CN109304247B - New forms of energy living beings processing apparatus - Google Patents

Abstract

The invention relates to the technical field of new energy, in particular to a new energy biomass processing device. The automatic feeding device comprises a power mechanism, a grinding assembly, a driving mechanism, an intermittent feeding assembly, a screening material guide plate, a belt, a; the biomass raw material crushing device can crush biomass raw materials fully, can perform intermittent blanking, prevent blockage, can continuously push the biomass raw materials to move downwards, improve crushing efficiency, can screen the crushed biomass raw materials, does not need manual secondary reworking treatment, ensures that the crushed biomass raw materials can be combusted fully, improves power generation efficiency, and reduces resource waste.

Description

New forms of energy living beings processing apparatus

Technical Field

The invention relates to the technical field of new energy, in particular to a new energy biomass processing device.

Background

Along with the continuous reduction of non-renewable energy, the biomass energy is widely used gradually, the straw of plant is mainly used in traditional biomass power generation, the power generation process of straw needs to burn, in order to realize the abundant burning of straw, the straw needs to be cut up. The prior art needs to crush the straw biomass before the straw biomass is utilized, but only simply smashes once, can not realize sufficient crushing to the straw many times, can cause the crushed particles to not reach the use requirement like this, and crushing effect is unsatisfactory to can not screen the straw after smashing, lead to the straw after smashing not of uniform size, can not satisfy the needs of straw burning electricity generation. Multiple reworking operations are also required.

Disclosure of Invention

The invention aims to provide a new energy biomass processing device which has the advantages that biomass raw materials can be fully crushed and can be subjected to multiple crushing, the crushing effect is good, the device can intermittently feed materials, the phenomenon of blockage is prevented, meanwhile, the biomass raw materials can be continuously pushed to move downwards, the crushing efficiency is improved, the crushed biomass raw materials can be screened so as to screen out the biomass raw materials meeting the requirement, secondary reworking treatment is not needed manually, the crushed biomass raw materials can be fully combusted, the power generation efficiency is improved, and the waste of resources is reduced.

The purpose of the invention is realized by the following technical scheme:

a new energy biomass processing device comprises a base, a power mechanism, a crushing assembly, a driving mechanism, an intermittent feeding assembly, a screening guide plate, a circulating loopback assembly and a collecting box, wherein the power mechanism is fixedly connected to the base and is in transmission connection with the crushing assembly through a belt, the crushing assembly is fixedly connected to the base and is in transmission connection with the driving mechanism through a belt, the driving mechanism is fixedly connected to the upper end of the crushing assembly, the intermittent feeding assembly is fixedly connected to the middle end inside the driving mechanism, the screening guide plate is fixedly connected to the base and is in transmission connection with the crushing assembly through a belt, the upper end of the screening guide plate is positioned below the crushing assembly, the lower end of the screening guide plate is communicated with the inside of the circulating loopback assembly, the circulating loopback assembly is fixedly connected to the base, and the circulating loopback assembly is in transmission connection with the screening guide plate through a belt, the collecting box is fixedly connected to the base and located below the screening material guide plate.

The base comprises a bottom plate, a vertical plate, a connecting plate, a supporting plate and a side plate; riser and sideboard difference fixed connection are both ends about the bottom plate, collect box fixed connection in the middle-end of bottom plate, and connecting plate and backup pad difference fixed connection are in the middle-end and the upper end of riser.

The power mechanism comprises a motor and a driving belt wheel I; the motor is fixedly connected to the vertical plate through the motor frame, and the driving belt wheel I is fixedly connected to an output shaft of the motor; the driving belt wheel I is in transmission connection with the crushing assembly through a belt.

The crushing assembly comprises a feeding seat, a rectangular seat with an upper hollow part and a lower hollow part, a driving shaft, a driving belt wheel II, a driven belt wheel I, a driving gear, a driven shaft, a driving belt wheel I and a crushing cutter; the lower end of the feeding seat is fixedly connected with a rectangular seat, the rectangular seat is fixedly connected to a supporting plate, two ends of a driving shaft and two ends of a driven shaft are respectively rotatably connected to two ends of the rectangular seat through belt seat bearings, a driving belt pulley II, a driven belt pulley I and a driving gear are sequentially and fixedly connected to the driving shaft from front to back, the driving belt pulley I and the driven gear are sequentially and fixedly connected to the driven shaft from front to back, the driving belt pulley II, the driven belt pulley I, the driving gear, the driving belt pulley I and the driven gear are all located at the front end of the rectangular seat, the driven belt pulley I is in transmission connection with the driving belt pulley I through a belt, the driving belt pulley II is in transmission connection with a driving mechanism through a belt, the driving gear is in meshing; and the driving shaft and the driven shaft are fixedly connected with a plurality of crushing cutters which are positioned at the lower end inside the rectangular seat.

The driving mechanism comprises a cam rotating shaft, a rotating shaft seat, a driven belt wheel II, a cam, a rectangular sliding rod, a rod frame plate, a pressing plate, an extrusion block and a compression spring I; the both ends of cam pivot are rotated through taking the seat bearing respectively and are connected on two pivot seats, two pivot seats are fixed connection both ends around the feeding seat top surface respectively, II fixed connection of driven pulleys are in the cam pivot, driven pulleys II are located the front end of feeding seat, driven pulleys II pass through the belt transmission with driving pulley II and are connected, cam fixed connection is in the middle-end of cam pivot, rectangle slide bar sliding connection is in the pole frame board, pole frame board fixed connection is on the inner wall of feeding seat, clamp plate and stripper block fixed connection are the upper and lower both ends of rectangle slide bar respectively, the stripper block is the structure of falling the trapezoid, clamp plate and cam laminating, the cover is equipped with compression spring I on the rectangle slide bar between clamp plate and the pole frame board.

The intermittent feeding assembly comprises a striker plate, a rectangular through groove, a pressing block, a Z-shaped limiting plate, a rectangular limiting rod, a compression spring II, a push rod sliding seat plate, a push rod, a spring seat plate, a spring sleeve rod and a compression spring III; the striker plate is fixedly connected to the upper end of the inner side of the rotating shaft seat, two rectangular through grooves are symmetrically formed in the striker plate, two pressing blocks are symmetrically and slidably connected into the two rectangular through grooves, the upper ends of the two pressing blocks are inclined, and two ends of the two pressing blocks are fixedly connected with a Z-shaped limiting plate respectively; the Z-shaped limiting plate is connected to the rectangular limiting rod in a sliding mode, the top end of the rectangular limiting rod is fixedly connected with the baffle, the bottom end of the rectangular limiting rod is fixedly connected to the striker plate, and the rectangular limiting rod between the striker plate and the Z-shaped limiting plate is sleeved with a compression spring II; two ejector rod sliding seat plates are symmetrically and fixedly connected to the material baffle plate, the two ejector rods are respectively and slidably connected into the two ejector rod sliding seat plates, the outer ends of the two ejector rods respectively abut against the inclined surfaces of the two pressing blocks, the inner ends of the two ejector rods are respectively and fixedly connected with a spring seat plate, the two spring seat plates are respectively and slidably connected to two spring loop rods, and the two spring loop rods are respectively and fixedly connected to the two ejector rod sliding seat plates; and a compression spring III is sleeved on a spring loop bar between the ejector rod sliding seat plate and the spring seat plate.

The screening material guide plate comprises a material guide inclined plate, a roller rotating shaft, a grinding roller, a transmission belt wheel I and a driving belt wheel II; guide swash plate fixed connection is on the connecting plate, the upper end of guide swash plate is located the below of rectangle seat, the middle-end of connection at the guide swash plate is rotated through the rolling bearing respectively at the both ends of roller pivot, driving pulley I and driving pulley II are fixed connection respectively in the outer end at roller pivot both ends, driving pulley I passes through the belt drive with driving pulley I and is connected, the roller fixed connection that mills is in the middle-end of roller pivot, driving pulley II and circulation loopback subassembly pass through the belt drive and are connected, evenly be provided with a plurality of circular through-holes on the guide swash plate.

The circulating and returning assembly comprises a returning cylinder body, a blade rotating shaft, a worm wheel, a worm, a transmission belt wheel II, a worm frame plate, rotary conveying blades and a discharging pipe; loopback a body fixed connection on the sideboard, the upper and lower both ends of connection at loopback a body are rotated through the rolling bearing respectively at the both ends of blade pivot, the equal fixed connection of rotary conveying worm wheel and rotary conveying blade is in the blade pivot, rotary conveying blade rotates to be connected in loopback a body, the worm wheel is located the top of loopback a body, the worm wheel is connected with worm meshing transmission, the one end of worm is passed through rolling bearing and is connected on the worm frame plate, worm frame plate fixed connection and intercommunication are in the upper end of loopback a body, the other end fixed connection driving pulley II of worm, driving pulley II passes through the belt transmission with driving pulley II and is connected, arrange material pipe fixed connection and intercommunication in the upper end of loopback a body, it is located the top of feed seat to arrange the material pipe.

Both ends of the ejector rod are of semicircular structures.

The new energy biomass processing and treating device has the beneficial effects that:

according to the new energy biomass processing device, biomass raw materials can be fully crushed and can be subjected to multiple crushing, the crushing effect is good, the intermittent blanking can be realized, the blockage phenomenon is prevented, meanwhile, the biomass raw materials can be continuously pushed to move downwards, the crushing efficiency is improved, the crushed biomass raw materials can be screened, so that the biomass raw materials meeting the requirement can be screened, the secondary rework treatment is not needed, the crushed biomass raw materials can be fully combusted, the power generation efficiency is improved, and the waste of resources is reduced.

Drawings

Fig. 1 is a schematic structural diagram of a new energy biomass processing device according to the invention;

FIG. 2 is a schematic structural diagram II of a new energy biomass processing device according to the present invention;

FIG. 3 is a schematic view of the base and the collection box;

FIG. 4 is a schematic structural view of the power mechanism;

FIG. 5 is a schematic view of the shredder assembly;

FIG. 6 is a schematic view of a portion of the size reduction assembly;

FIG. 7 is a schematic view of the driving mechanism;

FIG. 8 is a schematic structural view of an intermittent feed assembly;

FIG. 9 is a schematic view showing the structure of a screening guide plate;

FIG. 10 is a schematic diagram of the loop back assembly;

fig. 11 is a schematic cross-sectional view of the loop back assembly.

In the figure: a base 1; a bottom plate 1-1; a vertical plate 1-2; connecting plates 1-3; support plates 1-4; 1-5 of side plates; a power mechanism 2; a motor 2-1; a driving belt wheel I2-2; a crushing assembly 3; a feeding seat 3-1; a rectangular base 3-2; 3-3 of a driving shaft; a driving belt wheel II 3-4; 3-5 parts of a driven belt wheel; 3-6 parts of a driving gear; 3-7 parts of a driven gear; 3-8 parts of a driven shaft; a driving belt wheel I3-9; 3-10 parts of a crushing cutter; a drive mechanism 4; a cam rotating shaft 4-1; 4-2 of a rotating shaft seat; a driven belt wheel II 4-3; 4-4 of a cam; 4-5 of a rectangular slide bar; 4-6 of a lever frame plate; 4-7 of a pressing plate; 4-8 parts of an extrusion block; 4-9 parts of a compression spring; a batch feed assembly 5; 5-1 of a material baffle plate; a rectangular through groove 5-2; 5-3 of briquetting; 5-4 parts of Z-shaped limiting plates; 5-5 of a rectangular limiting rod; 5-6 parts of a compression spring; 5-7 parts of a mandril slide seat plate; 5-8 of a mandril; 5-9 parts of spring seat plate; 5-10 parts of spring sleeve rod; 5-11 parts of a compression spring; a screening material guide plate 6; a material guiding inclined plate 6-1; a roller rotating shaft 6-2; 6-3 parts of grinding roller; 6-4 of a transmission belt wheel; a driving belt wheel II 6-5; a circulating back-feeding assembly 7; a return cylinder body 7-1; a blade rotating shaft 7-2; a worm wheel 7-3; 7-4 parts of worm; a transmission belt wheel II 7-5; 7-6 of a worm frame plate; rotary conveying blades 7-7; 7-8 parts of a discharge pipe; a collection box 8.

Detailed Description

The invention is described in further detail below with reference to figures 1-11 and the specific implementation.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 11, and a new energy biomass processing device includes a base 1, a power mechanism 2, a pulverizing assembly 3, a driving mechanism 4, an intermittent feeding assembly 5, a sieving material guide plate 6, a circulating returning assembly 7 and a collecting box 8, wherein the power mechanism 2 is fixedly connected to the base 1, the power mechanism 2 is connected to the pulverizing assembly 3 through belt transmission, the pulverizing assembly 3 is fixedly connected to the base 1, the pulverizing assembly 3 is connected to the driving mechanism 4 through belt transmission, the driving mechanism 4 is fixedly connected to the upper end of the pulverizing assembly 3, the intermittent feeding assembly 5 is fixedly connected to the middle end inside the driving mechanism 4, the sieving material guide plate 6 is fixedly connected to the base 1, the sieving material guide plate 6 is connected to the pulverizing assembly 3 through belt transmission, the upper end of the sieving material guide plate 6 is located below the pulverizing assembly 3, the lower extreme of screening stock guide 6 and the inside intercommunication that the subassembly 7 was returned to the circulation, the circulation returns the subassembly 7 fixed connection that returns on base 1, the circulation returns the subassembly 7 and is connected through belt transmission with screening stock guide 6, collects box 8 fixed connection on base 1, collects box 8 and is located the below of screening stock guide 6. When the biomass material crusher is used, biomass materials to be processed are put into the crushing assembly 3, the power mechanism 2 can drive the crushing assembly 3 to work after being electrified, the crushing assembly 3 can drive the driving mechanism 4 to work, the intermittent feeding assembly 5 can be controlled to work when the driving mechanism 4 works, the biomass materials at the upper end of the crushing assembly 3 intermittently fall to the lower end of the crushing assembly 3 to be crushed when the intermittent feeding assembly 5 works, the phenomenon of blockage is prevented, meanwhile, the intermittent feeding assembly 5 can continuously push the biomass materials at the lower end of the crushing assembly 3 to move downwards, the crushing efficiency is improved, the crushed biomass materials fall on the guide plate 6, the crushing assembly 3 can drive the guide plate 6 to work, the guide plate 6 can screen and mill the crushed biomass materials, and the biomass materials meeting the requirements directly fall into the collecting box 8, the during operation of stock guide 6 can carry out the secondary to unqualified biomass feedstock after the screening and mill, and the secondary mills that the biomass feedstock after handling meets the requirements and falls into and collect in the box 8, unqualified then returns subassembly 7 through the circulation and carry out broken handle in dropping into crushing unit 3 again, until meeting the demands, does not need the manual work to carry out the secondary and does over again and handle, guarantees the burning that the biomass feedstock after smashing can be abundant, improves the efficiency of electricity generation, reduces the waste of resource.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1-11, wherein the base 1 includes a bottom plate 1-1, a vertical plate 1-2, a connecting plate 1-3, a supporting plate 1-4 and a side plate 1-5; the vertical plate 1-2 and the side plate 1-5 are respectively and fixedly connected with the left end and the right end of the bottom plate 1-1, the collecting box 8 is fixedly connected with the middle end of the bottom plate 1-1, and the connecting plate 1-3 and the supporting plate 1-4 are respectively and fixedly connected with the middle end and the upper end of the vertical plate 1-2.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 11, wherein the power mechanism 2 includes a motor 2-1 and a driving pulley i 2-2; the motor 2-1 is fixedly connected to the vertical plate 1-2 through a motor frame, and the driving belt wheel I2-2 is fixedly connected to an output shaft of the motor 2-1; the driving belt wheel I2-2 is in transmission connection with the crushing assembly 3 through a belt. When the power mechanism 2 is used, the motor 2-1 is connected with the power supply and the control switch through the conducting wire and is started, the motor 2-1 drives the driving belt wheel I2-2 to rotate anticlockwise around the axis of the motor 2-1, and the driving belt wheel I2-2 drives the crushing assembly 3 to work.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-11, wherein the crushing assembly 3 comprises a feeding seat 3-1, a rectangular seat 3-2 with a hollow upper part and a hollow lower part, a driving shaft 3-3, a driving belt pulley II 3-4, a driven belt pulley I3-5, a driving gear 3-6, a driven gear 3-7, a driven shaft 3-8, a driving belt pulley I3-9 and a crushing knife 3-10; the lower end of a feeding seat 3-1 is fixedly connected with a rectangular seat 3-2, the rectangular seat 3-2 is fixedly connected on a supporting plate 1-4, two ends of a driving shaft 3-3 and a driven shaft 3-8 are respectively and rotatably connected with two ends of the rectangular seat 3-2 through a bearing with a seat, a driving pulley II 3-4, a driven pulley I3-5 and a driving gear 3-6 are sequentially and fixedly connected on the driving shaft 3-3 from front to back, a driving pulley I3-9 and a driven gear 3-7 are sequentially and fixedly connected on the driven shaft 3-8 from front to back, the driving pulley II 3-4, the driven pulley I3-5, the driving gear 3-6, the driving pulley I3-9 and the driven gear 3-7 are all positioned at the front end of the rectangular seat 3-2, the driven pulley I3-5 is in transmission connection with the driving pulley I2-2 through a belt, the driving belt wheels II 3-4 are in transmission connection with the driving mechanism 4 through belts, the driving gears 3-6 are in meshing transmission with the driven gears 3-7, and the driving belt wheels I3-9 are in transmission connection with the screening material guide plate 6 through belts; the driving shaft 3-3 and the driven shaft 3-8 are both fixedly connected with a plurality of crushing knives 3-10, and the crushing knives 3-10 are positioned at the lower end inside the rectangular seat 3-2. When the crushing assembly 3 is used, biomass raw materials are put into the feeding seat 3-1 and fall into the rectangular seat 3-2 of the rectangular seat, the driving belt wheel I2-2 drives the driven belt wheel I3-5 to rotate anticlockwise around the axis of the driven belt wheel I3-5, the driven belt wheel I3-5 drives the driving shaft 3-3 to rotate anticlockwise around the axis of the driven belt wheel I3-2, the driving shaft 3-3 drives the driving belt wheel II 3-4 and the driving gear 3-6 to rotate anticlockwise around the axis of the driven belt wheel II 3-4, the driving belt wheel II 3-4 drives the driving mechanism 4 to work, the driving gear 3-6 drives the driven gear 3-7 to rotate clockwise around the axis of the driven belt wheel I3-9, the driven gear 3-7 drives the driven shaft 3-8 to rotate clockwise around the axis of the driven shaft, the driving belt wheels I3-9 drive the screening material guide plate 6 to work, and the driving shafts 3-3 and the driven shafts 3-8 respectively drive the crushing cutters 3-10 on the driving shafts to rotate oppositely to crush the biomass raw materials in the rectangular seat 3-2.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1-11, and the driving mechanism 4 includes a cam rotating shaft 4-1, a rotating shaft seat 4-2, a driven pulley ii 4-3, a cam 4-4, a rectangular sliding rod 4-5, a rod frame plate 4-6, a pressure plate 4-7, an extrusion block 4-8 and a compression spring i 4-9; two ends of a cam rotating shaft 4-1 are respectively and rotatably connected on two rotating shaft seats 4-2 through belt seat bearings, the two rotating shaft seats 4-2 are respectively and fixedly connected at the front end and the rear end of the top surface of a feeding seat 3-1, a driven belt pulley II 4-3 is fixedly connected on the cam rotating shaft 4-1, the driven belt pulley II 4-3 is positioned at the front end of the feeding seat 3-1, the driven belt pulley II 4-3 is in transmission connection with a driving belt pulley II 3-4 through a belt, a cam 4-4 is fixedly connected at the middle end of the cam rotating shaft 4-1, a rectangular sliding rod 4-5 is in sliding connection with a rod frame plate 4-6, the rod frame plate 4-6 is fixedly connected on the inner wall of the feeding seat 3-1, a pressing plate 4-7 and an extrusion block 4-8 are respectively and fixedly connected at the upper end and, the extrusion block 4-8 is of an inverted trapezoidal structure, the pressing plate 4-7 is attached to the cam 4-4, and the compression spring I4-9 is sleeved on the rectangular sliding rod 4-5 between the pressing plate 4-7 and the rod frame plate 4-6. When the driving mechanism 4 is used, the driving belt wheel II 3-4 drives the driven belt wheel II 4-3 to rotate around the axis of the driving mechanism, the driven belt wheel II 4-3 drives the cam rotating shaft 4-1 to rotate around the axis of the driving mechanism, the cam rotating shaft 4-1 drives the cam 4-4 to rotate around the axis of the driving mechanism, the cam 4-4 intermittently extrudes the pressing plate 4-7 downwards when rotating, the pressing plate 4-7 drives the extrusion block 4-8 to reciprocate up and down, and the compression spring I4-9 facilitates the resetting of the extrusion block 4-8.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1-11, and the intermittent feeding assembly 5 comprises a striker plate 5-1, a rectangular through groove 5-2, a pressing block 5-3, a Z-shaped limiting plate 5-4, a rectangular limiting rod 5-5, a compression spring II 5-6, a top rod slide plate 5-7, a top rod 5-8, a spring seat plate 5-9, a spring loop rod 5-10 and a compression spring III 5-11; the striker plate 5-1 is fixedly connected to the upper end of the inner side of the rotating shaft seat 4-2, the striker plate 5-1 is symmetrically provided with two rectangular through grooves 5-2, two pressing blocks 5-3 are symmetrically and slidably connected in the two rectangular through grooves 5-2, the upper ends of the two pressing blocks 5-3 are inclined, and two ends of the two pressing blocks 5-3 are respectively and fixedly connected with a Z-shaped limiting plate 5-4; the Z-shaped limiting plate 5-4 is connected to the rectangular limiting rod 5-5 in a sliding mode, the top end of the rectangular limiting rod 5-5 is fixedly connected with the baffle, the bottom end of the rectangular limiting rod 5-5 is fixedly connected to the material baffle 5-1, and the rectangular limiting rod 5-5 between the material baffle 5-1 and the Z-shaped limiting plate 5-4 is sleeved with a compression spring II 5-6; two ejector rod slide seat plates 5-7 are symmetrically and fixedly connected to the striker plate 5-1, the two ejector rods 5-8 are respectively and slidably connected into the two ejector rod slide seat plates 5-7, the outer ends of the two ejector rods 5-8 are respectively abutted against the inclined surfaces of the two pressing blocks 5-3, the inner ends of the two ejector rods 5-8 are respectively and fixedly connected with a spring seat plate 5-9, the two spring seat plates 5-9 are respectively and slidably connected to the two spring loop bars 5-10, and the two spring loop bars 5-10 are respectively and fixedly connected to the two ejector rod slide seat plates 5-7; and a compression spring III 5-11 is sleeved on a spring loop bar 5-10 between the ejector rod slide seat plate 5-7 and the spring seat plate 5-9. When the intermittent feeding assembly 5 is used, the extrusion block 4-8 can extrude the two ejector rods 5-8 when moving downwards, so that the two ejector rods 5-8 slide outwards at the same time, the compression spring III 5-11 is compressed, the two ejector rods 5-8 extrude the inclined planes of the two pressing blocks 5-3, so that the two pressing blocks 5-3 slide downwards, the compression spring II 5-6 is compressed, the feeding seat 3-1 is communicated with the rectangular seat 3-2 at the moment, biomass raw materials enter the rectangular seat 3-2 through the inclined planes at the upper ends of the two pressing blocks 5-3, the two pressing blocks 5-3 can push the biomass raw materials in the rectangular seat 3-2 downwards when sliding downwards, the crushing speed is improved, when the extrusion block 4-8 moves upwards and resets, the two ejector rods 5-8 reset under the action of the compression spring III 5-11, the two pressing blocks 5-3 are reset under the action of the compression springs II 5-6, the feeding seat 3-1 is separated from the rectangular seat 3-2, the blanking is stopped at the moment, and the extruding blocks 4-8 reciprocate up and down to realize intermittent feeding to prevent the blockage.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 11, and the screening material guide plate 6 includes a material guide sloping plate 6-1, a roller rotating shaft 6-2, a grinding roller 6-3, a driving pulley i 6-4 and a driving pulley ii 6-5; the material guide inclined plate 6-1 is fixedly connected to the connecting plate 1-3, the upper end of the material guide inclined plate 6-1 is located below the rectangular seat 3-2, two ends of the roller rotating shaft 6-2 are rotatably connected to the middle end of the material guide inclined plate 6-1 through belt seat bearings respectively, the transmission belt wheel I6-4 and the driving belt wheel II 6-5 are fixedly connected to the outer ends of two ends of the roller rotating shaft 6-2 respectively, the transmission belt wheel I6-4 is in transmission connection with the driving belt wheel I3-9 through a belt, the grinding roller 6-3 is fixedly connected to the middle end of the roller rotating shaft 6-2, the driving belt wheel II 6-5 is in transmission connection with the circulating and returning assembly 7 through a belt, and the material guide inclined plate 6-1 is uniformly provided with a plurality of circular. When the screening material guide plate 6 is used, crushed biomass raw materials fall on the material guide inclined plate 6-1 for screening, the biomass raw materials meeting requirements directly fall into the collection box 8 through the circular through hole on the material guide inclined plate 6-1, the unqualified biomass raw materials after screening slide downwards, the driving belt wheel I3-9 drives the driving belt wheel I6-4 to rotate clockwise around the axis of the driving belt wheel I6-4, the driving belt wheel I6-4 drives the roller rotating shaft 6-2 to rotate clockwise around the axis of the driving belt wheel I, the roller rotating shaft 6-2 drives the grinding roller 6-3 and the driving belt wheel II 6-5 to rotate clockwise around the axis of the driving belt wheel II, the unqualified biomass raw materials are ground when the grinding roller 6-3 rotates clockwise, and the ground biomass raw materials directly fall into the collection box 8 through the circular through hole on the material guide inclined plate 6-1 for collection if meeting requirements, the biomass raw material which is not qualified after being milled slides down into the circulating and returning assembly 7 under the action of gravity.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1 to 11, and the circulating and returning assembly 7 comprises a returning cylinder body 7-1, a blade rotating shaft 7-2, a worm wheel 7-3, a worm 7-4, a driving pulley ii 7-5, a worm frame plate 7-6, a rotary conveying blade 7-7 and a discharging pipe 7-8; the back conveying cylinder body 7-1 is fixedly connected to the side plates 1-5, two ends of a blade rotating shaft 7-2 are respectively and rotatably connected to the upper end and the lower end of the back conveying cylinder body 7-1 through bearing blocks, a rotary conveying worm wheel 7-3 and a rotary conveying blade 7-7 are both fixedly connected to the blade rotating shaft 7-2, the rotary conveying blade 7-7 is rotatably connected into the back conveying cylinder body 7-1, the worm wheel 7-3 is positioned above the back conveying cylinder body 3-1, the worm wheel 7-3 is in meshing transmission connection with the worm 7-4, one end of the worm 7-4 is rotatably connected to a worm frame plate 7-6 through the bearing blocks, the worm frame plate 7-6 is fixedly connected and communicated with the upper end of the back conveying cylinder body 7-1, the other end of the worm 7-4 is fixedly connected with a transmission belt wheel II 7-, the driving belt wheel II 7-5 is in transmission connection with the driving belt wheel II 6-5 through a belt, the discharging pipe 7-8 is fixedly connected and communicated with the upper end of the returning cylinder body 7-1, and the discharging pipe 7-8 is positioned above the feeding seat 3-1. When the circulating and returning assembly 7 is used, the driving belt wheel II 6-5 drives the driving belt wheel II 7-5 to rotate around the axis of the driving belt wheel II 7-5 through a belt, the driving belt wheel II 7-5 drives the worm 7-4 to rotate around the axis of the driving belt wheel II, the worm 7-4 drives the worm wheel 7-3 to rotate around the axis of the driving belt wheel II, the rotary conveying worm wheel 7-3 drives the blade rotating shaft 7-2 to rotate around the axis of the driving belt wheel II, the blade rotating shaft 7-2 drives the rotary conveying blade 7-7 to rotate around the axis of the driving belt wheel II, biomass raw materials which do not meet requirements are conveyed upwards when the rotary conveying blade 7-7 rotates, and the biomass raw materials are returned to the feeding seat 3-.

The specific implementation method nine:

the present embodiment is described below with reference to fig. 1 to 11, wherein both ends of the push rod 5 to 8 are semi-circular structures to reduce the friction force when the push rod 5 to 8 moves.

The working principle of the new energy biomass processing device is as follows: when the biomass material crusher is used, biomass materials to be processed are put into the crushing assembly 3, the power mechanism 2 can drive the crushing assembly 3 to work after being electrified, the crushing assembly 3 can drive the driving mechanism 4 to work, the intermittent feeding assembly 5 can be controlled to work when the driving mechanism 4 works, the biomass materials at the upper end of the crushing assembly 3 intermittently fall to the lower end of the crushing assembly 3 to be crushed when the intermittent feeding assembly 5 works, the phenomenon of blockage is prevented, meanwhile, the intermittent feeding assembly 5 can continuously push the biomass materials at the lower end of the crushing assembly 3 to move downwards, the crushing efficiency is improved, the crushed biomass materials fall on the guide plate 6, the crushing assembly 3 can drive the guide plate 6 to work, the guide plate 6 can screen and mill the crushed biomass materials, and the biomass materials meeting the requirements directly fall into the collecting box 8, the during operation of stock guide 6 can carry out the secondary to unqualified biomass feedstock after the screening and mill, and the secondary mills that the biomass feedstock after handling meets the requirements and falls into and collect in the box 8, unqualified then returns subassembly 7 through the circulation and carry out broken handle in dropping into crushing unit 3 again, until meeting the demands, does not need the manual work to carry out the secondary and does over again and handle, guarantees the burning that the biomass feedstock after smashing can be abundant, improves the efficiency of electricity generation, reduces the waste of resource.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (3)

1. The utility model provides a new forms of energy living beings processing apparatus, includes base (1), power unit (2), crushing unit (3), actuating mechanism (4), intermittent type feeding subassembly (5), screening stock guide (6), circulation loopback subassembly (7) and collect box (8), its characterized in that: the power mechanism (2) is fixedly connected on the base (1), the power mechanism (2) is connected with the crushing component (3) through belt transmission, the crushing component (3) is fixedly connected on the base (1), the crushing component (3) is connected with the driving mechanism (4) through belt transmission, the driving mechanism (4) is fixedly connected at the upper end of the crushing component (3), the intermittent feeding component (5) is fixedly connected at the middle end inside the driving mechanism (4), the screening guide plate (6) is fixedly connected on the base (1), the screening guide plate (6) is connected with the crushing component (3) through belt transmission, the upper end of the screening guide plate (6) is positioned below the crushing component (3), the lower end of the screening guide plate (6) is communicated with the inside of the circulating loopback component (7), the circulating loopback component (7) is fixedly connected on the base (1), the circulating loopback component (7) is connected with the screening guide plate (6) through a transmission belt, the collecting box (8) is fixedly connected to the base (1), and the collecting box (8) is positioned below the screening material guide plate (6);

the base (1) comprises a bottom plate (1-1), a vertical plate (1-2), a connecting plate (1-3), a supporting plate (1-4) and a side plate (1-5); the vertical plate (1-2) and the side plate (1-5) are respectively and fixedly connected to the left end and the right end of the bottom plate (1-1), the collecting box (8) is fixedly connected to the middle end of the bottom plate (1-1), and the connecting plate (1-3) and the supporting plate (1-4) are respectively and fixedly connected to the middle end and the upper end of the vertical plate (1-2);

the power mechanism (2) comprises a motor (2-1) and a driving belt wheel I (2-2); the motor (2-1) is fixedly connected to the vertical plate (1-2) through a motor frame, and the driving belt wheel I (2-2) is fixedly connected to an output shaft of the motor (2-1); the driving belt wheel I (2-2) is in transmission connection with the crushing assembly (3) through a belt;

the crushing assembly (3) comprises a feeding seat (3-1), a rectangular seat (3-2) which is hollow at the upper part and the lower part, a driving shaft (3-3), a driving belt wheel II (3-4), a driven belt wheel I (3-5), a driving gear (3-6), a driven gear (3-7), a driven shaft (3-8), a driving belt wheel I (3-9) and a crushing knife (3-10); the lower end of a feeding seat (3-1) is fixedly connected with a rectangular seat (3-2), the rectangular seat (3-2) is fixedly connected to a supporting plate (1-4), two ends of a driving shaft (3-3) and a driven shaft (3-8) are respectively and rotatably connected to two ends of the rectangular seat (3-2), a driving pulley II (3-4), a driven pulley I (3-5) and a driving gear (3-6) are sequentially and fixedly connected to the driving shaft (3-3) from front to back, a driving pulley I (3-9) and a driven gear (3-7) are sequentially and fixedly connected to the driven shaft (3-8) from front to back, the driving pulley II (3-4), the driven pulley I (3-5), the driving gear (3-6), the driving pulley I (3-9) and the driven gear (3-7) are all located at the front end of the rectangular seat (3-2), the driven belt wheel I (3-5) is in transmission connection with the driving belt wheel I (2-2) through a belt, the driving belt wheel II (3-4) is in transmission connection with the driving mechanism (4) through the belt, the driving gear (3-6) is in meshing transmission with the driven gear (3-7), and the driving belt wheel I (3-9) is in transmission connection with the screening material guide plate (6) through the belt; the driving shaft (3-3) and the driven shaft (3-8) are fixedly connected with a plurality of crushing knives (3-10), and the crushing knives (3-10) are positioned at the lower end of the inside of the rectangular seat (3-2);

the driving mechanism (4) comprises a cam rotating shaft (4-1), a rotating shaft seat (4-2), a driven belt wheel II (4-3), a cam (4-4), a rectangular sliding rod (4-5), a rod frame plate (4-6), a pressing plate (4-7), an extrusion block (4-8) and a compression spring I (4-9); two ends of a cam rotating shaft (4-1) are respectively and rotatably connected to two rotating shaft seats (4-2), the two rotating shaft seats (4-2) are respectively and fixedly connected to the front end and the rear end of the top surface of a feeding seat (3-1), a driven pulley II (4-3) is fixedly connected to the cam rotating shaft (4-1), the driven pulley II (4-3) is positioned at the front end of the feeding seat (3-1), the driven pulley II (4-3) is in transmission connection with a driving pulley II (3-4) through a belt, a cam (4-4) is fixedly connected to the middle end of the cam rotating shaft (4-1), a rectangular sliding rod (4-5) is slidably connected into a rod frame plate (4-6), the rod frame plate (4-6) is fixedly connected to the inner wall of the feeding seat (3-1), and a pressing plate (4-7) and an extrusion block (4-8) are respectively and fixedly connected to the rectangular sliding rod (4-5) ) The upper end and the lower end of the pressing block (4-8) are in an inverted trapezoidal structure, a pressing plate (4-7) is attached to a cam (4-4), and a compression spring I (4-9) is sleeved on a rectangular sliding rod (4-5) between the pressing plate (4-7) and a rod frame plate (4-6);

the intermittent feeding assembly (5) comprises a material baffle plate (5-1), a rectangular through groove (5-2), a pressing block (5-3), a Z-shaped limiting plate (5-4), a rectangular limiting rod (5-5), a compression spring II (5-6), an ejector rod sliding seat plate (5-7), an ejector rod (5-8), a spring seat plate (5-9), a spring loop rod (5-10) and a compression spring III (5-11); the striker plate (5-1) is fixedly connected to the upper end of the inner side of the rotating shaft seat (4-2), two rectangular through grooves (5-2) are symmetrically arranged on the striker plate (5-1), two pressing blocks (5-3) are symmetrically and slidably connected in the two rectangular through grooves (5-2), the upper ends of the two pressing blocks (5-3) are inclined, and two Z-shaped limiting plates (5-4) are fixedly connected to two ends of the two pressing blocks (5-3) respectively; the Z-shaped limiting plate (5-4) is connected to the rectangular limiting rod (5-5) in a sliding mode, the top end of the rectangular limiting rod (5-5) is fixedly connected with the baffle, the bottom end of the rectangular limiting rod (5-5) is fixedly connected to the material baffle plate (5-1), and a compression spring II (5-6) is sleeved on the rectangular limiting rod (5-5) between the material baffle plate (5-1) and the Z-shaped limiting plate (5-4); two ejector rod sliding seat plates (5-7) are symmetrically and fixedly connected to the striker plate (5-1), the two ejector rods (5-8) are respectively and slidably connected into the two ejector rod sliding seat plates (5-7), the outer ends of the two ejector rods (5-8) are respectively abutted to the inclined surfaces of the two pressing blocks (5-3), the inner ends of the two ejector rods (5-8) are respectively and fixedly connected with a spring seat plate (5-9), the two spring seat plates (5-9) are respectively and slidably connected onto the two spring loop bars (5-10), and the two spring loop bars (5-10) are respectively and fixedly connected onto the two ejector rod sliding seat plates (5-7); a compression spring III (5-11) is sleeved on a spring loop bar (5-10) between the ejector rod slide seat plate (5-7) and the spring seat plate (5-9);

the screening material guide plate (6) comprises a material guide inclined plate (6-1), a roller rotating shaft (6-2), a grinding roller (6-3), a transmission belt wheel I (6-4) and a driving belt wheel II (6-5); the material guide inclined plate (6-1) is fixedly connected to the connecting plate (1-3), the upper end of the material guide inclined plate (6-1) is located below the rectangular seat (3-2), two ends of the roller rotating shaft (6-2) are respectively and rotatably connected to the middle end of the material guide inclined plate (6-1), the transmission belt pulley I (6-4) and the driving belt pulley II (6-5) are respectively and fixedly connected to the outer ends of two ends of the roller rotating shaft (6-2), the transmission belt pulley I (6-4) is in transmission connection with the driving belt pulley I (3-9) through a belt, the grinding roller (6-3) is fixedly connected to the middle end of the roller rotating shaft (6-2), the driving belt pulley II (6-5) is in transmission connection with the circulating and returning assembly (7) through a belt, and a plurality of circular through holes are uniformly formed in the material guide inclined plate (6-1).

2. The new energy biomass processing device according to claim 1, characterized in that: the circulating and returning assembly (7) comprises a returning cylinder body (7-1), a blade rotating shaft (7-2), a worm wheel (7-3), a worm (7-4), a transmission belt wheel II (7-5), a worm frame plate (7-6), a rotary conveying blade (7-7) and a discharging pipe (7-8); the back conveying cylinder body (7-1) is fixedly connected to the side plates (1-5), two ends of the blade rotating shaft (7-2) are respectively and rotatably connected to the upper end and the lower end of the back conveying cylinder body (7-1), the rotary conveying worm wheel (7-3) and the rotary conveying blade (7-7) are both fixedly connected to the blade rotating shaft (7-2), the rotary conveying blade (7-7) is rotatably connected into the back conveying cylinder body (7-1), the worm wheel (7-3) is positioned above the back conveying cylinder body (3-1), the worm wheel (7-3) is in meshing transmission connection with the worm (7-4), one end of the worm (7-4) is rotatably connected to the worm frame plate (7-6), the worm frame plate (7-6) is fixedly connected and communicated with the upper end of the back conveying cylinder body (7-1), the other end of the worm (7-4) is fixedly connected with a driving belt wheel II (7-5), the driving belt wheel II (7-5) is in driving connection with a driving belt wheel II (6-5) through a belt, a discharging pipe (7-8) is fixedly connected and communicated with the upper end of the returning cylinder body (7-1), and the discharging pipe (7-8) is positioned above the feeding seat (3-1).

3. The new energy biomass processing device according to claim 2, characterized in that: both ends of the ejector rod (5-8) are of semicircular structures.

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