阅读说明：本技术 一种半自动多层轻物质湿法分离设备 (Semi-automatic multilayer light material wet separation equipment ) 是由 马桂军 于 2020-12-03 设计创作，主要内容包括：为解决上述技术问题,一种半自动多层轻物质湿法分离设备,包括给料装置、给料控制装置、分离装置,通过给料装置运送装有需要分离材料的装置然后在到达一定的位置后驱动给料控制装置接收装有才材料的装置然后继续移动,当给料控制装置将盛装装置移动到一定的位置后分离装置进行吹气材料加湿然后再通过加湿后的材料受力不同进行分离等功能,其特征在于：给料控制装置安装固定在给料装置上,分离装置安装固定在给料装置上。(In order to solve the technical problem, the semi-automatic multilayer light material wet separation equipment comprises a feeding device, a feeding control device and a separation device, wherein the feeding device is used for conveying a device which is provided with materials to be separated, then the feeding control device is driven to receive the device which is provided with the materials after the device reaches a certain position, then the device continues to move, and after the feeding control device moves the containing device to a certain position, the separation device performs functions of air blowing material humidification and then separation through different forces of the humidified materials, and the equipment is characterized in that: the feeding control device is fixedly arranged on the feeding device, and the separating device is fixedly arranged on the feeding device.)

1. The utility model provides a semi-automatic multilayer light material wet process splitter, includes feeder (1), feed controlling means (2), separator (3), its characterized in that: the feeding control device (2) is fixedly arranged on the feeding device (1), and the separating device (3) is fixedly arranged on the feeding device (1).

2. A semi-automatic multi-layer light material wet separation apparatus as claimed in claim 1, wherein: the feeding device (1) comprises a mounting square tube (1-1), a matching groove (1-2), a sliding matching groove (1-3), a front end non-threaded rotating lead screw (1-4), a cross connecting shaft (1-5), a sliding thread block (1-6), a cross hole rotating rod (1-7), a cross hole (1-8), a pushing spring (1-9), a spring (1-10), a sliding square plate (1-11), a connecting square column (1-12), a connecting rod (1-13), a bevel gear (1-14), a moving plate (1-15), a control bar (1-16), a matching tooth surface (1-17), a connecting plate (1-18), a spring (1-19), a connecting fixing plate (1-20), a rotating shaft (1-21), The transmission gear assembly comprises transmission gears (1-22), output bevel gears (1-23), rotating lead screws (1-24), receiving bevel gears (1-25), clamping sliding blocks (1-26), limiting springs (1-27), limiting balls (1-28) and material mounting plates (1-29), matching grooves (1-2) are fixedly arranged on mounting square pipes (1-1), sliding matching grooves (1-3) are fixedly arranged on the mounting square pipes (1-1), front-end screwless rotating lead screws (1-4) are rotatably arranged on the matching grooves (1-2), cross connecting shafts (1-5) are fixedly arranged on the front-end screwless rotating lead screws (1-4), sliding thread blocks (1-6) are slidably arranged on the mounting square pipes (1-1), cross hole rotating rods (1-7) are rotatably arranged on the sliding thread blocks (1-6), a cross connecting shaft (1-5) is slidably arranged in a cross hole (1-8), the cross hole (1-8) is arranged on a cross hole rotating rod (1-7), a pushing spring (1-9) is fixedly arranged on a sliding thread block (1-6) and inside a mounting square tube (1-1), a spring (1-10) is arranged in the cross hole rotating rod (1-7), a sliding square plate (1-11) is slidably arranged in the cross hole rotating rod (1-7), a connecting square column (1-12) is fixedly arranged on the sliding square plate (1-11), a connecting rod (1-13) is fixedly arranged on a connecting square column (1-12), a bevel gear (1-14) is fixedly arranged on the connecting rod (1-13), and a moving plate (1-15) is fixedly arranged on the sliding thread block (1-6), the control strips (1-16) are fixedly arranged on the first connecting plates (1-18), the matched tooth surfaces (1-17) are arranged on the control strips (1-16), the first connecting plates (1-18) are slidably arranged in the movable plates (1-15), the first springs (1-19) are fixedly arranged in the first connecting plates (1-18) and the movable plates (1-15), the connecting fixing plates (1-20) are fixedly arranged on the movable plates (1-15), the rotating shafts (1-21) are rotatably arranged on the connecting fixing plates (1-20), the transmission gears (1-22) are fixedly arranged on the rotating shafts (1-21), the output bevel gears (1-23) are fixedly arranged on the rotating shafts (1-21), and the rotating lead screws (1-24) are rotatably arranged in the connecting fixing plates (1-20), the receiving bevel gears (1-25) are fixedly arranged on the rotating lead screws (1-24), the receiving bevel gears (1-25) are meshed with the output bevel gears (1-23), the locking sliding blocks (1-26) are slidably arranged inside the connecting and fixing plates (1-20), the locking sliding blocks (1-26) are in threaded fit with the rotating lead screws (1-24), the limiting springs (1-27) are arranged inside the connecting and fixing plates (1-20), the limiting balls (1-28) are slidably arranged inside the connecting and fixing plates (1-20), the material mounting plates (1-29) are arranged on the connecting and fixing plates (1-20), and the material mounting plates (1-29) are arranged on the locking sliding blocks (1-26).

3. A semi-automatic multi-layer light material wet separation apparatus as claimed in claim 1, wherein: the feeding control device (2) comprises a connecting square pipe (2-1), a lifting screw rod (2-2), a receiving bevel gear I (2-3), a movable threaded sliding plate (2-4), a connecting plate III (2-5), a position adjusting hole plate (2-6), a limiting column (2-7), a pushing control plate (2-8), a reset spring (2-9) and a separating trapezoidal plate (2-10), wherein the connecting square pipe (2-1) is fixedly arranged on the mounting square pipe (1-1), the lifting screw rod (2-2) is rotatably arranged on the connecting square pipe (2-1), the receiving bevel gear I (2-3) is fixedly arranged on the lifting screw rod (2-2), and the receiving bevel gear I (2-3) is meshed with the bevel gear (1-14), the movable threaded sliding plate (2-4) is slidably mounted on the connecting square tube (2-1), the movable threaded sliding plate (2-4) is in threaded fit with the lifting screw rod (2-2), the connecting plate III (2-5) is fixedly mounted on the movable threaded sliding plate (2-4), the position adjusting pore plate (2-6) is slidably mounted on the connecting square tube (2-1), the position adjusting pore plate (2-6) is slidably mounted on the limiting column (2-7), the limiting column (2-7) is fixedly mounted on the connecting square tube (2-1), the pushing control plate (2-8) is fixedly mounted on the position adjusting pore plate (2-6), the reset spring (2-9) is sleeved on the limiting column (2-7), and the separated trapezoidal plate (2-10) is fixedly mounted on the position adjusting pore plate (2-6).

4. A semi-automatic multi-layer light material wet separation apparatus as claimed in claim 1, wherein: the separation device (3) comprises a separation cylinder (3-1), an air supply device mounting hole (3-2), an outer gear ring rotating turbine (3-3), a separation annular rod (3-4), a half baffle disc (3-5), an air baffle spring (3-6), a transmission gear I (3-7), a transmission shaft (3-8), a transmission gear II (3-9), a water supply device connecting pipe (3-10), a water storage cavity (3-11), a connecting rotating gear ring (3-12), a rotating drainage ring (3-13), a moving perforated square plate (3-14), a drainage valve body (3-15), a water inlet hole (3-16), a water outlet hole (3-17), a water outlet cavity (3-18), a spring IV (3-19), an atomization conical head (3-20), A separation air inlet (3-21), a separation cylinder (3-1) is fixedly arranged on a connecting square pipe (2-1), an air supply device mounting hole (3-2) is arranged on the separation cylinder (3-1), an outer gear ring rotating turbine (3-3) is rotatably arranged in the separation cylinder (3-1), a separation annular rod (3-4) is slidably arranged in the separation cylinder (3-1), a half baffle disc (3-5) is fixed on the separation annular rod (3-4), the half baffle disc (3-5) is slidably arranged in the separation cylinder (3-1), an air baffle spring (3-6) is arranged in the separation cylinder (3-1), a transmission gear I (3-7) is meshed with the outer gear ring rotating turbine (3-3), the transmission gear I (3-7) is fixedly arranged on a transmission shaft (3-8), the transmission shaft (3-8) is rotatably arranged in the separating cylinder (3-1), the transmission gear II (3-9) is fixedly arranged on the transmission shaft (3-8), the water supply device connecting pipe (3-10) is fixedly arranged on the separating cylinder (3-1), the water storage cavity (3-11) is arranged in the separating cylinder (3-1), the transmission gear II (3-9) is meshed with the connecting rotating toothed ring (3-12), the connecting rotating toothed ring (3-12) is rotatably arranged in the separating cylinder (3-1), the rotating water discharge ring (3-13) is fixedly arranged on the connecting rotating toothed ring (3-12), the rotating water discharge ring (3-13) is rotatably arranged in the separating cylinder (3-1), the movable square plate with holes (3-14) is slidably arranged in the rotating water discharge ring (3-13), the drainage valve body (3-15) is fixedly arranged on the movable square plate with the hole (3-14), the water inlet hole (3-16) is arranged on the drainage valve body (3-15), the water outlet hole (3-17) is arranged on the drainage valve body (3-15), the water outlet cavity (3-18) is arranged on the rotary drainage ring (3-13), the spring (3-19) is sleeved on the drainage valve body (3-15), the atomizing conical head (3-20) is fixedly arranged inside the water outlet cavity (3-18), and the separation air inlet hole (3-21) is arranged on the separation cylinder (3-1).

5. A semi-automatic multi-layer light material wet separation device according to claim 4, wherein: the air supply device is characterized in that the separating cylinder (3-1) of the separating device (3) is provided with vent holes which are represented by numbers in the figure, published air supply devices are arranged on the air supply device mounting holes (3-2), published water supply devices are arranged on the water supply device connecting pipes (3-10), the number of the movable square plates with holes (3-14), the number of the water discharge valve bodies (3-15), the number of the water inlet holes (3-16), the number of the water outlet holes (3-17), the number of the water outlet cavities (3-18), the number of the springs (3-19) and the number of the atomizing conical heads (3-20) are eight, and the published air supply device for wind power separation is arranged on the separating air inlet holes (3-21).

Technical Field

The invention relates to light material wet separation equipment, in particular to semi-automatic multilayer light material wet separation equipment.

Background

In our life, a substance mixed with a plurality of materials exists, wherein a light substance is the main substance, and some materials have certain recycling value, so that the semi-automatic multilayer light substance wet separation equipment is invented.

Disclosure of Invention

The invention relates to semi-automatic multilayer light material wet separation equipment, in particular to semi-automatic multilayer light material wet separation equipment.

In order to solve the technical problem, the semi-automatic multilayer light material wet separation equipment comprises a feeding device, a feeding control device and a separation device, wherein the feeding device is used for conveying a device which is provided with materials to be separated, then the feeding control device is driven to receive the device which is provided with the materials after the device reaches a certain position, then the device continues to move, and after the feeding control device moves the containing device to a certain position, the separation device performs functions of air blowing material humidification and then separation through different forces of the humidified materials, and the equipment is characterized in that: the feeding control device is fixedly arranged on the feeding device, and the separating device is fixedly arranged on the feeding device.

As a further optimization of the technical scheme, the invention relates to semi-automatic multilayer light material wet separation equipment, wherein a feeding device comprises a mounting square pipe, a matching groove, a sliding matching groove, a front end unthreaded rotating lead screw, a cross connecting shaft, a sliding thread block, a cross hole rotating rod, a cross hole, a pushing spring, a sliding square plate, a connecting square column, a connecting rod, a bevel gear, a moving plate, a control strip, a matching tooth surface, a connecting plate I, a spring I, a connecting fixing plate, a rotating shaft, a transmission gear, an output bevel gear, a rotating lead screw, a receiving bevel gear, a clamping sliding block, a limiting spring, a limiting ball and a material mounting plate, the matching groove is fixedly mounted on the mounting square pipe, the front end unthreaded rotating lead screw is rotatably mounted on the matching groove, the cross connecting shaft is fixedly mounted on the front end unthreaded rotating lead screw, the sliding threaded block is slidably mounted on the mounting square pipe, the cross hole rotating rod is rotatably mounted on the sliding threaded block, the cross connecting shaft is slidably mounted inside the cross hole, the cross hole is formed in the cross hole rotating rod, the pushing spring is fixedly mounted on the sliding threaded block and inside the mounting square pipe, the spring is mounted inside the cross hole rotating rod, the sliding square plate is slidably mounted inside the cross hole rotating rod, the connecting square column is fixedly mounted on the sliding square plate, the connecting rod is fixedly mounted on the connecting square column, the bevel gear is fixedly mounted on the connecting rod, the moving plate is fixedly mounted on the sliding threaded block, the control strip is fixedly mounted on the connecting plate I, the matching tooth surface is arranged on the control strip, the connecting plate I is slidably mounted inside the moving plate, the spring I is fixedly mounted inside the connecting plate I and the moving plate, the connecting fixed, drive gear installation is fixed in the axis of rotation, output bevel gear installation is fixed in the axis of rotation, it installs inside connection fixed plate to rotate the lead screw, it fixes on rotating the lead screw to receive bevel gear installation, receive bevel gear and output bevel gear meshing, the dead sliding block slidable mounting of card is inside connection fixed plate, the dead sliding block of card and rotation lead screw-thread fit, spacing spring mounting is inside connection fixed plate, spacing ball slidable mounting is inside connection fixed plate, the material mounting panel is installed on the dead sliding block of card.

As a further optimization of the technical scheme, the invention relates to a semi-automatic multilayer light material wet separation device, wherein a feeding control device comprises a connecting square pipe, a lifting screw rod, a receiving bevel gear I, a movable threaded sliding plate, a connecting plate III, a position adjusting orifice plate, a limiting column, a pushing control plate, a reset spring and a separating trapezoidal plate, the connecting square pipe is fixedly arranged on a mounting square pipe, the lifting screw rod is rotatably arranged on the connecting square pipe, the receiving bevel gear I is fixedly arranged on the lifting screw rod, the receiving bevel gear I is meshed with the bevel gear, the movable threaded sliding plate is slidably arranged on the connecting square pipe, the movable threaded sliding plate is in threaded fit with the lifting screw rod, the connecting plate III is fixedly arranged on the movable threaded sliding plate, the position adjusting orifice plate is slidably arranged on the connecting square pipe, the position adjusting orifice plate is slidably arranged, the push control panel is installed and fixed on the position adjusting pore plate, the reset spring is sleeved on the limiting column, and the separated trapezoidal plate is installed and fixed on the position adjusting pore plate.

As a further optimization of the technical scheme, the invention relates to semi-automatic multilayer light material wet separation equipment, which comprises a separation cylinder, an air supply device mounting hole, an outer gear ring rotating turbine, a separation annular rod, a semi-baffle disc, an air baffle spring, a first transmission gear, a first transmission shaft, a second transmission gear, a water supply device connecting pipe, a water storage cavity, a connecting rotating gear ring, a rotating water discharge ring, a moving square plate with holes, a water discharge valve body, a water inlet hole, a water outlet cavity, a fourth spring, an atomizing conical head and a separation air inlet hole, wherein the separation cylinder is fixedly arranged on the connecting square pipe, the air supply device mounting hole is arranged on the separation cylinder, the outer gear ring rotating turbine is rotatably arranged inside the separation cylinder, the separation annular rod is slidably arranged inside the separation cylinder, the semi-baffle disc is fixedly arranged on the separation annular rod, the semi-baffle disc is slidably arranged inside the separation cylinder, the air baffle spring is arranged, the water supply device comprises a first transmission gear, a second transmission gear, a water supply device connecting pipe, a water storage cavity, a first transmission gear, a second transmission gear, a connecting rotary gear ring, a rotary drainage ring, a movable square plate, a drainage valve body, a water inlet hole, a water outlet cavity, a spring, an atomization conical head and a separation air inlet hole, wherein the first transmission gear is meshed with a transmission shaft, the transmission shaft is rotatably installed inside a separation cylinder, the second transmission gear is fixedly installed on the transmission shaft, the water supply device connecting pipe is fixedly installed on the separation cylinder, the second transmission gear is meshed with the connecting rotary gear ring, the connecting rotary drainage ring is rotatably installed inside the separation cylinder, the movable square plate with holes is slidably installed inside the rotary drainage ring, the drainage valve body is fixedly installed on the movable square plate with holes, the water inlet hole is formed in the drainage valve body, the water outlet hole is.

As a further optimization of the technical scheme, the semi-automatic multilayer light material wet separation equipment is characterized in that a separation cylinder of the separation device is provided with vent holes which are embodied in the drawing but not indicated by serial numbers, a published air supply device is arranged on an installation hole of the air supply device, a published water supply device is arranged on a connecting pipe of the water supply device, eight movable square plates with holes, eight drainage valve bodies, eight water inlet holes, eight water outlet cavities, eight springs and eight atomizing conical heads are arranged on the separation air inlet holes, and the published wind separation air supply device is arranged on the separation air inlet holes.

The semi-automatic multilayer light material wet separation equipment has the beneficial effects that:

the invention relates to semi-automatic multilayer light material wet separation equipment, in particular to semi-automatic multilayer light material wet separation equipment, which realizes the functions of conveying a device filled with materials to be separated through a feeding device, driving a feeding control device to receive the device filled with the materials after the device reaches a certain position, then continuously moving, humidifying the materials by blowing through a separation device after the feeding control device moves the containing device to the certain position, and then separating through different stresses of the humidified materials.

Drawings

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

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the overall structure of the present invention.

Fig. 3 is a first structural schematic diagram of the feeding device of the present invention.

Fig. 4 is a schematic structural diagram of a feeding device of the present invention.

Fig. 5 is a third schematic structural diagram of the feeding device of the present invention.

Fig. 6 is a fourth schematic structural view of the feeding device of the present invention.

Fig. 7 is a fifth structural schematic diagram of the feeding device of the present invention.

Fig. 8 is a sixth structural schematic diagram of the feeding device of the present invention.

Fig. 9 is a first structural schematic diagram of the feeding control device of the present invention.

Fig. 10 is a structural schematic diagram of a feeding control device of the present invention.

Fig. 11 is a third structural schematic diagram of the feeding control device of the present invention.

FIG. 12 is a first schematic structural diagram of a separation device according to the present invention.

FIG. 13 is a second schematic structural diagram of a separation device according to the present invention.

Fig. 14 is a third schematic structural view of the separation device of the present invention.

Fig. 15 is a fourth schematic structural view of the separation device of the present invention.

Fig. 16 is a schematic structural diagram of a separating device according to the present invention.

In the figure: a feeding device 1; mounting a square tube 1-1; a mating groove 1-2; 1-3 of a sliding fit groove; the front end of the screw rod rotates 1-4 without threads; 1-5 of a cross connecting shaft; 1-6 of a sliding thread block; a cross hole rotating rod 1-7; 1-8 parts of cross holes; pushing springs 1-9; 1-10 parts of spring; 1-11 of a sliding square plate; connecting square columns 1-12; connecting rods 1-13; bevel gears 1-14; moving the plates 1-15; control bars 1-16; mating tooth surfaces 1-17; 1-18 of a connecting plate; 1-19 of a first spring; connecting the fixing plates 1-20; 1-21 of a rotating shaft; transmission gears 1-22; output bevel gears 1-23; rotating the lead screw 1-24; receiving bevel gears 1-25; locking the sliding blocks 1-26; 1-27 of a limiting spring; 1-28 parts of a limiting ball; 1-29 parts of a material mounting plate; a feed control device 2; connecting the square tubes 2-1; 2-2 of a lifting screw rod; receiving a bevel gear I2-3; moving the threaded sliding plate 2-4; 2-5 of a connecting plate III; 2-6 parts of a position adjusting pore plate; 2-7 of a limiting column; pushing the control plate 2-8; 2-9 parts of a return spring; separating the trapezoidal plates 2-10; a separation device 3; 3-1 of a separation cylinder; a gas supply device mounting hole 3-2; the external gear ring rotates the turbine 3-3; separating the annular rods 3-4; 3-5 of a half-blocking disc; 3-6 of an air blocking spring; 3-7 of a transmission gear I; a transmission shaft 3-8; a second transmission gear 3-9; the water supply device is connected with the pipes 3-10; 3-11 parts of a water storage cavity; connecting the rotating toothed ring 3-12; rotating the drainage ring 3-13; moving the square plate with the holes 3-14; 3-15 parts of a drainage valve body; 3-16 parts of water inlet holes; 3-17 parts of water outlet holes; 3-18 parts of a water outlet cavity; a fourth spring 3-19; 3-20 parts of an atomizing conical head; separating the inlet vents 3-21.

Detailed Description

The first embodiment is as follows:

in order to solve the technical problems, a semi-automatic multi-layer light material wet separation device comprises a feeding device 1, a feeding control device 2 and a separation device 3, wherein the feeding device is used for conveying a device containing materials to be separated, then the feeding control device is driven to receive the device containing the materials after the device reaches a certain position, then the device continues to move, and after the feeding control device moves the containing device to a certain position, the separation device is used for humidifying the blown materials and then separating the materials through different forces of the humidified materials, and the semi-automatic multi-layer light material wet separation device is characterized in that: the feeding control device 2 is fixedly arranged on the feeding device 1, and the separating device 3 is fixedly arranged on the feeding device 1.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16. the present embodiment further describes the first embodiment that the feeding device 1 includes a square installation tube 1-1, a mating groove 1-2, a sliding mating groove 1-3, a front end unthreaded rotary screw 1-4, a cross connecting shaft 1-5, a sliding threaded block 1-6, a cross hole rotating rod 1-7, a cross hole 1-8, a pushing spring 1-9, a spring 1-10, a sliding square plate 1-11, a connecting square column 1-12, a connecting rod 1-13, a bevel gear 1-14, a moving plate 1-15, a control bar 1-16, a mating tooth surface 1-17, a connecting plate 1-18, a spring 1-19, a connecting square column 1-12, a connecting rod 1-13, a bevel gear 1, Connecting a fixed plate 1-20, a rotating shaft 1-21, a transmission gear 1-22, an output bevel gear 1-23, a rotating lead screw 1-24, a receiving bevel gear 1-25, a blocking sliding block 1-26, a limiting spring 1-27, a limiting ball 1-28 and a material mounting plate 1-29, firstly rotating the lead screw 1-4 to drive a sliding thread block 1-6 to move through rotating the front end of a feeding device 1 without threads, driving a moving plate 1-15 to move through the sliding thread block 1-6, when the moving plate 1-15 moves to the outermost end of a matching groove 1-2 and a sliding matching groove 1-3, then pushing a control bar 1-16 to the inner part of the moving plate 1-15, and driving the transmission gear 1-22 to rotate through a matching tooth surface 1-17 by the control bar 1-16, and the springs I1-19 are compressed through the connecting plates I1-18, the transmission gears 1-22 drive the rotating shafts 1-21 to rotate, the rotating shafts 1-21 drive the output bevel gears 1-23 to rotate, the output bevel gears 1-23 drive the rotating lead screws 1-24 to rotate through the receiving bevel gears 1-25, the rotating lead screws 1-24 drive the locking sliding blocks 1-26 to move inwards in the connecting and fixing plates 1-20, then the material mounting plates 1-29 are placed on the connecting and fixing plates 1-20, then the control bars 1-16 are loosened, then the control bars 1-16 drive the transmission gears 1-22 to rotate reversely through the matching tooth surfaces 1-17 under the action of the compressed springs I1-19, and the transmission gears 1-22 drive the output bevel gears 1-23 to rotate through the rotating shafts 1-21, the output bevel gears 1-23 drive the rotating screw rods 1-24 through receiving the bevel gears 1-25 so as to drive the blocking sliding blocks 1-26 to enter the material mounting plates 1-29 and limit and fix the material mounting plates 1-29, then the materials to be separated are placed on the material mounting plates 1-29, then the front-end unthreaded rotating screw rods 1-4 are rotated, then the rotating front-end unthreaded rotating screw rods 1-4 push the moving plates 1-15 through the sliding thread blocks 1-6 and then drive the material mounting plates 1-29 to move, meanwhile, the front-end unthreaded rotating screw rods 1-4 drive the cross connecting shafts 1-5 to rotate, the cross connecting shafts 1-5 drive the bevel gears 1-14 on the connecting rods 1-13 to rotate through the sliding square plates 1-11 and the connecting square columns 1-12, after the moving plate 1-15 moves and moves, the control bar 1-16 moves downwards due to the inclined surface at the upper end of the mounting square tube 1-1, then the blocking sliding block 1-26 is separated from the material mounting plate 1-29, the material mounting plate 1-29 enters the connecting plate three 2-5 of the feeding control device 2, the unthreaded part at the front end of the unthreaded rotating lead screw 1-4 at the front end is matched with the sliding thread block 1-6, so that the sliding thread block 1-6 pushes the sliding thread block 1-6 to move no matter the unthreaded rotating lead screw 1-4 at the front end rotates, and the pushing spring 1-9 pushes the sliding thread block 1-6 to be in contact with the thread of the outer ring of the unthreaded rotating lead screw 1-4 at the front end all the time, so that the sliding thread block 1-6 can move in the first time, after separation, the material mounting plates 1-29 are returned to the outer ends of the device by rotating the front end unthreaded rotary screw rods 1-4 in the direction, the limiting springs 1-27 and the limiting balls 1-28 help the connecting fixing plates 1-20 to pull the material mounting plates 1-29 outwards, the matching grooves 1-2 are fixedly arranged on the mounting square tubes 1-1, the sliding matching grooves 1-3 are fixedly arranged on the mounting square tubes 1-1, the front end unthreaded rotary screw rods 1-4 are rotatably arranged on the matching grooves 1-2, the cross connecting shafts 1-5 are fixedly arranged on the front end unthreaded rotary screw rods 1-4, the sliding thread blocks 1-6 are slidably arranged on the mounting square tubes 1-1, the cross hole rotating rods 1-7 are rotatably arranged on the sliding thread blocks 1-6, and the cross connecting shafts 1-5 are slidably arranged in the cross holes 1-8, the cross holes 1-8 are arranged on the cross hole rotating rods 1-7, the pushing springs 1-9 are fixedly arranged on the sliding thread blocks 1-6 and inside the mounting square tubes 1-1, the springs 1-10 are arranged inside the cross hole rotating rods 1-7, the sliding square plates 1-11 are slidably arranged inside the cross hole rotating rods 1-7, the connecting square columns 1-12 are fixedly arranged on the sliding square plates 1-11, the connecting rods 1-13 are fixedly arranged on the connecting square columns 1-12, the bevel gears 1-14 are fixedly arranged on the connecting rods 1-13, the moving plates 1-15 are fixedly arranged on the sliding thread blocks 1-6, the control bars 1-16 are fixedly arranged on the connecting plates 1-18, and the matched tooth surfaces 1-17 are arranged on the control bars 1-16, the first connecting plate 1-18 is slidably arranged inside the moving plate 1-15, the first springs 1-19 are fixedly arranged inside the first connecting plate 1-18 and the moving plate 1-15, the connecting fixing plate 1-20 is fixedly arranged on the moving plate 1-15, the rotating shafts 1-21 are rotatably arranged on the connecting fixing plate 1-20, the transmission gears 1-22 are fixedly arranged on the rotating shafts 1-21, the output bevel gears 1-23 are fixedly arranged on the rotating shafts 1-21, the rotating lead screws 1-24 are rotatably arranged inside the connecting fixing plate 1-20, the receiving bevel gears 1-25 are fixedly arranged on the rotating lead screws 1-24, the receiving bevel gears 1-25 are meshed with the output bevel gears 1-23, the locking sliding blocks 1-26 are slidably arranged inside the connecting fixing plate 1-20, the clamping sliding blocks 1-26 are in threaded fit with the rotating lead screws 1-24, the limiting springs 1-27 are installed inside the connecting and fixing plates 1-20, the limiting balls 1-28 are installed inside the connecting and fixing plates 1-20 in a sliding mode, the material installing plates 1-29 are installed on the connecting and fixing plates 1-20, and the material installing plates 1-29 are installed on the clamping sliding blocks 1-26.

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, and 16, and the embodiment further describes the embodiment, where the feeding control device 2 includes a connecting square tube 2-1, a lifting screw 2-2, a receiving bevel gear 2-3, a moving threaded sliding plate 2-4, a connecting plate three 2-5, a position adjusting orifice plate 2-6, a limiting column 2-7, a pushing control plate 2-8, a return spring 2-9, and a separating trapezoidal plate 2-10, and the bevel gear 1-14 drives the receiving bevel gear 2-3 to rotate, the receiving bevel gear 2-3 drives the lifting screw 2-2 to rotate, the lifting screw 2-2 drives the moving threaded sliding plate 2-4 to move, moving the threaded sliding plate 2-4 to drive the connecting plate III 2-5 to move, driving the material mounting plate 1-29 filled with materials to move upwards by the connecting plate III 2-5, driving the material mounting plate 1-29 to push the push control plate 2-8 to move upwards after the material mounting plate 1-29 moves to a moving position, driving the control plate 2-8 to drive the position adjusting orifice plate 2-6 to move, driving the separating trapezoidal plate 2-10 to move by the position adjusting orifice plate 2-6, mounting and fixing the connecting square pipe 2-1 on the mounting square pipe 1-1, rotatably mounting the lifting screw 2-2 on the connecting square pipe 2-1, mounting and fixing the receiving bevel gear I2-3 on the lifting screw 2-2, meshing the receiving bevel gear I2-3 with the bevel gear 1-14, slidably mounting the moving threaded sliding plate 2-4 on the connecting square pipe 2-1, the movable threaded sliding plate 2-4 is in threaded fit with the lifting screw rod 2-2, the connecting plate III 2-5 is fixedly installed on the movable threaded sliding plate 2-4, the position adjusting pore plate 2-6 is slidably installed on the connecting square tube 2-1, the position adjusting pore plate 2-6 is slidably installed on the limiting column 2-7, the limiting column 2-7 is fixedly installed on the connecting square tube 2-1, the pushing control plate 2-8 is fixedly installed on the position adjusting pore plate 2-6, the reset spring 2-9 is sleeved on the limiting column 2-7, and the separated trapezoidal plate 2-10 is fixedly installed on the position adjusting pore plate 2-6.

The fourth 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 and 16. the embodiment is further described, wherein the separation device 3 comprises a separation cylinder 3-1, an air supply device mounting hole 3-2, an outer toothed ring rotating turbine 3-3, a separation annular rod 3-4, a half baffle 3-5, an air baffle spring 3-6, a transmission gear I3-7, a transmission shaft 3-8, a transmission gear II 3-9, a water supply device connecting pipe 3-10, a water storage cavity 3-11, a connecting rotating toothed ring 3-12, a rotating water discharge ring 3-13, a moving perforated square plate 3-14, a water discharge valve body 3-15, a water inlet hole 3-16, a water outlet hole 3-17, a water outlet cavity 3-18, 3-19 parts of spring, 3-20 parts of atomizing conical head and 3-21 parts of separation air inlet, 2-10 parts of movable separating trapezoidal plate push 3-4 parts of separating ring-shaped rod of separating device 3 to two sides and then compress 3-6 parts of air blocking spring, 3-4 parts of separating ring-shaped rod drive 3-5 parts of half blocking disc to two sides for separation, then open the hole at the center of separating cylinder 3-1, then wind enters through 3-2 parts of air feeding device mounting hole to drive 3-3 parts of outer toothed ring rotating turbine to enlarge the wind range, then fix 1-4 parts of leading screw with no screw thread at the front end, because the wind flow blows up the material on 1-29 parts of material mounting plate and then blows up towards 3-21 parts of separation air inlet, 3-3 parts of rotating outer toothed ring rotating turbine drive 3-7 parts of transfer gear to rotate, the first transmission gear 3-7 drives the second transmission gear 3-9 to rotate through the transmission shaft 3-8, the second transmission gear 3-9 drives the connecting rotating toothed ring 3-12 to rotate, the connecting rotating toothed ring 3-12 drives the rotating water discharge ring 3-13 to rotate, the water discharge valve body 3-15 is moved outwards under the action of centrifugal force, then the spring fourth 3-19 is compressed through the moving square plate 3-14 with holes, so that the water inlet hole 3-16 enters the water outlet cavity 3-18 to discharge water, then the water is discharged from the water outlet hole 3-17 to impact the atomizing conical head 3-20 to atomize and adsorb on the passing material, because different materials adsorb on water differently, then the deviated positions under the action of the same wind are different to separate the material by a wet method, the separating cylinder 3-1 is installed and fixed on the connecting square pipe 2-1, a gas supply device mounting hole 3-2 is arranged on a separating cylinder 3-1, an outer gear ring rotating turbine 3-3 is rotatably arranged inside the separating cylinder 3-1, a separating annular rod 3-4 is slidably arranged inside the separating cylinder 3-1, a half baffle disc 3-5 is fixed on the separating annular rod 3-4, the half baffle disc 3-5 is slidably arranged inside the separating cylinder 3-1, a gas baffle spring 3-6 is arranged inside the separating cylinder 3-1, a transmission gear I3-7 is meshed with the outer gear ring rotating turbine 3-3, the transmission gear I3-7 is fixedly arranged on a transmission shaft 3-8, the transmission shaft 3-8 is rotatably arranged inside the separating cylinder 3-1, a transmission gear II 3-9 is fixedly arranged on the transmission shaft 3-8, a water supply device connecting pipe 3-10 is fixedly arranged on the separating cylinder 3-1, a water storage cavity 3-11 is arranged inside a separating cylinder 3-1, a transfer gear II 3-9 is meshed with a connecting rotating gear ring 3-12, the connecting rotating gear ring 3-12 is rotatably arranged inside the separating cylinder 3-1, a rotating water discharge ring 3-13 is fixedly arranged on the connecting rotating gear ring 3-12, the rotating water discharge ring 3-13 is rotatably arranged inside the separating cylinder 3-1, a moving square plate with holes 3-14 is slidably arranged inside the rotating water discharge ring 3-13, a water discharge valve body 3-15 is fixedly arranged on the moving square plate with holes 3-14, a water inlet hole 3-16 is arranged on the water discharge valve body 3-15, a water outlet hole 3-17 is arranged on the water discharge valve body 3-15, a water outlet cavity 3-18 is arranged on the rotating water discharge ring 3-13, a spring IV 3-19 is sleeved on the water discharge valve body 3-15, the atomizing conical head 3-20 is fixedly arranged inside the water outlet cavity 3-18, and the separation air inlet 3-21 is arranged on the separation cylinder 3-1.

The fifth concrete implementation mode:

the fourth embodiment is further described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16. the fourth embodiment is further described, the separating cylinder 3-1 of the separating device 3 is provided with vent holes which are represented by the embodiments but not with reference numbers in the drawings, the air supply device mounting hole 3-2 is provided with a published air supply device, the water supply device connecting pipe 3-10 is provided with a published water supply device, the movable square plate with holes 3-14, the drain valve body 3-15, the water inlet hole 3-16, the water outlet hole 3-17, the water outlet cavity 3-18, the spring four 3-19 and the atomizing conical head 3-20 are eight in number, and the separating air inlet hole 3-21 is provided with a published wind power separating air supply device.

The working principle of the invention is as follows:

a semi-automatic multilayer light material wet separation device has the working principle that whether the connection condition between devices meets requirements is checked before the device is used, firstly, a screw rod 1-4 is rotated without threads at the front end of a feeding device 1 to rotate to drive a sliding thread block 1-6 to move, the sliding thread block 1-6 drives a movable plate 1-15 to move, when the movable plate 1-15 moves to the outermost ends of a matching groove 1-2 and a sliding matching groove 1-3, a control strip 1-16 is pushed towards the inner part of the movable plate 1-15, the control strip 1-16 drives a transmission gear 1-22 to rotate through a matching tooth surface 1-17, a first compression spring 1-19 is compressed through a connecting plate 1-18, the transmission gear 1-22 drives a rotating shaft 1-21 to rotate, the rotating shaft 1-21 drives an output bevel gear 1-23 to rotate, the output bevel gears 1-23 drive the rotating lead screws 1-24 to rotate through the receiving bevel gears 1-25, the rotating lead screws 1-24 drive the blocking sliding blocks 1-26 to move inwards in the connecting and fixing plates 1-20, then the material mounting plates 1-29 are placed on the connecting and fixing plates 1-20, then the control strips 1-16 are loosened, then the control strips 1-16 drive the transmission gears 1-22 to rotate reversely through the matching tooth surfaces 1-17 under the action of the compressed springs 1-19, the transmission gears 1-22 drive the output bevel gears 1-23 to rotate through the rotating shafts 1-21, the output bevel gears 1-23 drive the rotating lead screws 1-24 through the receiving bevel gears 1-25 to drive the blocking sliding blocks 1-26 to enter the material mounting plates 1-29 and limit and fix the material mounting plates 1-29, then the materials to be separated are placed on the material mounting plates 1-29, then the front end unthreaded rotating lead screw 1-4 is rotated, then the rotating front end unthreaded rotating lead screw 1-4 pushes the moving plate 1-15 through the sliding thread block 1-6 and then drives the material mounting plates 1-29 to move, meanwhile, the front end unthreaded rotating lead screw 1-4 drives the cross connecting shaft 1-5 to rotate, the cross connecting shaft 1-5 drives the bevel gears 1-14 on the connecting rods 1-13 to rotate through the sliding square plates 1-11 and the connecting square columns 1-12, after the moving plate 1-15 moves to a moving position, the control strips 1-16 move downwards due to the inclined planes at the upper ends of the mounting square tubes 1-1, then the clamping slide blocks 1-26 are separated from the material mounting plates 1-29, and the material mounting plates 1-29 enter the connecting plate III 2 of the feeding control device 2 In the-5 plate, the unthreaded part at the front end of the front end unthreaded rotating lead screw 1-4 is matched with the sliding thread block 1-6, so that the sliding thread block 1-6 pushes the sliding thread block 1-6 to move no matter the front end unthreaded rotating lead screw 1-4 rotates, and the pushing spring 1-9 pushes the sliding thread block 1-6 to be always in contact with the thread of the outer ring of the front end unthreaded rotating lead screw 1-4, so that the sliding thread block 1-6 can move in the direction at the first time, meanwhile, the bevel gear 1-14 drives the receiving bevel gear I2-3 to rotate, the receiving bevel gear I2-3 drives the lifting lead screw 2-2 to rotate, the lifting lead screw 2-2 drives the moving thread sliding plate 2-4 to move, the moving thread sliding plate 2-4 drives the connecting plate III 2-5 to move, the connecting plate III 2-5 drives the material mounting plate 1-29 filled with materials to move upwards, after the material mounting plate 1-29 moves to a moving position, the material mounting plate 1-29 pushes the push control plate 2-8 upwards, the push control plate 2-8 drives the position adjusting orifice plate 2-6 to move, the position adjusting orifice plate 2-6 drives the separating trapezoidal plate 2-10 to move, the moving separating trapezoidal plate 2-10 pushes the separating annular rod 3-4 of the separating device 3 towards two sides and then compresses the air blocking spring 3-6, the separating annular rod 3-4 drives the half air blocking disc 3-5 to separate towards two sides, then the hole in the center of the separating cylinder 3-1 is opened, then wind enters through the air feeding device mounting hole 3-2 and drives the outer toothed ring rotating turbine 3-3 to increase the range of the wind, then fixing the front end of the screw rod 1-4 without screw thread, blowing up the material on the material mounting plate 1-29 by the flow of wind and blowing up the material towards the direction of the separation air inlet 3-21, driving the transmission gear 3-7 to rotate by the rotating outer ring gear 3-3, driving the transmission gear 3-7 to rotate by the transmission shaft 3-8, driving the transmission gear 3-9 to rotate by the transmission gear 3-9, driving the connecting rotating ring gear 3-12 to rotate by the connecting rotating ring gear 3-12, driving the rotating drainage ring 3-13 to rotate by the connecting rotating ring gear 3-12, making the drainage valve body 3-15 move outwards under the action of centrifugal force, then compressing the spring four 3-19 by the moving square plate 3-14 with holes, making the water inlet 3-16 enter the water outlet cavity 3-18 for drainage, then discharging water from the water outlet 3-17 to impact on the atomizing cone head 3-20 for atomization and then absorbing on the path On the materials which pass through, because different materials have different water absorption, the deviated positions under the action of the same wind are different, so that the materials are subjected to wet separation, after separation, the material mounting plates 1-29 are returned to the outer ends of the device by rotating the lead screws 1-4 with the front ends being free of threads in a rotating direction, and the limiting springs 1-27 and the limiting balls 1-28 help the connecting fixing plates 1-20 to pull the material mounting plates 1-29 outwards.

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.