阅读说明：本技术 一种轻物质湿法分离设备 (Light material wet separation equipment ) 是由 杨国余 于 2020-12-08 设计创作，主要内容包括：本发明涉及一种取样设备,更具体的说是一种轻物质湿法分离设备,包括传送机构、搅拌联动机构、输出机构,设备能够夹紧将水与轻物质混合物传送至搅拌桶中,设备能能够将水与轻物质混合物搅拌混合,设备能够通过旋转时产生的离心力将轻物质旋转至设备安装圈上,设备能够将设备安装圈上的轻物质向下吹动倾斜板上,设备能够将轻物质传送出设备,传送机构与搅拌联动机构连接,搅拌联动机构与输出机构连接,输出机构与传送机构连接。(The invention relates to sampling equipment, in particular to light material wet separation equipment which comprises a conveying mechanism, a stirring linkage mechanism and an output mechanism, wherein the equipment can clamp and convey a mixture of water and light materials into a stirring barrel, the equipment can stir and mix the mixture of the water and the light materials, the equipment can rotate the light materials onto an equipment mounting ring through centrifugal force generated during rotation, the equipment can blow the light materials on the equipment mounting ring downwards onto an inclined plate, the equipment can convey the light materials out of the equipment, the conveying mechanism is connected with the stirring linkage mechanism, the stirring linkage mechanism is connected with the output mechanism, and the output mechanism is connected with the conveying mechanism.)

1. The utility model provides a light material wet separation equipment, includes transport mechanism (1), stirring link gear (2), output mechanism (3), its characterized in that: the conveying mechanism (1) is connected with the stirring linkage mechanism (2), the stirring linkage mechanism (2) is connected with the output mechanism (3), and the output mechanism (3) is connected with the conveying mechanism (1).

2. A light material wet separation apparatus as claimed in claim 1, wherein: the conveying mechanism (1) comprises a motor mounting seat (1-1), a motor (1-2), a motor shaft (1-3), a sealing plate (1-4) at the lower part of the stirring barrel, the stirring barrel (1-5), a stirring barrel connecting plate (1-6), an equipment mounting ring (1-7), a connecting plate a (1-8), a connecting plate b (1-9), a belt a (1-10), a connecting shaft a (1-11), a belt b (1-12), a connecting shaft b (1-13), a connecting plate c (1-14), a belt c (1-15), a friction ring (1-16), a propeller mounting ring (1-17), a propeller (1-18), a rotating shaft (1-19), an output connecting ring (1-20), an input pipe (1-21), The device comprises feeding pipes (1-22), feeding pipe limiting plates (1-23), connecting plates d (1-24), handles (1-25), feeding boxes (1-26), separating plates (1-27), sliding limiting plates (1-28), feeding arc pipes (1-29), conical feeding barrels (1-30) and equipment mounting plates (1-31), wherein a motor mounting seat (1-1) is connected with a motor (1-2), the motor mounting seat (1-1) is connected with a lower sealing plate (1-4) of the stirring barrel, the motor (1-2) is connected with a motor shaft (1-3), the motor shaft (1-3) is connected with a lower sealing plate (1-4) of the stirring barrel in a bearing manner, and the motor shaft (1-3) is connected with a connecting plate a (1-8) in a bearing manner, a motor shaft (1-3) is in friction connection with a belt a (1-10), a stirring barrel (1-5) is connected with a stirring barrel connecting plate (1-6), the stirring barrel connecting plate (1-6) is connected with an equipment mounting ring (1-7), two stirring barrel connecting plates (1-6) on one side are in bearing connection with a connecting shaft a (1-11), the equipment mounting ring (1-7) is connected with a connecting plate a (1-8), the equipment mounting ring (1-7) is connected with a connecting plate c (1-14), the equipment mounting ring (1-7) is connected with an output connecting ring (1-20), the equipment mounting ring (1-7) is connected with an equipment mounting plate (1-31), the connecting plate a (1-8) is connected with a connecting plate b (1-9), the connecting plate a (1-8) is in bearing connection with a connecting shaft b (1-13), the connecting plates b (1-9) are connected and communicated with the input pipes (1-21), the belts a (1-10) are in friction connection with the connecting shafts a (1-11), the connecting shafts a (1-11) are in friction connection with the belts b (1-12), the belts b (1-12) are in friction connection with the connecting shafts b (1-13), the connecting shafts b (1-13) are in bearing connection with the connecting plates c (1-14), the connecting plates c (1-14) are connected and communicated with the input pipes (1-21), the belts c (1-15) are in friction connection with the two connecting shafts b (1-13), the belts c (1-15) are in friction connection with the friction rings (1-16), the friction rings (1-16) are connected with the propeller mounting rings (1-17), the propeller mounting rings (1-17) are connected with the propellers (1-18), the propeller mounting ring (1-17) is in bearing connection with the output connecting ring (1-20), the propeller mounting ring (1-17) is in bearing connection with the feeding pipe (1-22), the propeller (1-18) is connected with the rotating shaft (1-19), the output connecting ring (1-20) is connected and communicated with the input pipe (1-21), the feeding pipe (1-22) is connected with the feeding pipe limiting plate (1-23), the feeding pipe (1-22) is connected with the connecting plate d (1-24), the feeding pipe (1-22) is in sliding connection with the feeding box (1-26), the feeding pipe limiting plate (1-23) is in sliding connection with the separating plate (1-27), and the feeding pipe limiting plate (1-23) is in sliding connection with the sliding limiting plate (1-28), the connecting plate d (1-24) is connected with the feeding box (1-26) in a sliding mode, the connecting plate d (1-24) is connected with the handle (1-25), the feeding box (1-26) is connected with the separating plate (1-27), the feeding box (1-26) is connected with the equipment mounting plate (1-31), one end of the sliding limiting plate (1-28) is connected with the separating plate (1-27) and the other end of the sliding limiting plate is connected with the feeding box (1-26), the sliding limiting plate (1-28) is connected with the feeding arc-shaped pipe (1-29), the feeding arc-shaped pipe (1-29) is connected with the conical feeding barrel (1-30), and the conical feeding barrel (1-30) is connected with the equipment mounting plate (1-31).

3. A light material wet separation apparatus as claimed in claim 1, wherein: the stirring linkage mechanism (2) comprises a bearing ring (2-1), a thread limiting strip (2-2), a thread transmission limiting plate (2-3), a thread conveying plate (2-4), a first belt (2-5), a propeller a (2-6), a fourth connecting shaft (2-7), a first friction wheel (2-8), a second belt (2-9), a second connecting shaft (2-10), a second connecting plate (2-11), a second friction wheel (2-12), a rotary sliding ring (2-13), a sliding ring connecting plate (2-14), a third connecting shaft (2-15), a third friction wheel (2-16) and a fourth friction wheel (2-17), wherein the bearing ring (2-1) is connected with the thread limiting strip (2-2), and the bearing ring (2-1) is connected with a stirring barrel (1-5) through a bearing, a bearing ring (2-1) is in frictional connection with a first friction wheel (2-8), a thread limiting strip (2-2) is connected with a thread transmission limiting plate (2-3), the thread limiting strip (2-2) is in sliding connection with a thread conveying plate (2-4), the thread conveying plate (2-4) is in sliding connection with a motor shaft (1-3), one end of a belt (2-5) is in frictional connection with the motor shaft (1-3), the other end of the belt is in frictional connection with a connecting shaft a (1-11), a propeller a (2-6) is connected with a fourth connecting shaft (2-7), the fourth connecting shaft (2-7) is in bearing connection with a sliding ring connecting plate (2-14), the fourth connecting shaft (2-7) is connected with a fourth friction wheel (2-17), the first friction wheel (2-8) is connected with a connecting shaft a (1-11), one end of a second belt (2-9) is in friction connection with a motor shaft (1-3) and the other end is in friction connection with a second connecting shaft (2-10), the second connecting shaft (2-10) is in bearing connection with a second connecting plate (2-11), the second connecting shaft (2-10) is in friction connection with a second friction wheel (2-12), the second connecting plate (2-11) is connected with an equipment mounting ring (1-7), the second friction wheel (2-12) is in friction connection with a second rotating sliding ring (2-13), the second rotating sliding ring (2-13) is in sliding connection with the equipment mounting ring (1-7), the second rotating sliding ring (2-13) is connected with a connecting plate (2-14) of the sliding ring, the connecting plate (2-14) of the sliding ring is in bearing connection with a third connecting shaft (2-15), the third connecting shaft (2-15) is connected with a third friction wheel (2-16), the third friction wheel (2-16) is in friction connection with the equipment mounting ring (1-7), and the third friction wheel (2-16) is in friction connection with the fourth friction wheel (2-17).

4. A light material wet separation apparatus as claimed in claim 1, wherein: the output mechanism (3) comprises a linkage belt (3-1), a linkage shaft (3-2), a mounting plate a (3-3), a cam (3-4), a mounting plate b (3-5), an output inclined plate (3-6), a reset supporting block (3-7), a reset shaft (3-8), a reset limiting plate (3-9), a reset tension spring (3-10), an output port (3-11) and an output inclined plate a (3-12), one end of the linkage belt (3-1) is in friction connection with a motor shaft (1-3), the other end of the linkage belt is in friction connection with the linkage shaft (3-2), the linkage shaft (3-2) is in bearing connection with the mounting plate a (3-3), the linkage shaft (3-2) is connected with the cam (3-4), the mounting plate a (3-3) is connected with an equipment mounting ring (1-7), the cam (3-4) is connected with the mounting plate b (3-5) in a sliding manner, the mounting plate b (3-5) is connected with the output inclined plate (3-6), the output inclined plate (3-6) is connected with the reset limiting plate (3-9), the output inclined plate (3-6) is connected with the equipment mounting ring (1-7) in a sliding manner, the reset supporting block (3-7) is connected with the reset shaft (3-8), the reset supporting block (3-7) is connected with the equipment mounting ring (1-7), the reset shaft (3-8) is connected with the reset limiting plate (3-9) in a sliding manner, the reset tension spring (3-10) is sleeved on the reset shaft (3-8) and limited on the reset supporting block (3-7) and the reset limiting plate (3-9), the output port (3-11) is opened on the equipment mounting ring (1-7), the output inclined plates a (3-12) are connected with the output inclined plates (3-6) in a sliding mode, and the output inclined plates a (3-12) are connected with the equipment mounting rings (1-7).

5. A light material wet separation apparatus as claimed in claim 1, wherein: the material of the feeding pipes (1-22) is high-elasticity rubber, and the length of the feeding pipes (1-22) is slightly longer than that of the feeding pipes shown in the figure.

Technical Field

The invention relates to wet separation equipment, in particular to light substance wet separation equipment.

Background

In the wet separation of the light substances, the process flow is more complicated, more operators are required to operate related equipment, but no better wet separation equipment exists in the market, so the wet separation equipment for the light substances is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing light substance wet separation equipment, the equipment can clamp and convey a mixture of water and light substances into a stirring barrel, the equipment can stir and mix the mixture of the water and the light substances, the equipment can rotate the light substances onto an equipment mounting ring through centrifugal force generated during rotation, the equipment can blow the light substances on the equipment mounting ring downwards onto an inclined plate, and the equipment can convey the light substances out of the equipment.

In order to solve the technical problem, the invention relates to a sampling device, in particular to a light material wet separation device which comprises a conveying mechanism, a stirring linkage mechanism and an output mechanism, wherein the device can clamp and convey a mixture of water and light materials into a stirring barrel, can stir and mix the mixture of the water and the light materials, can rotate the light materials to an equipment mounting ring through centrifugal force generated during rotation, can blow the light materials on the equipment mounting ring downwards onto an inclined plate, and can convey the light materials out of the device.

The conveying mechanism is connected with the stirring linkage mechanism, the stirring linkage mechanism is connected with the output mechanism, and the output mechanism is connected with the conveying mechanism.

As a further optimization of the technical scheme, the invention relates to light material wet separation equipment, wherein a conveying mechanism comprises a motor mounting seat, a motor shaft, a lower sealing plate of a stirring barrel, the stirring barrel, a connecting plate of the stirring barrel, an equipment mounting ring, a connecting plate a, a connecting plate b, a belt a, a connecting shaft a, a belt b, a connecting shaft b, a connecting plate c, a belt c, a friction ring, a screw mounting ring, a screw, a rotating shaft, an output connecting ring, an input pipe, a feeding pipe limiting plate, a connecting plate d, a handle, a feeding box, a separating plate, a sliding limiting plate, a feeding arc-shaped pipe, a conical feeding barrel and an equipment mounting plate, the motor mounting seat is connected with the motor, the motor mounting seat is connected with the lower sealing plate of the stirring barrel, the motor is connected with the motor shaft, the motor, the motor shaft is connected with a belt a in a friction way, the stirring barrels are connected with a connecting plate of the stirring barrels, the connecting plate of the stirring barrels is connected with an equipment mounting ring, two connecting plates of the stirring barrels on one side are connected with a bearing of a connecting shaft a, the equipment mounting ring is connected with a connecting plate a, the equipment mounting ring is connected with an output connecting ring, the equipment mounting ring is connected with an equipment mounting plate, the connecting plate a is connected with a connecting plate b, the connecting plate a is connected with a bearing of a connecting shaft b, the connecting plate b is connected and communicated with an input pipe, the belt a is connected with the connecting shaft a in a friction way, the connecting shaft a is connected with a belt b in a friction way, the belt b is connected with the connecting shaft b in a friction way, the connecting shaft b is connected with a bearing of the connecting plate c, the connecting plate c is connected and communicated with the input, screw installation circle and screw are connected, screw installation circle and output connection circle bearing connection, screw installation circle and inlet pipe bearing connection, the screw is connected with the rotation axis, output connection circle and input tube connection and intercommunication, inlet pipe and inlet pipe limited connection, the inlet pipe is connected with connecting plate d, inlet pipe and feeding case sliding connection, inlet pipe limited plate and stripper plate sliding connection, inlet pipe limited plate and slip limited plate sliding connection, connecting plate d and feeding case sliding connection, connecting plate d is connected with the handle, the feeding case is connected with the stripper plate, the feeding case is connected with the equipment fixing board, the one end and the stripper plate of slip limited plate are connected the other end and are connected with the feeding case, slip limited plate and feeding arc union coupling, the feeding arc is connected with toper feeding bucket, toper feeding bucket is connected with the equipment fixing board.

As a further optimization of the technical scheme, the invention relates to light material wet separation equipment, wherein a stirring linkage mechanism comprises a bearing ring, a thread limiting strip, a thread transmission limiting plate, a thread conveying plate, a first belt, a screw propeller a, a fourth connecting shaft, a first friction wheel, a second belt, a second connecting shaft, a second connecting plate, a second friction wheel, a rotary sliding ring, a sliding ring connecting plate, a third connecting shaft, a third friction wheel and a fourth friction wheel, the bearing ring is connected with the thread limiting strip, the bearing ring is connected with a stirring barrel bearing, the bearing ring is connected with the first friction wheel in a friction mode, the thread limiting strip is connected with the thread transmission limiting plate, the thread limiting strip is connected with the thread conveying plate in a sliding mode, the thread conveying plate is connected with a motor shaft in a sliding mode, one end of the belt is connected with the motor shaft in a friction mode, the screw propeller a is connected with the fourth connecting shaft, the connecting shaft four is connected with the friction wheel four, the friction wheel I is connected with a connecting shaft a, one end of the belt II is in friction connection with the motor shaft, the other end of the belt II is in friction connection with the connecting shaft II, the connecting shaft II is connected with the connecting plate II through a bearing, the connecting shaft II is connected with the friction wheel II, the connecting plate II is connected with the equipment installation ring, the friction wheel II is in friction connection with the rotary sliding ring, the rotary sliding ring is in sliding connection with the equipment installation ring, the rotary sliding ring is connected with the sliding ring connecting plate, the sliding ring connecting plate is connected with the connecting shaft three bearing, the connecting shaft III is connected with the friction wheel III, the friction wheel III is in friction connection with the equipment.

As a further optimization of the technical scheme, the invention relates to light material wet separation equipment, wherein an output mechanism comprises a linkage belt, a linkage shaft, a mounting plate a, a cam, a mounting plate b, an output inclined plate, a reset supporting block, a reset shaft, a reset limiting plate, a reset tension spring, an output port and an output inclined plate a, one end of the linkage belt is in friction connection with a motor shaft, the other end of the linkage belt is in friction connection with the linkage shaft, the linkage shaft is connected with a bearing of the mounting plate a, the mounting plate a is connected with an equipment mounting ring, the cam is in sliding connection with the mounting plate b, the mounting plate b is connected with the output inclined plate, the output inclined plate is connected with the reset limiting plate, the output inclined plate is in sliding connection with the equipment mounting ring, the reset supporting block is connected with the reset shaft, the reset shaft is in sliding connection with the reset limiting plate, the reset tension spring is sleeved on the reset, the output port is arranged on the equipment mounting ring, the output inclined plate a is connected with the output inclined plate in a sliding mode, and the output inclined plate a is connected with the equipment mounting ring.

As a further optimization of the technical scheme, the light material wet separation equipment is characterized in that the material of the feeding pipe is high-elasticity rubber, and the length of the feeding pipe is slightly longer than that of the feeding pipe shown in the figure.

The light material wet separation equipment has the beneficial effects that:

according to the light material wet separation equipment, the equipment can clamp and convey a mixture of water and light materials to the stirring barrel, the equipment can stir and mix the mixture of the water and the light materials, the equipment can rotate the light materials to the equipment mounting ring through centrifugal force generated during rotation, the equipment can blow the light materials on the equipment mounting ring downwards onto the inclined plate, and the equipment can convey the light materials 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 material wet separation device of the present invention.

Fig. 2 is a schematic structural diagram of a light material wet separation device of the present invention.

Fig. 3 is a schematic structural diagram of a light material wet separation device of the present invention.

Fig. 4 is a schematic structural diagram of a light material wet separation device of the present invention.

Fig. 5 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 6 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 7 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 8 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 9 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 10 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 11 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 12 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 13 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 14 is a schematic structural diagram of a light material wet separation device according to the present invention.

Fig. 15 is a schematic structural diagram of a light material wet separation device according to the present invention.

In the figure: a transfer mechanism 1; a motor mounting base 1-1; a motor 1-2; a motor shaft 1-3; sealing plates 1-4 at the lower part of the stirring barrel; 1-5 parts of a stirring barrel; connecting plates 1-6 of the stirring barrel; 1-7 of an equipment mounting ring; connection board a 1-8; connecting plate b 1-9; belt a 1-10; connecting shaft a 1-11; belt b 1-12; connecting shaft b 1-13; connecting plate c 1-14; belt c 1-15; 1-16 parts of friction ring; 1-17 of a propeller mounting ring; 1-18 of a propeller; a rotating shaft 1-19; output connecting rings 1-20; input pipes 1 to 21; 1-22 parts of a feeding pipe; feed pipe limiting plates 1-23; connecting plates d 1-24; 1-25 parts of a handle; a feed box 1-26; separation plates 1-27; sliding limit plates 1-28; feeding arc pipes 1-29; 1-30 parts of a conical feed barrel; equipment mounting plates 1-31; a stirring linkage mechanism 2; 2-1 of a bearing ring; 2-2 of a threaded limiting strip; 2-3 of a thread transmission limiting plate; 2-4 of a threaded transfer plate; 2-5 parts of a first belt; propeller a 2-6; connecting shaft IV 2-7; 2-8 parts of a first friction wheel; 2-9 parts of a second belt; 2-10 parts of a connecting shaft II; 2-11 parts of a second connecting plate; 2-12 parts of a second friction wheel; rotating the sliding ring 2-13; the sliding ring connecting plates 2-14; connecting shafts III 2-15; 2-16 parts of a friction wheel III; 2-17 parts of friction wheel; an output mechanism 3; a linkage belt 3-1; a linkage shaft 3-2; mounting plate a 3-3; 3-4 of a cam; mounting plate b 3-5; output tilt plates 3-6; 3-7 of a reset supporting block; 3-8 parts of a reset shaft; 3-9 parts of a reset limiting plate; 3-10 of a reset tension spring; output ports 3 to 11; the output inclined plate a 3-12.

Detailed Description

The first 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, and fig. 15, the present invention relates to a sampling device, and more specifically, to a light material wet separation device, which includes a transfer mechanism 1, a stirring linkage mechanism 2, and an output mechanism 3, the device is capable of transferring a mixture of water and light materials into a stirring barrel by clamping, the device is capable of stirring and mixing the mixture of water and light materials, the device is capable of rotating the light materials onto a device mounting ring by centrifugal force generated during rotation, the device is capable of blowing the light materials on the device mounting ring downward onto an inclined plate, and the device is capable of transferring the light materials out of the device.

The conveying mechanism 1 is connected with the stirring linkage mechanism 2, the stirring linkage mechanism 2 is connected with the output mechanism 3, and the output mechanism 3 is connected with the conveying mechanism 1.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, and the present embodiment further describes the present embodiment, where the conveying mechanism 1 includes a motor mounting base 1-1, a motor 1-2, a motor shaft 1-3, a sealing plate 1-4 at the lower part of the stirring barrel, a stirring barrel 1-5, a connecting plate 1-6 of the stirring barrel, an equipment mounting ring 1-7, a connecting plate a1-8, a connecting plate b1-9, a belt a1-10, a connecting shaft 1-11, a belt b1-12, a connecting shaft b1-13, a connecting plate c1-14, a belt c1-15, a friction ring 1-16, a propeller mounting ring 1-17, a propeller 1-18, a propeller, 1-19 parts of rotating shaft, 1-20 parts of output connecting ring, 1-21 parts of input pipe, 1-22 parts of feed pipe, 1-23 parts of feed pipe limiting plate, d1-24 parts of connecting plate, 1-25 parts of handle, 1-26 parts of feed box, 1-27 parts of separating plate, 1-28 parts of sliding limiting plate, 1-29 parts of feed arc pipe, 1-30 parts of conical feed barrel and 1-31 parts of equipment mounting plate, 1-1 parts of motor mounting seat is connected with 1-2 parts of motor, 1-1 parts of motor mounting seat is connected with 1-4 parts of lower sealing plate of mixing barrel, 1-2 parts of motor is connected with 1-3 parts of motor shaft, 1-3 parts of motor shaft is connected with 1-4 parts of lower sealing plate of mixing barrel by bearing, 1-3 parts of motor shaft is connected with a1-8 parts of connecting plate by bearing, the mixing tank 1-5 is connected with a mixing tank connecting plate 1-6, the mixing tank connecting plate 1-6 is connected with an equipment mounting ring 1-7, the two mixing tank connecting plates 1-6 at one side are connected with a connecting shaft a1-11 bearing, the equipment mounting ring 1-7 is connected with a connecting plate a1-8, the equipment mounting ring 1-7 is connected with a connecting plate c1-14, the equipment mounting ring 1-7 is connected with an output connecting ring 1-20, the equipment mounting ring 1-7 is connected with an equipment mounting plate 1-31, the connecting plate a1-8 is connected with a connecting plate b1-9, the connecting plate a1-8 is connected with a connecting shaft b1-13 bearing, the connecting plate b1-9 is connected and communicated with an input pipe 1-21, a belt a1-10 is connected with a connecting shaft a1-11 by friction, the connecting shaft a1-11 is in friction connection with a belt b1-12, the belt b1-12 is in friction connection with a connecting shaft b1-13, the connecting shaft b1-13 is in bearing connection with a connecting plate c1-14, the connecting plate c1-14 is connected and communicated with an input pipe 1-21, the belt c1-15 is in friction connection with two connecting shafts b1-13, the belt c1-15 is in friction connection with friction rings 1-16, the friction rings 1-16 are connected with propeller mounting rings 1-17, the propeller mounting rings 1-17 are connected with propellers 1-18, the propeller mounting rings 1-17 are in bearing connection with output connecting rings 1-20, the propeller mounting rings 1-17 are in bearing connection with feed pipes 1-22, the propellers 1-18 are connected with rotating shafts 1-19, the output connecting rings 1-20 are connected and communicated with input pipes 1-21, the feeding pipes 1 to 22 are connected with feeding pipe limiting plates 1 to 23, the feeding pipes 1 to 22 are connected with connecting plates d1 to 24, the feeding pipes 1 to 22 are slidably connected with feeding boxes 1 to 26, the feeding pipe limiting plates 1 to 23 are slidably connected with the feeding boxes 1 to 26, the feeding pipe limiting plates 1 to 23 are slidably connected with separating plates 1 to 27, the feeding pipe limiting plates 1 to 23 are slidably connected with sliding limiting plates 1 to 28, the connecting plates d1 to 24 are slidably connected with the feeding boxes 1 to 26, the connecting plates d1 to 24 are connected with handles 1 to 25, the feeding boxes 1 to 26 are connected with the separating plates 1 to 27, the feeding boxes 1 to 26 are connected with equipment mounting plates 1 to 31, one ends of the sliding limiting plates 1 to 28 are connected with the separating plates 1 to 27, and the other ends of the sliding limiting plates are connected with the feeding boxes 1, the sliding limit plate 1-28 is connected with the feeding arc-shaped pipe 1-29, the feeding arc-shaped pipe 1-29 is connected with the conical feeding barrel 1-30, the conical feeding barrel 1-30 is connected with the equipment mounting plate 1-31, the equipment can clamp and convey a mixture of water and light substances into the stirring barrel, the motor 1-2 works to drive the motor shaft 1-3 to rotate clockwise, the motor shaft 1-3 rotates to drive the connecting shaft a1-11 to rotate through the belt a1-10, the connecting shaft a1-11 rotates to drive the connecting shaft b1-13 to rotate through the belt b1-12, the connecting shaft b1-13 rotates to drive the other connecting shaft b1-13 to rotate through the belt c1-15, and the belt c1-15 drives the friction ring 1-16 to rotate when following movement, the friction rings 1-16 rotate to drive the propeller mounting rings 1-17 to rotate, the propeller mounting rings 1-17 rotate to drive the propellers 1-18 to rotate, the propellers 1-18 rotate to drive the rotating shafts 1-19 to rotate, the propellers 1-18 blow air in the direction of the output connecting rings 1-20 when rotating and suck air into the feed pipes 1-22, water on one side of a larger space formed by the feed tanks 1-26 and the separating plates 1-27 is adsorbed to the output connecting rings 1-20 through the feed pipes 1-22, the water in the output connecting rings 1-20 enters a space formed by the lower sealing plates 1-4 of the stirring barrel and the stirring barrel 1-5 through the input pipes 1-21, the handles 1-25 are pulled, the handles 1-25 move to drive the connecting plates d1-24, the connecting plates d1-24 move to drive the feed pipes 1-22, the feed pipes 1-22 slide on the grooves on the feed boxes 1-26, when the feed pipes 1-22 slide to coincide with the circular holes on the feed arc pipes 1-29, the feed pipes 1-22 slide to the extreme positions of the grooves on the feed boxes 1-26, and the light material mixture in the conical feed barrels 1-30 enters the feed pipes 1-22 through the feed arc pipes 1-29, and is conveyed to the space formed by the lower sealing plates 1-4 of the mixing barrels and the mixing barrels 1-5 under the action of the propellers 1-18.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the embodiment further describes the embodiment, where the stirring linkage mechanism 2 includes a bearing ring 2-1, a thread limit strip 2-2, a thread transmission limit plate 2-3, a thread transmission plate 2-4, a belt i 2-5, a propeller a2-6, a connecting shaft iv 2-7, a friction wheel i 2-8, a belt ii 2-9, a connecting shaft ii 2-10, a connecting plate ii 2-11, a friction wheel ii 2-12, a rotary sliding ring 2-13, a sliding ring connecting plate 2-14, a connecting shaft iii 2-15, a friction wheel iii 2-16, and a friction wheel iv 2-17, a bearing ring 2-1 is connected with a thread limit strip 2-2, the bearing ring 2-1 is connected with a stirring barrel 1-5 bearing, the bearing ring 2-1 is connected with a friction wheel I2-8 in a friction way, the thread limit strip 2-2 is connected with a thread transmission limit plate 2-3, the thread limit strip 2-2 is connected with a thread transmission plate 2-4 in a sliding way, the thread transmission plate 2-4 is connected with a motor shaft 1-3 in a sliding way, one end of a belt I2-5 is connected with the motor shaft 1-3 in a friction way, the other end of the belt I2-5 is connected with a connecting shaft a1-11 in a friction way, a propeller a2-6 is connected with a connecting shaft IV 2-7, a connecting shaft IV 2-7 is connected with a sliding ring connecting plate 2-14 bearing, a connecting shaft IV 2-7 is connected with a friction wheel IV 2-17, one end of a belt II 2-9 is in friction connection with a motor shaft 1-3, the other end of the belt II is in friction connection with a connecting shaft II 2-10, the connecting shaft II 2-10 is in bearing connection with a connecting plate II 2-11, the connecting shaft II 2-10 is in friction connection with a friction wheel II 2-12, the connecting plate II 2-11 is in friction connection with an equipment mounting ring 1-7, the friction wheel II 2-12 is in friction connection with a rotating sliding ring 2-13, the rotating sliding ring 2-13 is in sliding connection with the equipment mounting ring 1-7, the rotating sliding ring 2-13 is in connection with a sliding ring connecting plate 2-14, the sliding ring connecting plate 2-14 is in bearing connection with a connecting shaft III 2-15, the connecting shaft III 2-15 is in connection with a friction wheel III 2-16, and the friction wheel III 2-, the friction wheel III 2-16 is in friction connection with the friction wheel IV 2-17, the equipment can stir and mix water and light substance mixture, the equipment can rotate the light substance to the equipment installation ring through centrifugal force generated during rotation, the equipment can blow the light substance on the equipment installation ring downwards onto the inclined plate, the motor 1-2 works to drive the motor shaft 1-3 to rotate anticlockwise, the motor shaft 1-3 rotates to drive the connecting shaft a1-11 to rotate through the belt I2-5, the connecting shaft a1-11 rotates to drive the friction wheel I2-8 to rotate, the friction wheel I2-8 rotates to drive the bearing ring 2-1 to rotate, the bearing ring 2-1 rotates to drive the thread limit strip 2-2 to rotate, the thread limit strip 2-2 rotates to drive the thread transmission limit plate 2-3 to rotate, the thread conveying plate 2-4 is driven to rotate and move downwards when the thread limiting strip 2-2 rotates, water in the stirring barrel 1-5 and light substance mixture are uniformly mixed when the thread conveying plate 2-4 rotates, when the motor 1-2 drives the motor shaft 1-3 to rotate clockwise, the thread conveying plate 2-4 moves upwards, the rotating water and light substance in the light substance mixture are conveyed upwards when the thread conveying plate 2-4 moves upwards, when the thread conveying plate 2-4 moves to be in contact with the upper thread transmission limiting plate 2-3, the thread conveying plate 2-4 continues to rotate along with the thread limiting strip 2-2 and the thread transmission limiting plate 2-3, light substances on the thread conveying plate 2-4 are thrown onto the equipment mounting ring 1-7 under the action of centrifugal force generated by rotation, when the motor 1-2 drives the motor shaft 1-3 to rotate clockwise, the motor shaft 1-3 rotates and drives the connecting shaft II 2-10 to rotate through the belt II 2-9, the connecting shaft II 2-10 rotates the friction wheel II 2-12 to rotate, the friction wheel II 2-12 rotates and drives the rotating sliding ring 2-13 to rotate under the limitation of the equipment mounting ring 1-7, the rotating sliding ring 2-13 rotates and drives the sliding ring connecting plate 2-14 to rotate, the sliding ring connecting plate 2-14 rotates and drives the friction wheel III 2-16 to rotate through the connecting shaft III 2-15, when the friction wheel III 2-16 rotates along with the rotation, the friction wheel III rotates under the action of the equipment mounting ring 1-7, when the friction wheel III 2-16 rotates, the connecting shaft IV 2-7 is driven to rotate through the friction wheel IV 2-17, the connecting shaft IV 2-7 rotates to drive the propeller a2-6 to rotate, when the propeller a2-6 rotates, air is blown downwards to the propeller a2-6 and rotates around the equipment mounting ring 1-7 under the action of the rotating sliding ring 2-13, and blown light substances are blown down onto the output inclined plate 3-6 and the output inclined plate a 3-12.

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, and fig. 15, and the embodiment further describes the embodiment, where the output mechanism 3 includes a linkage belt 3-1, a linkage shaft 3-2, a mounting plate a3-3, a cam 3-4, a mounting plate b3-5, an output inclined plate 3-6, a reset support block 3-7, a reset shaft 3-8, a reset limit plate 3-9, a reset tension spring 3-10, an output port 3-11, and an output inclined plate a3-12, one end of the linkage belt 3-1 is frictionally connected to the motor shaft 1-3, and the other end is frictionally connected to the linkage shaft 3-2, the linkage shaft 3-2 is bearing-connected to the mounting plate a3-3, the universal driving device comprises a universal driving shaft 3-2, a cam 3-4, a mounting plate a3-3, an equipment mounting ring 1-7, a cam 3-4, a mounting plate b3-5, a mounting plate b3-5, an output inclined plate 3-6, a reset limiting plate 3-9, an output inclined plate 3-6, an equipment mounting ring 1-7, a reset supporting block 3-8, a reset supporting block 3-7, an equipment mounting ring 1-7, a reset shaft 3-8, a reset limiting plate 3-9, a reset tension spring 3-10, a reset tension spring 3-8, a reset supporting block 3-7, a reset limiting plate 3-9, an output port 3-11 and an equipment mounting ring 1-7, the output inclined plate a3-12 is connected with the output inclined plate 3-6 in a sliding mode, the output inclined plate a3-12 is connected with the equipment mounting ring 1-7, the equipment can convey light materials out of the equipment, when the light materials are blown down to the output inclined plate a3-12 and the output inclined plate 3-6, the light materials on the output inclined plate a3-12 are inclined to the inclined plate 3-6, the motor 1-2 works to drive the motor shaft 1-3 to rotate, the motor shaft 1-3 rotates to drive the linkage shaft 3-2 to rotate through the linkage belt 3-1, the linkage shaft 3-2 rotates to drive the cam 3-4 to rotate, the mounting plate b3-5 presses when the cam 3-4 rotates, the mounting plate b3-5 is pressed to move transversely, the mounting plate b3-5 moves to drive the output inclined plate 3-6 to move, the output inclined plate 3-6 moves to obliquely and transversely slide under the limitation of the reset support block 3-7, the reset shaft 3-8 and the reset limit plate 3-9 in a reciprocating manner, the output inclined plate 3-6 is pulled to reset in the process that the reset tension spring 3-10 pulls the reset limit plate 3-9, and light substances on the inclined plate 3-6 are conveyed out of the equipment through the output port 3-11.

The fifth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the present embodiment further describes the present embodiment, in which the material of the feeding pipes 1 to 22 is high-elasticity rubber, and the length of the feeding pipes 1 to 22 is slightly longer than that shown in the figures.

The working principle of the device is as follows: the equipment can clamp and convey a mixture of water and light substances into a stirring barrel, a motor 1-2 works, the motor 1-2 works to drive a motor shaft 1-3 to rotate clockwise, the motor shaft 1-3 rotates to drive a connecting shaft a1-11 to rotate through a belt a1-10, the connecting shaft a1-11 rotates to drive a connecting shaft b1-13 to rotate through a belt b1-12, the connecting shaft b1-13 rotates to drive another connecting shaft b1-13 to rotate through a belt c1-15, the belt c1-15 drives a friction ring 1-16 to rotate when moving along with the rotation, the friction ring 1-16 rotates to drive a propeller mounting ring 1-17 to rotate, the propeller mounting ring 1-17 rotates to drive a propeller 1-18 to rotate, the propeller 1-18 rotates to drive a rotating shaft 1-19 to rotate, the propeller 1-18 blows air to the direction of the output connecting ring 1-20 when rotating, sucks air to the feeding pipe 1-22, water on one side of a larger space formed by the feeding box 1-26 and the separating plate 1-27 is adsorbed to the output connecting ring 1-20 through the feeding pipe 1-22, the water in the output connecting ring 1-20 enters a space formed by the lower sealing plate 1-4 of the stirring barrel and the stirring barrel 1-5 through the input pipe 1-21, the handle 1-25 is pulled, the handle 1-25 moves to drive the connecting plate d1-24, the connecting plate d1-24 moves to drive the feeding pipe 1-22, the feeding pipe 1-22 slides on the groove on the feeding box 1-26, when the feeding pipe 1-22 slides to be overlapped with the round hole on the feeding arc-shaped pipe 1-29, the feeding pipe 1-22 slides to the limit position of the groove on the feeding box 1-26, at the moment, light substance mixtures in the conical feeding barrels 1-30 enter the feeding pipes 1-22 through the feeding arc-shaped pipes 1-29, the light substance mixtures are conveyed into a space formed by a sealing plate 1-4 at the lower part of the stirring barrel and the stirring barrel 1-5 under the action of the propellers 1-18, the equipment can stir and mix water and the light substance mixtures, the equipment can rotate the light substances to an equipment mounting ring through centrifugal force generated during rotation, the equipment can blow the light substances on the equipment mounting ring downwards to an inclined plate, the motor 1-2 works to drive a motor shaft 1-3 to rotate anticlockwise, the motor shaft 1-3 rotates to drive a connecting shaft a1-11 to rotate through a belt one 2-5, the connecting shaft a1-11 rotates to drive a friction wheel one 2-8 to rotate, the first friction wheel 2-8 rotates to drive the bearing ring 2-1 to rotate, the bearing ring 2-1 rotates to drive the thread limiting strip 2-2 to rotate, the thread limiting strip 2-2 rotates to drive the thread transmission limiting plate 2-3 to rotate, the thread limiting strip 2-2 rotates to drive the thread conveying plate 2-4 to rotate and move downwards, the thread conveying plate 2-4 rotates to uniformly mix water in the stirring barrel 1-5 with the light material mixture, when the motor 1-2 drives the motor shaft 1-3 to rotate clockwise, the thread conveying plate 2-4 moves upwards, when the thread conveying plate 2-4 moves upwards, the rotating water and the light material in the light material mixture are conveyed upwards, when the thread conveying plate 2-4 moves to contact with the upper thread transmission limiting plate 2-3, the thread conveying plate 2-4 continuously rotates along with the thread limiting strip 2-2 and the thread transmission limiting plate 2-3, light substances on the thread conveying plate 2-4 are thrown onto the equipment mounting ring 1-7 under the action of centrifugal force generated by rotation, when the motor 1-2 drives the motor shaft 1-3 to rotate clockwise, the motor shaft 1-3 rotates and drives the connecting shaft II 2-10 to rotate through the belt II 2-9, the connecting shaft II 2-10 rotates the friction wheel II 2-12 to rotate, the friction wheel II 2-12 rotates and drives the rotating sliding ring 2-13 to rotate under the limitation of the equipment mounting ring 1-7, the rotating sliding ring 2-13 rotates and drives the sliding ring connecting plate 2-14 to rotate, the sliding ring connecting plate 2-14 rotates and drives the friction wheel III 2-16 to rotate through the connecting shaft III 2-15, when the friction wheels three 2-16 rotate along with the rotation, the friction wheels three 2-16 rotate under the action of the equipment mounting rings 1-7, the friction wheels three 2-16 drive the connecting shafts four 2-7 to rotate through the friction wheels four 2-17 when rotating, the connecting shafts four 2-7 rotate to drive the propellers a2-6 to rotate, the propellers a2-6 blow downwards to the propellers a2-6 when rotating, and rotate around the equipment mounting rings 1-7 under the action of the rotating sliding rings 2-13, blown light substances are blown down to the output inclined plates 3-6 and the output inclined plates a3-12, the equipment can convey the light substances out of the equipment, when the light substances are blown down to the output inclined plates a3-12 and the output inclined plates 3-6, the light substances on the output inclined plates a3-12 incline to the inclined plates 3-6, the motor 1-2 works, the motor 1-2 works to drive the motor shaft 1-3 to rotate, the motor shaft 1-3 rotates to drive the linkage shaft 3-2 to rotate through the linkage belt 3-1, the linkage shaft 3-2 rotates to drive the cam 3-4 to rotate, the mounting plate b3-5 is pressed when the cam 3-4 rotates, the mounting plate b3-5 is pressed to move transversely, the mounting plate b3-5 moves to drive the output inclined plate 3-6 to move, the output inclined plate 3-6 moves to slide in an inclined reciprocating transverse manner under the limitation of the reset supporting block 3-7, the reset shaft 3-8 and the reset limiting plate 3-9, in the process that the reset tension spring 3-10 pulls the reset limiting plate 3-9, the output inclined plate 3-6 is pulled to reset, and light substances on the inclined plate 3-6 are conveyed out of the equipment through the output port 3-11.

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.