CN111707388A - Installation mechanism of graphene high-temperature sensor - Google Patents

Abstract

The invention discloses an installation mechanism of a graphene high-temperature sensor, which comprises a bottom plate, a support, an auxiliary support plate, a vertical plate, a circular groove and a protective structure, wherein the position among the bottom plate, the support and the auxiliary support plate is finely adjusted and then fixed through a bolt so as to change the position of the vertical plate, change the detection position, facilitate the adjustment of the detection position and increase the detection precision; set up protective structure through optimizing, when the temperature of detection department is higher, memory spring produces deformation, makes the push rod drive three hornblocks extrusion triangle nose bar through the push pedal, and the triangle nose bar drives half-round plate piece and moves the closure to the inboard, closes the sensor in the cover to prevent ruptured piece spill, guarantee the normal use of equipment.

Description

Installation mechanism of graphene high-temperature sensor

Technical Field

The invention relates to the field of sensor mounting frames, in particular to an installation mechanism of a graphene high-temperature sensor.

Background

The graphene has excellent optical, electrical and mechanical properties, has important application prospects in the aspects of materials science, micro-nano processing, energy, biomedicine, drug delivery and the like, and is considered to be a revolutionary material in the future; at present, there are many types of thin film sensors developed based on graphene, including a graphene temperature sensor thin film, a graphene humidity sensor thin film, a graphene strain sensor thin film, and the like, and since graphene is a two-dimensional hexagonal lattice structure and has excellent electrical, thermal, and mechanical properties, it is also often used as a material for manufacturing a high temperature sensor, and the graphene high temperature sensor is generally mounted at a specific position by using a mounting mechanism for stable detection.

The installation mechanism structure of the graphene high-temperature sensor in the prior art is single, and is usually only used as a carrier, when the position of a detection position and the position of the installation position have deviation, the detection position is not easy to adjust, so that the detection precision is relatively poor, and when the sensor is damaged and broken due to overhigh temperature of the detection position, broken fragments are easy to splash out, and the use of equipment is influenced.

Disclosure of Invention

Therefore, in order to solve the above-mentioned disadvantages, the present invention provides a mounting mechanism for a graphene high-temperature sensor.

The invention is realized in such a way that an installation mechanism of a graphene high-temperature sensor is constructed, the installation mechanism comprises an installation main body, the installation main body comprises a bottom plate, a support, an auxiliary support plate, a vertical plate, a circular groove and a protection structure, the left side and the right side of the vertical plate are in up-and-down sliding fit with the support, the support is fixed with the vertical plate through a bolt, the auxiliary support plate is integrally formed at the rear side of the bottom of the support, the outer side of the auxiliary support plate is in front-and-back sliding fit with the bottom plate, the auxiliary support plate is fixed with the bottom plate through a bolt, the middle part of the inner side of the vertical plate is provided with the circular groove, the central shaft of the protection structure and the center.

Preferably, a clamping groove is formed in the middle of the inner side of the bottom plate, an opening is formed in the inner side of the auxiliary supporting plate, and the inner side of the opening is mutually locked and fixed with the clamping groove through a bolt.

Preferably, protective structure includes cover, spacing groove, elasticity subassembly, dismantles top cap, a piece, fender bracket and power component, the spacing groove has been seted up on the inside right side of cover, the elasticity subassembly has been inlayed in the inside left side of spacing groove, it inserts the spacing inslot side to dismantle the top cap and pass through elasticity subassembly and spacing groove looks block, the inside left side integrated into one piece of cover has a piece, be connected with the fender bracket from top to bottom on a piece right side, power component inlays in the inside left side of cover to the power component left side contacts with the fender bracket.

Preferably, the limiting grooves and the elastic component are arranged in two, and the two limiting grooves are symmetrically arranged in the inner side direction of the cylinder cover.

Preferably, the elastic component comprises a frame seat, a spring and a clamping block, the frame seat is embedded in the inner side of the cylinder cover, the spring is fixed on the bottom side in the frame seat, the top of the spring is connected with the clamping block, the left end face and the right end face of the clamping block are inserted into the inner side of the frame seat and are in up-and-down sliding fit with the inner side of the frame seat, and meanwhile the top end face of the clamping block is in contact with the detachable top cover.

Preferably, dismantle the top cap and include interior ring cover, card post, apron and protection network, interior ring cover right-hand member face integrated into one piece has the apron, both sides integrated into one piece has the card post around the interior ring cover, interior ring cover inserts the spacing inslot side and rather than block mutually through the card post, and the protection network has been inlayed at the inboard middle part of interior ring cover simultaneously.

Preferably, the number of the protection frames is two, and the two protection frames are vertically symmetrical on the inner side of the cylinder cover.

Preferably, the protection frame includes semicircle board, slider and triangle nose bar, sliding fit about semicircle board left side and the slider, the slider left side is fixed mutually with the branch piece, semicircle board right part top side transversely is fixed with the triangle nose bar, the semicircle board outside is connected with the cover through a little spring.

Preferably, the number of the power assemblies is two, and the two power assemblies and the two protection frames are respectively arranged on the same horizontal plane.

Preferably, power component includes rectangle seat, gag lever post, memory spring, push pedal, gleitbretter, push rod and three hornblocks, the rectangle seat inlays in the inside left side of cover, the inside right side of rectangle seat transversely is fixed with the gag lever post, gag lever post surface parcel has memory spring, memory spring right-hand member face is fixed mutually with the rectangle seat, and memory spring left end face is fixed mutually with the push pedal simultaneously, push pedal lateral sliding fit is inboard in the gleitbretter, the gleitbretter is fixed in the inside left side of rectangle seat, push pedal left end face integrated into one piece has the push rod, the push rod runs through rectangle seat left side and rather than lateral sliding fit, three hornblock right flanks are fixed mutually with the push rod to three hornblocks left sides contact with three horn protruding poles.

Preferably, the material used for the cylinder cover is hafnium alloy.

Preferably, the material used for the semicircular plate is tungsten steel.

The invention has the following advantages: the invention provides a mounting mechanism of a graphene high-temperature sensor by improving, compared with the same type of equipment, the mounting mechanism has the following improvements:

the method has the advantages that: according to the installation mechanism of the graphene high-temperature sensor, the positions of the bottom plate, the bracket and the auxiliary supporting plate are finely adjusted and then fixed through the bolts so as to change the position of the vertical plate, so that the detection position is changed, and the problem that when the position of the detection position is deviated from the position of the installation position, the detection position is not easily adjusted, and the detection precision is relatively poor is solved.

The method has the advantages that: according to the mounting mechanism of the graphene high-temperature sensor, the protective structure is optimally arranged, when the temperature of a detection position is high, the memory spring deforms, the push rod drives the triangular block to extrude the triangular convex rod through the push plate, the triangular convex rod drives the semicircular plate to move inwards to close, and the sensor is closed in the cylinder cover, so that the problem that when the temperature of the detection position is too high, the sensor is damaged and broken, broken fragments are easy to splash out, and the use of equipment is affected is solved.

The method has the advantages that: according to the installation mechanism of the graphene high-temperature sensor, the middle part of the inner side of the bottom plate is provided with the clamping groove, the inner side of the auxiliary support plate is provided with the through hole, the inner side of the through hole is mutually locked and fixed with the clamping groove through the bolt, the bolt penetrates through the through hole and is fixed with the clamping groove, position adjustment is achieved, the two limiting grooves and the two elastic components are arranged, the two limiting grooves are symmetrically arranged in the inner side direction of the cylinder cover, the top cover can be conveniently fixed, the two protection frames are arranged, the two protection frames are vertically symmetrical on the inner side of the cylinder cover, the two power components are arranged, the two power components and the two protection frames are respectively arranged on the same horizontal plane, the protection frames act under the action of.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the connection structure of the bottom plate and the auxiliary supporting plate according to the present invention;

FIG. 3 is an enlarged view of a portion of the structure of FIG. 2;

FIG. 4 is a schematic structural view of the protective structure of the present invention;

FIG. 5 is a schematic structural view of the present invention with the top cover removed;

FIG. 6 is a schematic view of the construction of the resilient member of the present invention;

FIG. 7 is a schematic view of the connection between the protective frame and the power module according to the present invention;

fig. 8 is an enlarged view of a portion of the structure of fig. 7 at B according to the present invention.

Wherein: an installation main body-1, a bottom plate-2, a bracket-3, an auxiliary supporting plate-4, a vertical plate-5, a circular groove-6, a protective structure-7, a clamping groove-21, a through opening-41, a cylinder cover-71, a limiting groove-72, an elastic component-73, a detachable top cover-74, a supporting sheet-75, a protective frame-76, a power component-77 and a frame seat-731, the device comprises a spring-732, a clamping block-733, an inner ring cover-741, a clamping column-742, a cover plate-743, a protective net-744, a semicircular plate-761, a slider-762, a triangular convex rod-763, a rectangular seat-771, a limit rod-772, a memory spring-773, a push plate-774, a slide sheet-775, a push rod-776 and a triangular block-777.

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, 2 and 3, a mounting body 1 of the mounting mechanism for a graphene high-temperature sensor of the present invention includes a bottom plate 2, a bracket 3, an auxiliary support plate 4, a vertical plate 5, a circular groove 6 and a protective structure 7, wherein left and right sides of the vertical plate 5 are in up-down sliding fit with the bracket 3, the bracket 3 is fixed with the vertical plate 5 through a bolt, the auxiliary support plate 4 is integrally formed at a rear side of a bottom of the bracket 3, an outer side of the auxiliary support plate 4 is in front-back sliding fit with the bottom plate 2, the auxiliary support plate 4 is fixed with the bottom plate 2 through a bolt, the circular groove 6 is formed in a middle portion of an inner side of the vertical plate 5, a central axis of the protective structure 7 and a center of the circular groove 6 are on the same axis, four ends of the front portion of the protective structure 7 are fixed with the vertical plate 5 through bolts, and a, and the high-temperature graphene temperature sensor is prevented from splashing out after being broken under the action of the protective structure 7.

Referring to fig. 4 and 5, in the mounting mechanism of a graphene high-temperature sensor according to the present invention, the protective structure 7 includes a cylinder cover 71, a limiting groove 72, an elastic component 73, a detachable top cover 74, a supporting piece 75, a protective frame 76 and a power component 77, the limiting groove 72 is formed on the right side inside the cylinder cover 71, the elastic component 73 is embedded in the left side inside the limiting groove 72, the detachable top cover 74 is inserted into the inner side of the limiting groove 72, the detachable top cover 74 is engaged with the limiting groove 72 through the elastic component 73, the supporting piece 75 is integrally formed on the left side inside the cylinder cover 71, the protective frame 76 is connected to the right side of the supporting piece 75, the power component 77 is embedded in the left side inside the cylinder cover 71, the left side of the power component 77 is in contact with the protective frame 76, the detachable top cover 74 includes an inner ring cover 741, a clamping column 742, a cover 743 and a protective net 744, a cover 743 is integrally formed on the right, the inner ring cover 741 is inserted into the inner side of the limiting groove 72 through the clamping column 742 and clamped with the limiting groove, meanwhile, a protective net 744 is embedded in the middle of the inner side of the inner ring cover 741, the protective frame 76 is closed under the action of a power assembly when the temperature is too high, and fragments are prevented from splashing.

Referring to fig. 6, in the mounting mechanism of a graphene high temperature sensor according to the present invention, the elastic component 73 includes a frame seat 731, a spring 732, and a clamping block 733, the frame seat 731 is embedded inside the cylinder cover 71, the spring 732 is fixed on the bottom side inside the frame seat 731, the top of the spring 732 is connected to the clamping block 733, the left and right end faces of the clamping block 733 are inserted into the inside of the frame seat 731 and are in up-and-down sliding fit with the frame seat 731, meanwhile, the top end face of the clamping block 733 is in contact with the detachable top cover 74, and the detachable top cover 74 is pressed and fixed under the action of the spring 732 and the clamping.

Referring to fig. 7, in the mounting mechanism of a graphene high-temperature sensor according to the present invention, the protection frame 76 includes a semicircular plate 761, a slider 762 and a triangular protruding rod 763, the left side of the semicircular plate 761 is vertically slidably fitted with the slider 762, the left side of the slider 762 is fixed to the support plate 75, the right top side of the semicircular plate 761 is transversely fixed to the triangular protruding rod 763, and the outer side of the semicircular plate 761 is connected to the cylinder cover 71 through a small spring, and is protected by the semicircular plate 761.

Referring to fig. 8, in the mounting mechanism of a graphene high temperature sensor of the present invention, a power assembly 77 includes a rectangular seat 771, a limit rod 772, a memory spring 773, a push plate 774, a sliding sheet 775, a push rod 776 and a triangular block 777, the rectangular seat 771 is embedded in the left side inside a barrel cover 71, the limit rod 772 is transversely fixed on the right side inside the rectangular seat 771, the memory spring 773 wraps the outer surface of the limit rod 772, the right end surface of the memory spring 773 is fixed with the rectangular seat 771, the left end surface of the memory spring 773 is fixed with the push plate 774, the push plate 774 is transversely slidably fitted on the inner side of the sliding sheet 775, the sliding sheet 775 is fixed on the left side inside of the rectangular seat 771, the push rod 776 is integrally formed on the left end surface of the push plate 774, the push rod 776 penetrates through the left side of the rectangular seat 771 and is slidably fitted transversely thereto, the right side surface of the triangular block 777 is fixed with the push rod 775, the triangular block 777 is pushed by a push rod 776.

Example two:

according to the installation mechanism of the graphene high-temperature sensor, the middle part of the inner side of the bottom plate 2 is provided with the clamping groove 21, the inner side of the auxiliary support plate 4 is provided with the through hole 41, the inner side of the through hole 41 is mutually locked and fixed with the clamping groove 21 through a bolt, the bolt penetrates through the through hole 41 and is fixed with the clamping groove 21, position adjustment is achieved, two limiting grooves 72 and two elastic components 73 are arranged, the two limiting grooves 72 are symmetrically arranged in the inner side direction of the cylinder cover 71, the dismounting top cover 74 can be fixed conveniently, the two protection frames 76 are arranged, the two protection frames 76 are vertically symmetrical on the inner side of the cylinder cover 71, the two power components 77 are arranged, the two power components 77 and the two protection frames 76 are respectively arranged on the same horizontal plane, the protection frames 76 act under the action of the power components 77.

The invention provides an installation mechanism of a graphene high-temperature sensor through improvement, and the working principle is as follows;

firstly, a graphene high-temperature sensor is arranged in a cylinder cover 71, and then the design is fixed at a position to be detected through a bottom plate 2, so that the design is used;

secondly, when the position of the graphene high-temperature sensor is not aligned with the position of a position to be detected, a user can slide the support 3 back and forth on the inner side of the clamping groove 21 of the bottom plate 2 and slide the vertical plate 5 up and down on the inner side of the support 3, and when the circular groove 6 is aligned with the position to be detected, the graphene high-temperature sensor is locked and fixed by using a bolt, so that the graphene high-temperature sensor is aligned with the position to be detected, and the detection precision is increased;

thirdly, when the temperature of the detection part of the graphene high-temperature sensor is too high, the memory spring 773 is deformed by high temperature, the memory spring 773 is deformed and then pushes the push plate 774 to move leftwards on the slip sheet 775, the push plate 774 enables the triangular block 777 to extrude the triangular convex rod 763 through the push rod 776, the triangular convex rod 763 drives the semicircular plate 761 to move inwards and close, the graphene high-temperature sensor is closed in the cylinder cover 71, and when the temperature continuously rises to crack the graphene high-temperature sensor, broken slag of the graphene high-temperature sensor is kept in the cylinder cover 71 under the shielding of the semicircular plate 761;

fourthly, when the graphene high-temperature sensor needs to be replaced, a user presses the cover plate 743 to enable the clamping column 742 to extrude the clamping block 733, then the cover plate 743 is rotated to enable the clamping column 742 to be separated from the inner side of the limiting groove 72, and the clamping block 733 can be detached, after the graphene high-temperature sensor is replaced, the user inserts the inner ring shield 741 into the inner side of the cylinder shield 71 again, and the clamping column 742 is clamped into the limiting groove 72 to be used.

The invention provides an installation mechanism of a graphene high-temperature sensor through improvement, the positions of a bottom plate 2, a bracket 3 and an auxiliary supporting plate 4 are finely adjusted and then fixed through bolts so as to change the position of a vertical plate 5, thereby changing the detection position, and solving the problems that when the position of a detection position and the position of an installation position have deviation, the detection position is not easy to adjust, and the detection precision is relatively poor; by optimally arranging the protective structure 7, when the temperature of a detected part is higher, the memory spring 773 deforms, the push plate 774 drives the push rod 776 to drive the triangular block 777 to extrude the triangular convex rod 763, the triangular convex rod 763 drives the semicircular plate 761 to move inwards to close, and the sensor is closed in the cylinder cover 71, so that the problem that when the temperature of the detected part is too high, the sensor is damaged and broken, broken fragments are easy to splash out, and the use of equipment is influenced is solved; draw-in groove 21 has been seted up at the inboard middle part of bottom plate 2, opening 41 has been seted up to auxiliary support plate 4 inboard, and opening 41 inboard is fixed through bolt and draw-in groove 21 mutual locking, it is fixed mutually with draw-in groove 21 to pass opening 41 with the bolt, realize the regulation of position, spacing groove 72 and elasticity subassembly 73 all are provided with two, and two spacing grooves 72 set up at the inboard direction symmetry of cover 71, be favorable to fixing dismantling top cap 74, protection frame 76 is provided with two altogether, and two protection frames 76 are at the inboard longitudinal symmetry of cover 71, power component 77 is provided with two, and two power component 77 respectively with two protection frames 76 on same horizontal plane, make protection frame 76 move under power component 77's effect, prevent the piece departure.

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.

Claims (10)

1. The utility model provides a graphite alkene high temperature sensor's installation mechanism, includes installation main part (1), its characterized in that: installation main part (1) includes bottom plate (2), support (3), auxiliary supporting plate (4), riser (5), circular recess (6) and protective structure (7), sliding fit about riser (5) left and right sides and support (3) to support (3) are fixed mutually through bolt and riser (5), support (3) bottom rear side integrated into one piece has auxiliary supporting plate (4), sliding fit around auxiliary supporting plate (4) outside and bottom plate (2) to auxiliary supporting plate (4) are fixed mutually through bolt and bottom plate (2), circular recess (6) have been seted up at riser (5) inboard middle part, the center pin of protective structure (7) and the center of circular recess (6) are on same axis to protective structure (7) front portion is all ends to be fixed mutually through bolt and riser (5).

2. The mounting mechanism of the graphene high-temperature sensor according to claim 1, wherein: clamping groove (21) have been seted up at bottom plate (2) inboard middle part, opening (41) have been seted up to auxiliary stay board (4) inboard to opening (41) inboard is fixed through bolt and clamping groove (21) locking each other.

3. The mounting mechanism of the graphene high-temperature sensor according to claim 1, wherein: protective structure (7) include barrel casing (71), spacing groove (72), elasticity subassembly (73), dismantle top cap (74), prop up piece (75), protection frame (76) and power component (77), spacing groove (72) have been seted up on barrel casing (71) inside right side, elasticity subassembly (73) have been inlayed to the inside left side of spacing groove (72), it inserts spacing groove (72) inboard to dismantle top cap (74) through elasticity subassembly (73) and spacing groove (72) looks block, the inside left side integrated into one piece of barrel casing (71) has a piece (75), prop up piece (75) right side and be connected with protection frame (76) from top to bottom, power component (77) inlay in the inside left side of barrel casing (71) to power component (77) left side contacts with protection frame (76).

4. The mounting mechanism of the graphene high-temperature sensor according to claim 3, wherein: the two limiting grooves (72) and the two elastic components (73) are arranged, and the two limiting grooves (72) are symmetrically arranged in the inner side direction of the cylinder cover (71).

5. The mounting mechanism of the graphene high-temperature sensor according to claim 3, wherein: the elastic component (73) comprises a frame seat (731), a spring (732) and a clamping block (733), the frame seat (731) is embedded inside the cylinder cover (71), the spring (732) is fixed on the bottom side inside the frame seat (731), the top of the spring (732) is connected with the clamping block (733), the left end face and the right end face of the clamping block (733) are inserted into the inside of the frame seat (731) and are in up-and-down sliding fit with the frame seat, and meanwhile the top end face of the clamping block (733) is in contact with the detachable top cover (74).

6. The mounting mechanism of the graphene high-temperature sensor according to claim 3, wherein: dismantle top cap (74) and include interior ring cover (741), card post (742), apron (743) and protection network (744), interior ring cover (741) right-hand member face integrated into one piece has apron (743), both sides integrated into one piece has card post (742) around interior ring cover (741), interior ring cover (741) insert spacing groove (72) inboard through card post (742) and rather than block mutually, and protection network (744) have been inlayed in interior ring cover (741) inboard middle part simultaneously.

7. The mounting mechanism of the graphene high-temperature sensor according to claim 3, wherein: the number of the protection frames (76) is two, and the two protection frames (76) are vertically symmetrical on the inner side of the cylinder cover (71).

8. The mounting mechanism of the graphene high-temperature sensor according to claim 3, wherein: protection frame (76) include semicircle board piece (761), slider (762) and triangle projecting bar (763), semicircle board piece (761) left side and slider (762) sliding fit from top to bottom, slider (762) left side is fixed mutually with a piece (75), semicircle board piece (761) right part top side is transversely fixed with triangle projecting bar (763), semicircle board piece (761) outside is connected with cover (71) through a little spring.

9. The mounting mechanism of the graphene high-temperature sensor according to claim 3, wherein: the number of the power assemblies (77) is two, and the two power assemblies (77) are respectively on the same horizontal plane with the two protection frames (76).

10. The mounting mechanism of the graphene high-temperature sensor according to claim 3, wherein: the power assembly (77) comprises a rectangular seat (771), a limiting rod (772), a memory spring (773), a push plate (774), a sliding sheet (775), a push rod (776) and a triangular block (777), the rectangular seat (771) is embedded in the left side inside a cylinder cover (71), the limiting rod (772) is transversely fixed on the right side inside the rectangular seat (771), the memory spring (773) wraps the outer surface of the limiting rod (772), the right end face of the memory spring (773) is fixed with the rectangular seat (771), the left end face of the memory spring (773) is fixed with the push plate (774), the push plate (774) is transversely matched with the inner side of the sliding sheet (775), the sliding sheet (775) is fixed on the left side inside of the rectangular seat (771), the push rod (776) is integrally formed on the left end face of the push plate (774), and the push rod (776) penetrates through the left side of the rectangular seat (771) and is transversely matched, the right side surface of the triangular block (777) is fixed with the push rod (776), and the left side surface of the triangular block (777) is contacted with the triangular convex rod (763).

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