CN113181786A - Light nano-material mixing equipment for mixing nano-materials - Google Patents

Abstract

The invention relates to light nano-material mixing equipment, in particular to light nano-material mixing equipment for mixing nano-materials, which comprises an input mechanism, a mixing linkage mechanism and an output mechanism, wherein the equipment can input the nano-materials and liquid into a mixing box, can rotate the liquid to gather the nano-materials in the center of a liquid surface, can discharge the liquid adsorbed in the middle of the mixing box to the nano-materials gathered in the center of the equipment so that the nano-materials are accelerated to be dissolved in the liquid, can automatically discharge the mixed mixture out of the equipment, is connected with the mixing linkage mechanism, is connected with the output mechanism, and is connected with the input mechanism.

Description

Light nano-material mixing equipment for mixing nano-materials

Technical Field

The invention relates to light nano-material mixing equipment, in particular to light nano-material mixing equipment for mixing nano-materials.

Background

When the light nanometer material is mixed with liquid, the nanometer material is light in weight, the flow layer of the mixing process is complicated, time and labor are wasted during mixing, but no good light nanometer material mixing equipment exists in the market, so the light nanometer material mixing equipment for mixing the nanometer material is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing light nano-material mixing equipment for mixing nano-materials, the equipment can input nano-materials and liquid into a mixing box, the equipment can rotate the liquid to gather the nano-materials in the center of the liquid level, the equipment can discharge the liquid adsorbed in the middle of the mixing box to the nano-materials gathered in the center of the equipment to accelerate the dissolution of the nano-materials into the liquid, and the equipment can automatically discharge the mixed mixture out of the equipment.

In order to solve the technical problems, the invention relates to light nano-material mixing equipment, in particular to light nano-material mixing equipment for mixing nano-materials, which comprises an input mechanism, a mixing linkage mechanism and an output mechanism, wherein the equipment can input the nano-materials and liquid into a mixing box, the equipment can rotate the liquid to gather the nano-materials in the center of the liquid level, the equipment can discharge the liquid adsorbed in the middle of the mixing box to the nano-materials gathered in the center of the equipment so that the nano-materials are accelerated to be dissolved in the liquid, and the equipment can automatically discharge the mixed mixture out of the equipment.

The input mechanism is connected with the mixing linkage mechanism, the mixing linkage mechanism is connected with the output mechanism, and the output mechanism is connected with the input mechanism.

As a further optimization of the technical scheme, the invention relates to a light nano-material mixing device for mixing nano-materials, wherein an input mechanism comprises a power shaft a, a propeller, a connecting ring sealing plate, a connecting ring, a conical input block, an input pipe, a connecting plate a, a connecting box, a connecting plate b, a backflow pipe, a triangular block, a lifting plate, a sliding chute and an output groove, the power shaft a is connected with the propeller, the power shaft a is connected with the connecting ring sealing plate bearing, the power shaft a is connected with the connecting plate b bearing, the propeller is connected with the connecting ring in a sliding manner, the two connecting ring sealing plates are connected with the connecting ring, the connecting ring sealing plates are connected with the conical input block, holes in the connecting ring sealing plates are connected with the input pipe, holes in the conical input block are connected with the backflow pipe, the input pipe is connected with holes in the connecting plate a, the connecting plate a is connected with the connecting box, and the connecting box is connected with the connecting plate b, the hole on the connecting box is connected with the backflow pipe, the connecting box is connected with the lifting plate in a sliding mode, the connecting box is connected with the sliding groove, the connecting box is connected with the output groove, the triangular block is connected with the lifting plate, and the lifting plate is connected with the sliding groove in a sliding mode.

As a further optimization of the technical scheme, the light nano-material mixing device for mixing nano-materials comprises a power shaft b, a rotating disk, a mounting plate a, a toggle column, a mounting plate b, a spring a, a toggle plate, a hinged plate a, a hinged plate chute, a mounting plate c, a connecting shaft I, a mounting plate d, a spring c, a hinged plate b, a mounting plate f, a connecting shaft II, a mounting plate g, a spring b, a connecting shaft III, a friction column, a mounting plate e, a mixing tank, a belt a, a connecting shaft IV, a belt b, a connecting shaft V, a reaction force propeller a, a rubber hose, a small friction wheel, a connecting shaft VI, a large friction wheel, a mixing ring, a mixing plate, a mounting block, a liquid guide plate, a linkage friction wheel, a connecting shaft VII and a reaction force propeller b, wherein the power shaft b is connected with the rotating disk and the power shaft b is in friction connection with the belt a, the power shaft b is connected with a connecting box bearing, the rotating disc is connected with a mounting plate a in a sliding manner, the rotating disc is connected with a mounting plate b, the mounting plate a is connected with a toggle column in a sliding manner, the toggle column is connected with the mounting plate b, a spring a is sleeved on the toggle column and limited on the mounting plate a and the mounting plate b, the toggle plate is connected with a hinged plate a which is connected with a hinged plate sliding groove, the hinged plate a is connected with a mounting plate c, the hinged plate a is hinged with the hinged plate b, the hinged plate sliding groove is connected with a connecting box, the mounting plate c is connected with a connecting shaft I, the connecting shaft I is connected with a mounting plate d in a sliding manner, the mounting plate d is connected with a connecting box, the spring c is sleeved on the connecting shaft I and limited on the mounting plate c and the mounting plate d, the hinged plate b is connected with a mounting plate f in a sliding manner, the hinged plate b is connected with a connecting shaft III in a friction manner, the mounting plate f is connected with a connecting shaft II, and the mounting plate f is connected with the connecting box in a sliding manner, a second connecting shaft is connected with a mounting plate g in a sliding manner, the mounting plate g is connected with a connecting box, a spring b is sleeved on the second connecting shaft and limited on a mounting plate f and is connected with the mounting plate g, a third connecting shaft is connected with a friction column, a third connecting shaft is connected with a bearing of the connecting box, the friction column is connected with a mounting plate e in a friction manner, the mounting plate e is connected with a mixing tank, the mounting plate e is connected with a connecting plate a in a sliding manner, a hole in the mixing tank is connected with a rubber hose, the mixing tank is connected with a liquid guide plate, the mixing tank is connected with a seventh connecting shaft bearing, the mixing tank is connected with the connecting box in a sliding manner, a belt a is connected with a fourth connecting shaft in a friction manner, the belt a is connected with a small friction wheel in a friction manner, a fourth connecting shaft is connected with a reaction force propeller a, a fourth connecting shaft is, the small friction wheel is connected with the connecting shaft six, the connecting shaft six is connected with the large friction wheel, the connecting shaft six is connected with the mounting block bearing, the large friction wheel is connected with the mixing ring in a friction mode, the mixing ring is connected with the mixing plate, the mixing ring is connected with the mounting block bearing, the mounting block is connected with the connecting box, the linkage friction wheel is connected with the connecting shaft seven, and the connecting shaft seven is connected with the reaction force propeller b.

As a further optimization of the technical scheme, the invention relates to light nano-material mixing equipment for mixing nano-materials, which comprises an output belt, a transmission shaft, a special-shaped friction wheel, a torsion spring, a driven wheel, a driven shaft, a first connecting plate, a second connecting plate, a third connecting plate, a fourth connecting plate and a pushing shaft, wherein the output belt is in friction connection with the transmission shaft, the output belt is in friction connection with a sixth connecting shaft, the transmission shaft is connected with the special-shaped friction wheel, the transmission shaft is connected with a second connecting plate b through a bearing, the torsion spring is sleeved on the transmission shaft and limited on the special-shaped friction wheel and the second connecting plate, the driven wheel is connected with the driven shaft, the driven shaft is connected with the second connecting plate through a bearing, the first connecting plate is connected with the second connecting plate, the first connecting plate on one side is in friction connection with the special-shaped friction wheel, the first connecting plate on the other side is in friction connection with the driven wheel, and the second connecting plate is in sliding connection with the second connecting plate, the third connecting plate is connected with the pushing shaft, the fourth connecting plate is connected with the pushing shaft, and the pushing shaft is connected with a bearing of the connecting plates on two sides.

As a further optimization of the technical scheme, the light nano-material mixing device for mixing nano-materials is characterized in that power sources are arranged on the power shaft a and the power shaft b and can rotate.

The light nano-material mixing equipment for mixing nano-materials has the beneficial effects that:

according to the light nano-material mixing equipment for mixing the nano-materials, disclosed by the invention, the equipment can be used for inputting the nano-materials and liquid into the mixing box, the equipment can be used for rotating the liquid to gather the nano-materials in the center of the liquid level, the equipment can be used for discharging the liquid adsorbed in the middle of the mixing box to the nano-materials gathered in the center of the equipment so as to accelerate the dissolution of the nano-materials into the liquid, and the equipment can be used for automatically discharging the mixed mixture out of the equipment.

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 light nanomaterial mixing device for mixing nanomaterials, according to the present invention.

Fig. 2 is a structural schematic diagram of a light-weight nanomaterial mixing device for mixing nanomaterials, according to the invention.

Fig. 3 is a schematic structural diagram of an input mechanism 1 of a light nanomaterial mixing apparatus for mixing nanomaterials according to the present invention.

Fig. 4 is a second schematic structural diagram of the input mechanism 1 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 5 is a third schematic structural diagram of the input mechanism 1 of the light-weight nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 6 is a fourth schematic structural diagram of the input mechanism 1 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 7 is a first structural schematic diagram of a mixing linkage mechanism 2 of the light nanomaterial mixing apparatus for nanomaterial mixing of the present invention.

Fig. 8 is a second structural schematic diagram of the mixing linkage mechanism 2 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 9 is a third schematic structural diagram of the mixing linkage mechanism 2 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 10 is a fourth schematic structural diagram of the mixing linkage mechanism 2 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 11 is a fifth structural schematic view of the mixing linkage mechanism 2 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 12 is a sixth schematic structural view of the mixing linkage mechanism 2 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 13 is a seventh schematic structural diagram of the mixing linkage mechanism 2 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 14 is an eighth schematic structural view of the mixing linkage mechanism 2 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 15 is a first structural schematic diagram of the output mechanism 3 of the light-weight nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 16 is a second structural schematic diagram of the output mechanism 3 of the light-weight nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

Fig. 17 is a third schematic structural diagram of the output mechanism 3 of the light nanomaterial mixing apparatus for mixing nanomaterials of the present invention.

In the figure: an input mechanism 1; power shaft a 1-1; 1-2 of a propeller; connecting ring sealing plates 1-3; 1-4 of a connecting ring; a tapered input block 1-5; 1-6 of an input pipe; connection board a 1-7; 1-8 of a connecting box; connecting plate b 1-9; 1-10 parts of a return pipe; 1-11 parts of triangular blocks; 1-12 of a lifting plate; 1-13 of a chute; output chutes 1-14; a mixing linkage mechanism 2; a power shaft b 2-1; rotating the disc 2-2; mounting plate a 2-3; stirring the column 2-4; mounting plate b 2-5; spring a 2-6; 2-7 of a poking plate; hinge plate a 2-8; hinge plate chutes 2-9; mounting plate c 2-10; connecting shafts I2-11; mounting plate d 2-12; spring c 2-13; hinge plate b 2-14; mounting plate f 2-15; connecting shafts II 2-16; mounting plate g 2-17; spring b 2-18; connecting shafts III 2-19; 2-20 parts of friction column; mounting plate e 2-21; 2-22 parts of a mixing tank; belts a 2-23; connecting shafts are four 2-24; belts b 2-25; connecting shafts five 2-26; reaction force propellers a 2-27; 2-28 parts of rubber hose; 2-29 parts of small friction wheel; connecting shaft six 2-30; 2-31 parts of a large friction wheel; 2-32 parts of mixing ring; 2-33 of a mixing plate; mounting blocks 1-34; liquid guide plates 2-35; linkage friction wheels 2-36; connecting shafts seven 2-37; reaction force propellers b 2-38; an output mechanism 3; an output belt 3-1; a transmission shaft 3-2; 3-3 of a special-shaped friction wheel; 3-4 parts of a torsion spring; 3-5 of a driven wheel; 3-6 parts of a driven shaft; 3-7 of a first connecting plate; 3-8 of a second connecting plate; 3-9 parts of a connecting plate III; 3-10 parts of a connecting plate; pushing the shaft 3-11.

Detailed Description

The first embodiment is as follows:

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, and fig. 17, and the present invention relates to a light nanomaterial mixing apparatus, and more specifically, to a light nanomaterial mixing apparatus for nanomaterial mixing, which includes an input mechanism 1, a mixing link mechanism 2, and an output mechanism 3, and is capable of inputting a nanomaterial and a liquid into a mixing tank, collecting the nanomaterial at the center of a liquid surface by rotating the liquid, discharging the adsorbed liquid in the middle of the mixing tank toward the nanomaterial collected at the center of the apparatus to accelerate the nanomaterial to dissolve the nanomaterial in the liquid, and automatically discharging the mixed mixture from the apparatus.

The input mechanism 1 is connected with the mixing linkage mechanism 2, the mixing linkage mechanism 2 is connected with the output mechanism 3, and the output mechanism 3 is connected with the input mechanism 1.

The second embodiment is as follows:

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 the embodiment further describes the embodiment, where the input mechanism 1 includes a power shaft a1-1, a propeller 1-2, a connecting ring sealing plate 1-3, a connecting ring 1-4, a conical input block 1-5, an input pipe 1-6, a connecting plate a1-7, a connecting box 1-8, a connecting plate b1-9, a return pipe 1-10, a triangular block 1-11, a lifting plate 1-12, a chute 1-13, and an output groove 1-14, the power shaft a1-1 is connected with the propeller 1-2, the power shaft a1-1 is connected with the connecting ring sealing plate 1-3 by bearings, a power shaft a1-1 is connected with a connecting plate b1-9 through a bearing, a propeller 1-2 is connected with a connecting ring 1-4 in a sliding way, two connecting ring sealing plates 1-3 are connected with the connecting ring 1-4, the connecting ring sealing plates 1-3 are connected with a conical input block 1-5, holes on the connecting ring sealing plates 1-3 are connected with an input pipe 1-6, holes on the conical input block 1-5 are connected with a return pipe 1-10, the input pipe 1-6 is connected with holes on a connecting plate a1-7, the connecting plate a1-7 is connected with a connecting box 1-8, the connecting box 1-8 is connected with a connecting plate b1-9, holes on the connecting box 1-8 are connected with the return pipe 1-10, the connecting box 1-8 is connected with a lifting plate 1-12 in a sliding way, the connecting box 1-8 is connected with a sliding groove 1-13, the connecting box 1-8 is connected with the output groove 1-14, the triangular block 1-11 is connected with the lifting plate 1-12, the lifting plate 1-12 is connected with the sliding groove 1-13 in a sliding manner, the equipment can input nano materials and liquid into the mixing box, the power shaft a1-1 rotates, the power shaft a1-1 rotates to drive the propeller 1-2 to rotate, the propeller 1-2 can blow air upwards when rotating, the nano materials and the liquid are placed in the conical input block 1-5, the adsorption force generated by the propeller 1-2 can adsorb the materials in the conical input block 1-5 through the space formed by the two connecting ring sealing plates 1-3 and the connecting rings 1-4, the adsorbed materials are discharged into the connecting box 1-8 through the input pipe 1-6, when the height of the nano materials and the liquid is higher than that of the return pipe 1-10, the nanomaterial and liquid will flow back into the conical input block 1-5 through the return tube 1-10.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16 and 17. this embodiment further describes the embodiment, and the embodiment includes a power shaft b2-1, a rotating disk 2-2, a mounting plate a2-3, a toggle column 2-4, a mounting plate b2-5, a spring a2-6, a toggle plate 2-7, a hinge plate a2-8, a hinge plate runner 2-9, a mounting plate c2-10, a connecting shaft one 2-11, a mounting plate d2-12, a spring c2-13, a hinge plate b2-14, a mounting plate f2-15, a connecting shaft two 2-16, a mounting plate g2-17, a spring b2-18, a connecting shaft three 2-19, 2-19, 2-20 parts of friction column, 2-22 parts of mounting plate e2-21 parts of mixing tank, 2-22 parts of belt a2-23 parts of connecting shaft four, 2-24 parts of belt b2-25 parts of connecting shaft five, 2-26 parts of reaction force propeller a2-27 parts of rubber hose 2-28 parts of small friction wheel 2-29 parts of connecting shaft six, 2-30 parts of large friction wheel 2-31 parts of mixing ring 2-32 parts of mixing plate 2-33 parts of mounting block 1-34 parts of liquid guide plate 2-35 parts of linkage friction wheel 2-36 parts of connecting shaft seven 2-37 parts of reaction force propeller b2-38 parts of reaction force propeller b, 2-2 parts of power shaft b2-1 parts of rotating disc, 2-1 parts of power shaft b is connected with belt a2-23 parts of friction, 1-8 parts of power shaft b2-1 parts of connecting box by bearing, 2-2 parts of rotating disc is connected with mounting plate a2-3 parts of rotating disc in a sliding way, the rotary disk 2-2 is connected with a mounting plate b2-5, a mounting plate a2-3 is connected with a toggle column 2-4 in a sliding way, the toggle column 2-4 is connected with a mounting plate b2-5, a spring a2-6 is sleeved on the toggle column 2-4 and limited on the mounting plate a2-3 and the mounting plate b2-5, a toggle plate 2-7 is connected with a hinged plate a2-8, the hinged plate a2-8 is connected with a hinged plate sliding groove 2-9 in a sliding way, the hinged plate a2-8 is connected with a mounting plate c2-10, the hinged plate a2-8 is hinged with a hinged plate b2-14, the sliding groove 2-9 is connected with a connecting box 1-8, the mounting plate c2-10 is connected with a connecting shaft-2-11, the connecting shaft-2 is connected with a mounting plate d2-12 in a sliding way, the mounting plate d2, a spring c2-13 is sleeved on the first connecting shaft 2-11 and limited by the mounting plates c2-10 and d2-12, a hinged plate b2-14 is in sliding connection with the mounting plate f2-15, a hinged plate b2-14 is in friction connection with the third connecting shaft 2-19, a mounting plate f2-15 is in connection with the second connecting shaft 2-16, a mounting plate f2-15 is in sliding connection with the connecting box 1-8, a connecting shaft second 2-16 is in sliding connection with the mounting plate g2-17, a mounting plate g2-17 is in connection with the connecting box 1-8, a spring b2-18 is sleeved on the second connecting shaft 2-16 and limited by the mounting plate f2-15 and the mounting plate g2-17, the third connecting shaft 2-19 is in connection with the friction columns 2-20, the third connecting shaft 2-19 is in bearing connection with the connecting box 1-8, the friction column 2-20 is connected with the mounting plate e2-21 in a friction way, the mounting plate e2-21 is connected with the mixing tank 2-22, the mounting plate e2-21 is connected with the connecting plate a1-7 in a sliding way, holes on the mixing tank 2-22 are connected with the rubber hose 2-28, the mixing tank 2-22 is connected with the liquid guide plate 2-35, the mixing tank 2-22 is connected with the connecting shaft seven 2-37 in a bearing way, the mixing tank 2-22 is connected with the connecting box 1-8 in a sliding way, the belt a2-23 is connected with the connecting shaft four 2-24 in a friction way, the belt a2-23 is connected with the small friction wheel 2-29 in a friction way, the connecting shaft four 2-24 is connected with the belt b2-25 in a friction way, the connecting shaft four 2-24 is connected with the reaction propeller a2-27 in a friction way, the connecting shaft four 2-24 is connected with the connecting box 1-8 in a bearing way, the belt b2-25 is in friction connection with the connecting shaft five 2-26, the connecting shaft five 2-26 is in bearing connection with the connecting box 1-8, the rubber hose 2-28 is in bearing connection with the hole on the connecting box 1-8, the small friction wheel 2-29 is in connection with the connecting shaft six 2-30, the connecting shaft six 2-30 is in connection with the large friction wheel 2-31, the connecting shaft six 2-30 is in bearing connection with the mounting block 1-34, the large friction wheel 2-31 is in friction connection with the mixing ring 2-32, the mixing ring 2-32 is in connection with the mixing plate 2-33, the mixing ring 2-32 is in bearing connection with the mounting block 1-34, the mounting block 1-34 is in connection with the connecting box 1-8, the linkage friction wheel 2-36 is in connection with the connecting shaft seven 2-37, the connecting shaft seven 2-37 is in connection with the reaction force propeller b2-38, the equipment can rotate liquid to gather nano materials in the center of the liquid level, the equipment can discharge the liquid adsorbed in the middle of the mixing box to the nano materials gathered in the center of the equipment to enable the nano materials to be dissolved in the liquid in an accelerated manner, the power shaft b2-1 rotates, the power shaft b2-1 rotates to drive the connecting shaft IV 2-24 to rotate through the belt a2-23, the belt a2-23 rotates to rotate through the small friction wheel 2-29, the small friction wheel 2-29 rotates to drive the large friction wheel 2-31 to rotate in an accelerated manner through the connecting shaft VI 2-30, the large friction wheel 2-31 rotates to drive the mixing ring 2-32 to rotate, when the mixing ring 2-32 rotates to drive the mixing plate 2-33 to rotate, the liquid and the nano materials in a space formed by the connecting plate a1-7, the connecting box 1-8 and the connecting plate b1-9 rotate, at the moment, the nano-materials are gathered in the center of the liquid level, the power shaft b2-1 rotates to drive the rotating disc 2-2 to rotate, the rotating disc 2-2 rotates to drive the toggle column 2-4 to rotate through the mounting plate a2-3 and the mounting plate b2-5, the toggle column 2-4 rotates to toggle the toggle plate 2-7, the toggle column 2-4 can automatically reset under the action of the spring a2-6, the toggled toggle plate 2-7 drives the hinged plate a2-8 to slide under the limitation of the hinged plate sliding groove 2-9, the hinged plate sliding groove 2-9 can automatically reset under the action of the spring c2-13, the toggle plate 2-7 moves the hinged plate b2-14 to move, the hinged plate b2-14 always has a friction connection relation with the connecting shaft III 2-19 under the action of the spring b2-18, the hinged plate b2-14 moves to drive the connecting shaft III 2-19 to rotate, the connecting shaft III 2-19 rotates to drive the mounting plate e2-21 to move downwards and then reset through the friction column 2-20, the mounting plate e2-21 moves to drive the mixing tank 2-22 to move, the mixing tank 2-22 moves downwards to the limit position when the connecting shaft V2-26 contacts with the mixing tank 2-22, the nano material gathered at the center of the liquid level is pressed into the liquid by the mixing tank 2-22 at the moment, the belt b2-25 and the linkage friction wheel 2-36 are in friction connection, the connecting shaft IV 2-24 rotates to drive the connecting shaft V2-26 to rotate through the belt b2-25, the belt b2-25 moves to drive the linkage friction wheel 2-36 which moves downwards, the linkage friction wheel 2-36 rotates to drive the reaction force b2 through the seven 2-37 38, the reaction force propellers b2-38 rotate to blow the liquid to the direction of the linkage friction wheel 2-36, when the connecting shaft four 2-24 rotates, the liquid in the connecting box 1-8 is also driven to be discharged to the liquid guide plate 2-35 in the mixing tank 2-22 through the rubber hose 2-28, and the discharged liquid enables the nano material to be dissolved in the liquid in an accelerated mode through the reaction force propellers b 2-38.

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 the embodiment further describes the embodiment, where the output mechanism 3 includes an output belt 3-1, a transmission shaft 3-2, a profile friction wheel 3-3, a torsion spring 3-4, a driven wheel 3-5, a driven shaft 3-6, a first connecting plate 3-7, a second connecting plate 3-8, a third connecting plate 3-9, a fourth connecting plate 3-10, a pushing shaft 3-11, the output belt 3-1 is in frictional connection with the transmission shaft 3-2, the output belt 3-1 is in frictional connection with a connection shaft six 2-30, the transmission shaft 3-2 is in connection with the profile friction wheel 3-3, a transmission shaft 3-2 is in bearing connection with a connecting plate b1-9, a torsion spring 3-4 is sleeved on the transmission shaft 3-2 and limited on a special-shaped friction wheel 3-3 and a connecting plate b1-9, a driven wheel 3-5 is connected with a driven shaft 3-6, the driven shaft 3-6 is in bearing connection with a connecting plate b1-9, a connecting plate I3-7 is connected with a connecting plate II 3-8, a connecting plate I3-7 at one side is in friction connection with the special-shaped friction wheel 3-3, a connecting plate I3-7 at the other side is in friction connection with a driven wheel 3-5, a connecting plate II 3-8 is in sliding connection with a connecting plate b1-9, a connecting plate III 3-9 is connected with a pushing shaft 3-11, a connecting plate IV 3-10 is connected with a pushing shaft 3-11, and a pushing shaft 3-11 is in bearing connection with the connecting plate I3-7 at two sides, the device can automatically discharge the mixed mixture out of the device, when the connecting shaft six 2-30 rotates reversely, the output belt 3-1 drives the transmission shaft 3-2 to rotate, the transmission shaft 3-2 rotates to drive the special-shaped friction wheel 3-3 to rotate, the special-shaped friction wheel 3-3 rotates to intermittently drive the connecting plate one 3-7 to move towards the lifting plate 1-12, the special-shaped friction wheel 3-3 can automatically reset under the action of the torsion spring 3-4, the connecting plate one 3-7 moves to drive the connecting plate two 3-8 and the pushing shaft 3-11 to move, when the pushing shaft 3-11 moves, the mixed mixture applies thrust to the triangular blocks 1-11 under the action of the connecting plate three 3-9 and the connecting plate four 3-10, and the triangular blocks 1-11 drive the lifting plate 1-12 to move upwards under the limitation of the sliding grooves 1-13 under the action of the shape characteristics of the triangular blocks 1-11 The triangular blocks 1-11 are moved upwards to gradually separate from the output troughs 1-14, at which point the mixed mixture can exit the apparatus.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, and further described with reference to the first embodiment, in which the power shaft a1-1 and the power shaft b2-1 are provided with power sources capable of rotating.

The working principle of the device is as follows: the device can input nano materials and liquid into a mixing box, a power shaft a1-1 rotates, the power shaft a1-1 rotates to drive a propeller 1-2 to rotate, the propeller 1-2 can blow air upwards when rotating, the nano materials and the liquid are placed in a conical input block 1-5, the adsorption force generated by the propeller 1-2 can adsorb materials in the conical input block 1-5 through a space formed by two connecting ring sealing plates 1-3 and connecting rings 1-4, the adsorbed materials are discharged into a connecting box 1-8 through an input pipe 1-6, when the height of the nano materials and the liquid is higher than that of a return pipe 1-10, the nano materials and the liquid can flow back to the conical input block 1-5 through the return pipe 1-10, the device can rotate the liquid to gather the nano materials in the center of the liquid level, the equipment can discharge the liquid adsorbed in the middle of the mixing box to the nano material gathered in the center of the equipment to enable the nano material to be dissolved in the liquid in an accelerated manner, the power shaft b2-1 rotates, the power shaft b2-1 rotates to drive the connecting shaft IV 2-24 to rotate through the belt a2-23, the belt a2-23 rotates to rotate through the small friction wheel 2-29, the small friction wheel 2-29 rotates to drive the large friction wheel 2-31 to rotate in an accelerated manner through the connecting shaft VI 2-30, the large friction wheel 2-31 rotates to drive the mixing ring 2-32 to rotate, the liquid and the nano material in the space formed by the connecting plate a1-7, the connecting box 1-8 and the connecting plate b1-9 rotate when the mixing ring 2-32 rotates to drive the mixing plate 2-33 to rotate, the nano material gathers in the center of the liquid level, the power shaft b2-1 rotates to drive the rotating disc 2-2 to rotate, the rotating disc 2-2 rotates to drive the toggle column 2-4 to rotate through the mounting plate a2-3 and the mounting plate b2-5, the toggle column 2-4 is toggled when the toggle column 2-4 rotates, the toggle column 2-4 can automatically reset under the action of the spring a2-6, the toggled toggle plate 2-7 drives the hinge plate a2-8 to slide under the limitation of the hinge plate sliding groove 2-9, the hinge plate sliding groove 2-9 can automatically reset under the action of the spring c2-13, the toggle plate 2-7 moves the hinge plate b2-14, the hinge plate b2-14 always generates friction connection with the connecting shaft three 2-19 under the action of the spring b2-18, the hinge plate b2-14 moves to drive the connecting shaft three 2-19 to rotate, the connecting shaft three 2-19 rotates to drive the mounting plate e2-21 to reset after first moving downwards through the friction column 2-20, the mounting plate e2-21 moves to drive the mixing tank 2-22 to move, the mixing tank 2-22 moves downwards until the connecting shaft five 2-26 contacts, the mixing tank 2-22 presses the nano material gathered at the center of the liquid level into the liquid, the belt b2-25 and the linkage friction wheel 2-36 are in friction connection, the connecting shaft four 2-24 rotates to drive the connecting shaft five 2-26 to rotate through the belt b2-25, the belt b2-25 moves to drive the linkage friction wheel 2-36 which moves downwards to rotate, the linkage friction wheel 2-36 rotates to drive the reaction force propeller b2-38 to rotate through the connecting shaft seven 2-37, the reaction force propeller b2-38 rotates to blow the liquid to the linkage friction wheel 2-36, when the connecting shaft IV 2-24 rotates, the liquid in the connecting box 1-8 is also driven to be discharged onto the liquid guide plate 2-35 in the mixing tank 2-22 through the rubber hose 2-28, the discharged liquid enables the nano material to be dissolved in the liquid in an accelerating way through the reaction force propeller b2-38, the equipment can automatically discharge the mixed mixture out of the equipment, when the connecting shaft VI 2-30 rotates reversely, the output belt 3-1 drives the transmission shaft 3-2 to rotate, the transmission shaft 3-2 rotates to drive the special-shaped friction wheel 3-3 to rotate, the special-shaped friction wheel 3-3 rotates intermittently to drive the connecting plate I3-7 to move towards the lifting plate 1-12, the special-shaped friction wheel 3-3 can automatically reset under the action of the torsion spring 3-4, the connecting plate I3-7 moves to drive the connecting plate II 3-8 and the pushing shaft 3-11 to move, when the pushing shaft 3-11 moves, under the action of the third connecting plate 3-9 and the fourth connecting plate 3-10, the mixed mixture applies thrust to the triangular blocks 1-11, the triangular blocks 1-11 drive the lifting plates 1-12 to move upwards under the limitation of the sliding grooves 1-13 under the action of the shape characteristics of the triangular blocks 1-11, the triangular blocks 1-11 move upwards to be gradually separated from the output grooves 1-14, and at the moment, the mixed mixture can be discharged out of the equipment.

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 (5)

1. The utility model provides a nanometer material mixes uses light nanometer material mixing apparatus, includes input mechanism (1), mixes link gear (2), output mechanism (3), its characterized in that: the input mechanism (1) is connected with the mixing linkage mechanism (2), the mixing linkage mechanism (2) is connected with the output mechanism (3), and the output mechanism (3) is connected with the input mechanism (1).

2. The lightweight nanomaterial mixing apparatus for nanomaterial mixing according to claim 1, characterized in that: the input mechanism (1) comprises a power shaft a (1-1), a propeller (1-2), a connecting ring sealing plate (1-3), a connecting ring (1-4), a conical input block (1-5), an input pipe (1-6), a connecting plate a (1-7), a connecting box (1-8), a connecting plate b (1-9), a backflow pipe (1-10), a triangular block (1-11), a lifting plate (1-12), a sliding groove (1-13) and an output groove (1-14), wherein the power shaft a (1-1) is connected with the propeller (1-2), the power shaft a (1-1) is connected with the connecting ring sealing plate (1-3) through a bearing, the power shaft a (1-1) is connected with the connecting plate b (1-9) through a bearing, the propeller (1-2) is connected with the connecting ring (1-4) in a sliding manner, two connecting ring sealing plates (1-3) are connected with connecting rings (1-4), the connecting ring sealing plates (1-3) are connected with conical input blocks (1-5), holes on the connecting ring sealing plates (1-3) are connected with input pipes (1-6), holes on the conical input blocks (1-5) are connected with return pipes (1-10), the input pipes (1-6) are connected with holes on connecting plates a (1-7), the connecting plates a (1-7) are connected with connecting boxes (1-8), the connecting boxes (1-8) are connected with connecting plates b (1-9), holes on the connecting boxes (1-8) are connected with the return pipes (1-10), the connecting boxes (1-8) are connected with lifting plates (1-12) in a sliding manner, the connecting boxes (1-8) are connected with sliding chutes (1-13), the connecting box (1-8) is connected with the output groove (1-14), the triangular block (1-11) is connected with the lifting plate (1-12), and the lifting plate (1-12) is connected with the sliding groove (1-13) in a sliding manner.

3. The lightweight nanomaterial mixing apparatus for nanomaterial mixing according to claim 1, characterized in that: the hybrid linkage mechanism (2) comprises a power shaft b (2-1), a rotating disk (2-2), a mounting plate a (2-3), a toggle column (2-4), a mounting plate b (2-5), a spring a (2-6), a toggle plate (2-7), a hinge plate a (2-8), a hinge plate sliding groove (2-9), a mounting plate c (2-10), a connecting shaft I (2-11), a mounting plate d (2-12), a spring c (2-13), a hinge plate b (2-14), a mounting plate f (2-15), a connecting shaft II (2-16), a mounting plate g (2-17), a spring b (2-18), a connecting shaft III (2-19), a friction column (2-20), a mounting plate e (2-21), A mixing tank (2-22), a belt a (2-23), a connecting shaft four (2-24), a belt b (2-25), a connecting shaft five (2-26), a reaction force propeller a (2-27), a rubber hose (2-28), a small friction wheel (2-29), a connecting shaft six (2-30), a large friction wheel (2-31), a mixing ring (2-32), a mixing plate (2-33), a mounting block (1-34), a liquid guide plate (2-35), a linkage friction wheel (2-36), a connecting shaft seven (2-37) and a reaction force propeller b (2-38), wherein a power shaft b (2-1) is connected with the rotating disc (2-2), and a power shaft b (2-1) is connected with the belt a (2-23) in a friction way, the power shaft b (2-1) is connected with the connecting box (1-8) through a bearing, the rotating disc (2-2) is connected with the mounting plate a (2-3) in a sliding manner, the rotating disc (2-2) is connected with the mounting plate b (2-5), the mounting plate a (2-3) is connected with the toggle column (2-4) in a sliding manner, the toggle column (2-4) is connected with the mounting plate b (2-5), the spring a (2-6) is sleeved on the toggle column (2-4) and limited on the mounting plate a (2-3) and the mounting plate b (2-5), the toggle plate (2-7) is connected with the hinged plate a (2-8), the hinged plate a (2-8) is connected with the hinged plate sliding groove (2-9) in a sliding manner, and the hinged plate a (2-8) is connected with the mounting plate c (2-10), the hinged plate a (2-8) is hinged with the hinged plate b (2-14), the hinged plate sliding groove (2-9) is connected with the connecting box (1-8), the mounting plate c (2-10) is connected with the connecting shaft I (2-11), the connecting shaft I (2-11) is connected with the mounting plate d (2-12) in a sliding way, the mounting plate d (2-12) is connected with the connecting box (1-8), the spring c (2-13) is sleeved on the connecting shaft I (2-11) and limited on the mounting plate c (2-10) and the mounting plate d (2-12), the hinged plate b (2-14) is connected with the mounting plate f (2-15) in a sliding way, the hinged plate b (2-14) is connected with the connecting shaft III (2-19) in a friction way, and the mounting plate f (2-15) is connected with the connecting shaft II (2-16), the mounting plate f (2-15) is connected with the connecting box (1-8) in a sliding manner, the connecting shaft II (2-16) is connected with the mounting plate g (2-17) in a sliding manner, the mounting plate g (2-17) is connected with the connecting box (1-8), the spring b (2-18) is sleeved on the connecting shaft II (2-16) and limited on the mounting plate f (2-15) and the mounting plate g (2-17), the connecting shaft III (2-19) is connected with the friction column (2-20), the connecting shaft III (2-19) is connected with the connecting box (1-8) through a bearing, the friction column (2-20) is connected with the mounting plate e (2-21) in a friction manner, the mounting plate e (2-21) is connected with the mixing groove (2-22), and the mounting plate e (2-21) is connected with the connecting plate a (1-7) in a sliding manner, holes on the mixing tank (2-22) are connected with rubber hoses (2-28), the mixing tank (2-22) is connected with liquid guide plates (2-35), the mixing tank (2-22) is connected with a connecting shaft seven (2-37) through bearings, the mixing tank (2-22) is connected with a connecting box (1-8) in a sliding manner, a belt a (2-23) is connected with a connecting shaft four (2-24) in a friction manner, the belt a (2-23) is connected with a small friction wheel (2-29) in a friction manner, the connecting shaft four (2-24) is connected with a belt b (2-25) in a friction manner, the connecting shaft four (2-24) is connected with a reaction force propeller a (2-27), the connecting shaft four (2-24) is connected with the connecting box (1-8) through bearings, and the belt b (2-25) is connected with a connecting shaft five (2-26) in a friction manner, a fifth connecting shaft (2-26) is in bearing connection with a connecting box (1-8), a rubber hose (2-28) is in hole connection with the connecting box (1-8), a small friction wheel (2-29) is in bearing connection with a sixth connecting shaft (2-30), the sixth connecting shaft (2-30) is in connection with a large friction wheel (2-31), the sixth connecting shaft (2-30) is in bearing connection with a mounting block (1-34), the large friction wheel (2-31) is in friction connection with a mixing ring (2-32), the mixing ring (2-32) is connected with a mixing plate (2-33), the mixing ring (2-32) is in bearing connection with the mounting block (1-34), the mounting block (1-34) is connected with the connecting box (1-8), and a linkage friction wheel (2-36) is connected with a seventh connecting shaft (2-37), the connecting shaft seven (2-37) is connected with the reaction force propeller b (2-38).

4. The lightweight nanomaterial mixing apparatus for nanomaterial mixing according to claim 1, characterized in that: the output mechanism (3) comprises an output belt (3-1), a transmission shaft (3-2), a special-shaped friction wheel (3-3), a torsion spring (3-4), a driven wheel (3-5), a driven shaft (3-6), a first connecting plate (3-7), a second connecting plate (3-8), a third connecting plate (3-9), a fourth connecting plate (3-10) and a pushing shaft (3-11), the output belt (3-1) is in friction connection with the transmission shaft (3-2), the output belt (3-1) is in friction connection with a sixth connecting shaft (2-30), the transmission shaft (3-2) is connected with the special-shaped friction wheel (3-3), the transmission shaft (3-2) is in bearing connection with the connecting plate b (1-9), the torsion spring (3-4) is sleeved on the transmission shaft (3-2) and is limited on the special-shaped friction wheel (3-3) The driving wheel is connected with the driven shafts (3-6) through connecting plates b (1-9), the driven wheels (3-5) are connected with the driven shafts (3-6), the driven shafts (3-6) are in bearing connection with the connecting plates b (1-9), the connecting plates I (3-7) are connected with the connecting plates II (3-8), the connecting plates I (3-7) on one side are in friction connection with the special-shaped friction wheels (3-3), the connecting plates I (3-7) on the other side are in friction connection with the driven wheels (3-5), the connecting plates II (3-8) are in sliding connection with the connecting plates b (1-9), the connecting plates III (3-9) are connected with pushing shafts (3-11), the connecting plates IV (3-10) are connected with the pushing shafts (3-11), and the pushing shafts (3-11) are in bearing connection with the connecting plates I (3-7) on the two sides.

5. The lightweight nanomaterial mixing apparatus for nanomaterial mixing according to claim 1, characterized in that: and power sources arranged on the power shaft a (1-1) and the power shaft b (2-1) can rotate.

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