 to extend, a gap between the detector body 3 and the top cover 5 is sealed, and detection sealing performance can be guaranteed;
sixthly, simultaneously through having set up heat dissipation mechanism 77 in cyclic delivery cooling body 7 upper end, can cool off the heat dissipation to spare part through heat dissipation fan 773, simultaneously when placing board 75 swing, can contact with blotter 7746, thereby reduce and place board 75 impact force, it presses and moves kicking block 7745 to place board 75 afterwards, make kicking block 7745 press pressure spring 7744 and produce the deformation shrink, make kicking block 7745 imbed in spacing recess 751 inboard, it is spacing to placing board 75, reached and to have prevented to place board 75 skew.
The invention provides a device for detecting the heat conductivity of new energy parts through improvement, a circulating conveying cooling mechanism 7 is arranged at the upper end of a transverse plate 2, two placing plates 75 are arranged, when a first placing plate 75 is positioned at the inner side of a detector body 3, the other placing plate 75 is positioned at the right upper end of a heat dissipation fan 773 to dissipate heat of the parts, after the first part is detected, a driving mechanism 71 drives a swing arm 73 to swing, so that the detected parts are positioned at the top of the heat dissipation fan 773 to be cooled, and the detected parts are positioned at the inner side of the detector body 3 to be detected, so that the advantage of cooling the parts through circulating conveying detection is achieved; the driving mechanism 71 is arranged at the upper end of the circulating conveying cooling mechanism 7, the first telescopic cylinder 716 contracts and drives the gear 712 to rotate clockwise through the rack 713, so that the swing arm 73 is driven to rotate ninety degrees through the rotating shaft 72, and the swing arm 73 rotates plus or minus ninety degrees through the positive and negative rotation of the gear 712, so that two placing plates 75 are always positioned on the inner side of the detector body 3 and the top of the heat dissipation fan 773, and the advantage of quickly adjusting the position of the placing plate 75 is achieved; by arranging the sealing mechanism 76 at the upper end of the circulating conveying cooling mechanism 7, when the placing plate 75 is positioned at the inner side of the detector body 3, the second telescopic cylinder 765 extends to drive the second connecting frame 763 to move upwards, so that the second connecting frame 763 drives the telescopic hood 762 to extend, a gap between the detector body 3 and the top cover 5 is sealed, and the advantage of ensuring the detection sealing performance is achieved; through having set up heat dissipation mechanism 77 in cyclic delivery cooling body 7 upper end, can cool off the heat dissipation to spare part through heat dissipation fan 773, simultaneously when placing board 75 swing, can contact with blotter 7746, thereby reduce and place board 75 impact force, it presses ejector pad 7745 to place board 75 afterwards, make ejector pad 7745 press the pressure spring 7744 and produce the deformation shrink, make ejector pad 7745 imbed in spacing recess 751 inboard, it is spacing to placing board 75, reached and to have prevented to place the advantage of board 75 skew.
The basic principles and main features of the present invention and the advantages of the present invention have been shown and described, and the standard parts used in the present invention are all available on the market, the special-shaped parts can be customized according to the description and the accompanying drawings, the specific connection mode of each part adopts the conventional means of bolt and rivet, welding and the like mature in the prior art, the machinery, parts and equipment adopt the conventional type in the prior art, and the circuit connection adopts the conventional connection mode in the prior art, and the details are not described herein.
The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.