阅读说明：本技术 一种多功能的可自动下料的涡轮粉碎机 (Multifunctional turbine crusher capable of automatically discharging ) 是由 魏素花 魏罡 张宗武 于 2020-05-25 设计创作，主要内容包括：本发明提供一种多功能的可自动下料的涡轮粉碎机,包括粉碎外框,缓冲入料架结构,纵向固定架,旋转轴,从动轮,主动轮,传动带,驱动电机,旋转存放架结构,辅助破碎架结构,大孔径网板,小孔径网板,破碎刀片,引风扇,布层,透气孔,出料斗,振动导出架结构,导出斗和电源开关,所述的缓冲入料架结构安装在粉碎外框的上部；所述的纵向固定架焊接在粉碎外框的下部四角处；所述的从动轮焊接在旋转轴的左端。本发明导出孔分别开设在振动板的中间位置,打开电源开关给振动电机供电,振动电机带动振动板左侧的固定板从缓冲弹簧内上下活动,从而使经过粉碎外框中间位置合格的料物向下掉落,从而实现提前将成品料排出的功能。(The invention provides a multifunctional turbine crusher capable of automatically discharging materials, which comprises a crushing outer frame, a buffering feeding frame structure, a longitudinal fixing frame, a rotating shaft, a driven wheel, a driving belt, a driving motor, a rotating storage frame structure, an auxiliary crushing frame structure, a large-aperture screen plate, a small-aperture screen plate, a crushing blade, a guide fan, a cloth layer, an air vent, a discharging hopper, a vibration leading-out frame structure, a leading-out hopper and a power switch, wherein the buffering feeding frame structure is arranged at the upper part of the crushing outer frame; the longitudinal fixing frame is welded at the four corners of the lower part of the crushing outer frame; the driven wheel is welded at the left end of the rotating shaft. The guide holes are respectively formed in the middle of the vibrating plate, the power switch is turned on to supply power to the vibrating motor, and the vibrating motor drives the fixing plate on the left side of the vibrating plate to move up and down from the buffer spring, so that materials qualified by the middle of the crushing outer frame fall down, and the function of discharging finished materials in advance is achieved.)

1. The multifunctional turbine crusher capable of automatically discharging is characterized by comprising a crushing outer frame (1), a buffering feeding frame structure (2), a longitudinal fixing frame (3), a rotating shaft (4), a driven wheel (5), a driving wheel (6), a driving belt (7), a driving motor (8), a rotary storage frame structure (9), an auxiliary crushing frame structure (10), a large-aperture screen plate (11), a small-aperture screen plate (12), a crushing blade (13), an induced fan (14), a cloth layer (15), air vents (16), a discharging hopper (17), a vibration leading-out frame structure (18), a leading-out hopper (19) and a power switch (20), wherein the buffering feeding frame structure (2) is arranged on the upper part of the crushing outer frame (1); the longitudinal fixing frame (3) is welded at the four corners of the lower part of the crushing outer frame (1); the rotating shaft (4) transversely penetrates through the large-aperture screen plate (11), the small-aperture screen plate (12) and the cloth layer (15) and is connected with the middle price position of the crushing outer frame (1) in a shaft manner; the driven wheel (5) is welded at the left end of the rotating shaft (4); the driving wheel (6) is connected to the left output shaft of the driving motor (8) in a key way; the transmission belt (7) is sleeved on the outer sides of the driving wheel (6) and the driven wheel (5); the driving motor (8) is arranged on the left side of the lower part of the crushing outer frame (1) through a bolt; the rotary storage rack structure (9) is arranged at the lower part of the inner side of the longitudinal fixed rack (3); the auxiliary crushing frame structure (10) is arranged on the left side of the rotating shaft (4); the large-aperture screen (11) is arranged at the left position of the middle part of the crushing outer frame (1) by bolts; the small-aperture screen (12) is arranged at the right side of the middle part of the crushing outer frame (1) by bolts; the induced fan (14) is arranged on the right side of the small-aperture screen (12), and meanwhile, the bolt is installed on the outer side of the rotating shaft (4); the cloth layer (15) is arranged on the right side inside the crushing outer frame (1) through screws; the air holes (16) are formed in the upper part and the lower part of the right side of the crushing outer frame (1); the discharge hopper (17) is arranged at the lower part of the inner sides of the small-aperture screen plate (12) and the cloth layer (15) and is embedded into the inner side of the crushing outer frame (1); the vibration leading-out frame structure (18) is arranged at the middle lower part of the crushing outer frame (1); the power switch (20) is arranged on the upper part of the front side of the longitudinal fixing frame (3) through a screw; the vibration leading-out frame structure (18) comprises a rectangular frame (181), a vibration plate (182), a vibration motor (183), a fixing plate (184), a limiting plate (185), a buffer spring (186), a leading-out hole (187) and a protective pad (188), wherein the rectangular frame (181) is embedded in the middle lower part of the crushing outer frame (1); the right end of the vibrating plate (182) is axially connected to the right upper side of the inner wall of the rectangular frame (181); the vibration motor (183) is arranged on the left side of the lower part of the vibration plate (182) through screws; the number of the limiting plates (185) is two, and the limiting plates (185) are respectively welded on the left upper side of the inner wall of the rectangular frame (181) and the left side of the upper end of the rectangular frame (181); the buffer springs (186) are arranged in two numbers, and the buffer springs (186) are respectively installed on the inner sides of the limiting plates (185) through screws.

2. The multi-functional automatic blanking turbine crusher according to claim 1, characterized in that said rotary storage shelf structure (9) comprises a cross plate (91), a ball bearing (92), a rotary rod (93), a rotary disk (94), a storage tank (95), a storage bucket (96) and a support wheel (97), said cross plate (91) being bolted to the lower inner side of the longitudinal mount (3); the outer ring of the ball bearing (92) is embedded in the right position of the transverse plate (91); the rotating rod (93) is inserted into an inner ring of the ball bearing (92); the rotating disc (94) is welded on the upper part of the rotating rod (93); the storage tanks (95) are arranged at the four corners of the upper part of the rotating disc (94); the storage buckets (96) are respectively placed on the inner sides of the storage tanks (95).

3. The multi-functional automatic blanking turbine crusher of claim 1, wherein the buffer feeding frame structure (2) comprises a feeding hopper (21), a feeding pipe (22), a speed reducing motor (23), a longitudinal rod (24), a rotating pipe (25) and a spiral conveying blade (26), the feeding hopper (21) is inserted into the left side of the upper part of the feeding pipe (22); the lead-in pipe (22) is inserted at the upper part of the left side of the crushing outer frame (1); the speed reducing motor (23) is mounted in the middle of the left side of the lead-in pipe (22) through a bolt; the rotating pipe (25) is arranged on the inner side of the leading-in pipe (22), and the left side of the rotating pipe is connected with an output shaft key of the speed reducing motor (23).

4. The multi-functional automatic blanking turbine crusher according to claim 1, wherein said auxiliary crushing frame structure (10) comprises a fixed pipe (101), a turbine rotor (102), an inner connecting plate (103), a reinforcing steel rope (104), an outer connecting plate (105) and crushing teeth (106), said fixed pipe (101) being bolted to the outer left side of the rotating shaft (4); the turbine rotor (102) is welded on the left side of the outer part of the fixed pipe (101); the inner connecting plate (103) is mounted on the right side of the outer part of the fixed pipe (101) through bolts; the reinforcing steel bar ropes (104) are welded on the left side and the right side of one end, far away from the fixed pipe (101), of the inner side connecting plate (103); the outer side connecting plate (105) is welded at one end, far away from the inner side connecting plate (103), of the reinforcing steel bar rope (104).

5. The multi-functional automatic blanking turbo crusher according to claim 1, wherein a plurality of the lead-out holes (187) are provided, and the lead-out holes (187) are opened at the middle positions of the vibration plates (182), respectively.

6. The multi-function automatically baitable turbo crusher as claimed in claim 2, characterized in that said storage hopper (96) is disposed at the lower part of the discharging hopper (17) and the discharging hopper (19) while being placed at the inner side of the storage tank (95).

7. The multi-function automatic blanking turbine crusher as claimed in claim 4, wherein said crushing teeth (106) are provided in plurality, and said crushing teeth (106) are welded to the upper and lower portions of the outer connecting plate (105), respectively.

8. The multi-function automatically baitable turbo crusher as claimed in claim 3, characterized in that said spiral conveying blade (26) is disposed inside the introducing pipe (22) and is welded outside the rotating pipe (25).

9. The multi-functional automatic blanking turbine crusher as claimed in claim 1, wherein a plurality of said protection pads (188) are provided, one end of said protection pad (188) is glued on the upper right of the rectangular frame (181), the other end is glued on the right side of the upper portion of the vibrating plate (182), one end of said protection pad (188) is glued on the right side of the limiting plate (185), and the other end is glued on the left side of the vibrating plate (182).

10. The multi-function automatic blanking turbo crusher as claimed in claim 2, wherein said support wheels (97) are provided in four numbers, and said support wheels (97) are respectively journalled at four corners of the lower middle portion of the rotating disc (94).

Technical Field

The invention belongs to the technical field of turbo-crusher equipment, and particularly relates to a multifunctional automatic-discharging turbo-crusher.

Background

Most of the current turbo-crushers are provided with a crushing cavity, the crushing cavity is internally provided with a turbine and a sleeve, the sleeve is sleeved outside the turbine and fixed in the crushing cavity, the circumferential side wall of the sleeve is provided with a rack and a screen, during operation, the turbine rotates to enable material particles to be extruded, collided, sheared and the like between the side wall of the sleeve and a turbine blade, so that the material particles are ground into powder particles with smaller particle sizes, and the powder particles which accord with standard particle sizes fall down from the screen of the sleeve.

But current turbo crusher still has the inconvenience to finished product material thing discharge in advance, and is inconvenient to collect the finished product, and is poor to the crushing effect of material thing and the fast problem that influences crushing effect easily of pan feeding speed.

Therefore, it is necessary to invent a multifunctional turbine crusher capable of automatically feeding materials.

Disclosure of Invention

In order to solve the technical problems, the invention provides a multifunctional turbine crusher capable of automatically discharging materials, and aims to solve the problems that the existing turbine crusher is inconvenient to discharge finished materials in advance, collect finished products, have poor crushing effect on the materials and have high feeding speed and influence on the crushing effect easily. A multifunctional turbine crusher capable of automatically discharging materials comprises a crushing outer frame, a buffering feeding frame structure, a longitudinal fixing frame, a rotating shaft, a driven wheel, a driving belt, a driving motor, a rotating storage frame structure, an auxiliary crushing frame structure, a large-aperture screen plate, a small-aperture screen plate, a crushing blade, a guide fan, a cloth layer, an air vent, a discharging hopper, a vibration leading-out frame structure, a leading-out hopper and a power switch, wherein the buffering feeding frame structure is arranged at the upper part of the crushing outer frame; the longitudinal fixing frame is welded at the four corners of the lower part of the crushing outer frame; the rotating shaft transversely penetrates through the large-aperture screen plate, the small-aperture screen plate and the cloth layer and is connected with the middle price position of the crushing outer frame in a shaft mode; the driven wheel is welded at the left end of the rotating shaft; the driving wheel is connected to the left output shaft of the driving motor in a key manner; the driving belt is sleeved on the outer sides of the driving wheel and the driven wheel; the driving motor is mounted on the left side of the lower part of the crushing outer frame through a bolt; the rotary storage rack structure is arranged at the lower part of the inner side of the longitudinal fixing rack; the auxiliary crushing frame structure is arranged on the left side of the rotating shaft; the large-aperture screen plate is arranged at the left position of the middle part of the crushing outer frame through a bolt; the small-aperture mesh plate bolt is arranged at the right side position of the middle part of the crushing outer frame; the induced fan is arranged on the right side of the small-aperture screen plate, and the bolt is arranged on the outer side of the rotating shaft; the cloth layer screw is arranged on the right side inside the crushing outer frame; the air holes are formed in the upper part and the lower part of the right side of the crushing outer frame; the discharge hopper is arranged at the lower parts of the inner sides of the small-aperture screen plate and the cloth layer and is embedded into the inner side of the crushing outer frame; the vibration leading-out frame structure is arranged at the middle lower part of the crushing outer frame; the power switch screw is arranged on the upper part of the front side of the longitudinal fixing frame; the vibration leading-out frame structure comprises a rectangular frame, a vibration plate, a vibration motor, a fixed plate, a limiting plate, a buffer spring, a leading-out hole and a protective pad, wherein the rectangular frame is embedded in the middle lower part of the crushing outer frame; the right end of the vibrating plate is axially connected to the right upper side of the inner wall of the rectangular frame; the vibration motor screw is arranged on the left side of the lower part of the vibration plate; the two limiting plates are respectively welded on the left upper side of the inner wall of the rectangular frame and the left side of the upper end of the rectangular frame; the buffer springs are arranged in two numbers, and the buffer springs are respectively installed on the inner sides of the limiting plates through screws.

Preferably, the rotary storage rack structure comprises a transverse plate, a ball bearing, a rotary rod, a rotary disk, a storage tank, a storage bucket and a supporting wheel, wherein the transverse plate is mounted at the lower part of the inner side of the longitudinal fixing rack through a bolt; the outer ring of the ball bearing is embedded in the right side position of the transverse plate; the rotating rod is inserted in the inner ring of the ball bearing; the rotating disc is welded on the upper part of the rotating rod; the storage tanks are arranged at the four corners of the upper part of the rotating disc; the storage hoppers are respectively placed on the inner sides of the storage tanks.

Preferably, the buffering feeding frame structure comprises a feeding hopper, a leading-in pipe, a speed reducing motor, a longitudinal rod, a rotating pipe and a spiral conveying blade, wherein the feeding hopper is inserted at the left side of the upper part of the leading-in pipe; the lead-in pipe is inserted at the upper part of the left side of the crushing outer frame; the speed reducing motor is arranged at the middle position of the left side of the lead-in pipe through a bolt; the rotating pipe is arranged on the inner side of the guide-in pipe, and the left side of the rotating pipe is connected with an output shaft key of the speed reducing motor.

Preferably, the auxiliary crushing frame structure comprises a fixed pipe, a turbine rotor, an inner side connecting plate, a steel bar rope, an outer side connecting plate and crushing teeth, wherein the fixed pipe is mounted on the left side of the outer part of the rotating shaft through a bolt; the turbine rotor is welded on the left side of the outer part of the fixed pipe; the inner connecting plate is mounted on the right side of the outer part of the fixed pipe through a bolt; the reinforcing steel bar ropes are welded on the left side and the right side of one end of the inner connecting plate, which is far away from the fixed pipe; the outer side connecting plate is welded at one end, far away from the inner side connecting plate, of the reinforcing steel bar rope.

Preferably, the plurality of outlet holes are provided, and the outlet holes are respectively formed at the middle positions of the vibration plate.

Preferably, the storage hopper is arranged at the lower parts of the discharge hopper and the guide-out hopper and is placed at the inner side of the storage tank.

Preferably, the crushing teeth are provided in plurality, and the crushing teeth are welded to the upper part and the lower part of the outer connecting plate respectively.

Preferably, the spiral delivery blade is disposed inside the introduction pipe while being welded to the outside of the rotary pipe.

Preferably, the protection pad be provided with a plurality ofly, protection pad one end glue joint on the right side of rectangle frame, the upper portion right side of other end vibration board, protection pad one end glue joint on the right side of limiting plate, the other end glue joint is in the left side of vibration board.

Preferably, the guiding bucket screw is arranged at the lower part of the rectangular frame.

Preferably, four supporting wheels are arranged, and the supporting wheels are respectively connected to four corners of the middle lower part of the rotating disc in a shaft mode.

Preferably, the fixing plate is welded at the middle position of the left side of the vibration plate and is inserted into the inner side of the buffer spring.

Preferably, the crushing blade is arranged on the left side of the small-aperture screen plate, and the bolt is arranged on the outer side of the rotating shaft.

Preferably, the longitudinal rod screw is installed at the middle position of the right side of the introducing pipe, and the middle position is coupled with the rotating pipe in a shaft mode.

Preferably, the grinding racks are respectively screwed on the periphery of the inner wall of the crushing outer frame.

Preferably, driving motor adopt Y2-1 motor, gear motor adopt the motor that the model is 68KTY, vibrating motor adopt the motor that the model is MVE60/3, driving motor, gear motor and vibrating motor respectively with switch electric connection.

Compared with the prior art, the invention has the beneficial effects that:

1. in the invention, a plurality of the guide-out holes are arranged, the guide-out holes are respectively arranged at the middle position of the vibrating plate, the power switch is turned on to supply power to the vibrating motor, and the vibrating motor drives the fixing plate at the left side of the vibrating plate to move up and down from the buffer spring, so that the qualified material passing through the middle position of the crushing outer frame falls down, and the function of discharging the finished material in advance is realized.

2. According to the invention, the storage hopper is arranged at the lower parts of the discharge hopper and the derivation hopper and is simultaneously placed at the inner side of the storage tank, finished products can be conveniently stored when the finished products fall out along the discharge hopper or the derivation hopper, the rotating disc is broken when the storage hopper at one side is full, the rotating rod rotates in the ball bearing, and the other storage hopper is placed at the lower parts of the discharge hopper and the derivation hopper, so that the storage hopper can be quickly replaced.

3. According to the invention, the crushing teeth are respectively welded on the upper part and the lower part of the outer connecting plate, so that materials at the bottom of the crushing outer frame can be collided when in use, and the materials can be crushed better.

4. According to the invention, the spiral conveying blade is arranged on the inner side of the inlet pipe and is welded on the outer side of the rotating pipe, so that a power switch is turned on when the spiral conveying blade is used, the spiral conveying blade is driven to rotate through the rotating pipe by using the speed reduction motor, and the raw materials introduced from the feeding hopper are uniformly conveyed towards the right side, so that the influence of excessive raw materials poured at one time on the crushing effect of the raw materials is avoided.

5. According to the invention, a plurality of protection pads are arranged, one end of each protection pad is connected to the upper right of the rectangular frame in an adhesive mode, the right side of the upper part of the vibrating plate at the other end of each protection pad is connected to the right side of the limiting plate in an adhesive mode, the other end of each protection pad is connected to the left side of the vibrating plate in an adhesive mode, and therefore particle materials can be prevented from falling downwards from gaps between the vibrating plate and the left side and the right side of the rectangular frame when the protection pad is used.

6. In the invention, the screw of the guiding hopper is arranged at the lower part of the rectangular frame, so that the finished material guided downwards from the inside of the rectangular frame can be conveniently conveyed to the right side when in use, and the discharging position of the rectangular frame can be conveniently adjusted.

7. In the invention, four supporting wheels are arranged and are respectively connected at the four corners of the middle lower part of the rotating disc in a shaft mode, so that the pressure of finished products in the storage hopper can be received when the rotary disc type rotary disc.

8. In the invention, the fixing plate is welded at the middle position of the left side of the vibrating plate and is inserted into the inner side of the buffer spring, so that the vibrating plate is convenient to buffer in use, and the stability in vibrating and discharging can be improved.

9. In the invention, the crushing blade is arranged on the left side of the small-aperture screen plate, and the bolt is arranged on the outer side of the rotating shaft, so that the material which is completely crushed can be conveniently crushed for the second time in use.

10. In the invention, the longitudinal rod screw is arranged at the middle position of the right side of the lead-in pipe, and the middle position is in shaft connection with the rotating pipe, so that the right side of the rotating pipe can be conveniently positioned when the rotary pipe is used, and the friction between the spiral conveying blade and the inner wall of the lead-in pipe is avoided.

11. In the invention, the grinding racks are respectively screwed on the periphery of the inner wall of the crushing outer frame, which is beneficial to expanding the grinding range when in use.

Drawings

Fig. 1 is a schematic structural view of the present invention.

FIG. 2 is a schematic structural diagram of a buffer feeding rack structure according to the present invention.

Fig. 3 is a schematic structural view of the rotary storage rack structure of the present invention.

Fig. 4 is a structural schematic view of an auxiliary crushing frame structure of the present invention.

Fig. 5 is a schematic structural view of the vibration leading-out frame structure of the present invention.

In the figure:

1. crushing the outer frame; 2. a buffer feeding frame structure; 21. feeding into a hopper; 22. an introducing pipe; 23. a reduction motor; 24. a longitudinal rod; 25. rotating the tube; 26. a spiral conveying blade; 3. a longitudinal fixing frame; 4. a rotating shaft; 5. a driven wheel; 6. a driving wheel; 7. a transmission belt; 8. a drive motor; 9. rotating the storage rack structure; 91. a transverse plate; 92. a ball bearing; 93. rotating the rod; 94. rotating the disc; 95. a storage tank; 96. a storage hopper; 97. a support wheel; 10. an auxiliary crushing frame structure; 101. a fixed tube; 102. a turbine rotor; 103. an inner connecting plate; 104. a reinforcing steel rope; 105. an outer connecting plate; 106. crushing teeth; 11. a large-aperture screen plate; 12. a small-aperture screen plate; 13. crushing the blade; 14. a fan guide; 15. a cloth layer; 16. air holes are formed; 17. a discharge hopper; 18. a vibration lead-out frame structure; 181. a rectangular frame; 182. a vibrating plate; 183. a vibration motor; 184. a fixing plate; 185. a limiting plate; 186. a buffer spring; 187. a lead-out hole; 188. a protective pad; 19. a leading-out hopper; 20. and a power switch.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example (b):

as shown in figures 1 and 5

The invention provides a multifunctional turbine crusher capable of automatically discharging materials, which comprises a crushing outer frame 1, a buffering feeding frame structure 2, a longitudinal fixing frame 3, a rotating shaft 4, a driven wheel 5, a driving wheel 6, a driving belt 7, a driving motor 8, a rotary storage frame structure 9, an auxiliary crushing frame structure 10, a large-aperture screen plate 11, a small-aperture screen plate 12, a crushing blade 13, a draught fan 14, a cloth layer 15, an air vent 16, a discharging hopper 17, a vibration leading-out frame structure 18, a leading-out hopper 19 and a power switch 20, wherein the buffering feeding frame structure 2 is arranged at the upper part of the crushing outer frame 1; the longitudinal fixing frame 3 is welded at the four corners of the lower part of the crushing outer frame 1; the rotating shaft 4 transversely penetrates through the large-aperture mesh plate 11, the small-aperture mesh plate 12 and the cloth layer 15 and is connected with the middle price of the crushing outer frame 1 in a shaft mode; the driven wheel 5 is welded at the left end of the rotating shaft 4; the driving wheel 6 is connected with the left output shaft of the driving motor 8 in a key way; the transmission belt 7 is sleeved on the outer sides of the driving wheel 6 and the driven wheel 5; the driving motor 8 is arranged on the left side of the lower part of the crushing outer frame 1 through a bolt; the rotary storage rack structure 9 is arranged at the lower part of the inner side of the longitudinal fixed rack 3; the auxiliary crushing frame structure 10 is arranged on the left side of the rotating shaft 4; the large-aperture screen plate 11 is arranged at the left position of the middle part of the crushing outer frame 1 through a bolt; the small-aperture mesh plate 12 is arranged at the right side of the middle part of the crushing outer frame 1 through a bolt; the induced fan 14 is arranged at the right side of the small-aperture screen 12, and the bolt is arranged at the outer side of the rotating shaft 4; the cloth layer 15 is arranged on the right side inside the crushing outer frame 1 through screws; the air holes 16 are arranged at the upper part and the lower part of the right side of the crushing outer frame 1; the discharge hopper 17 is arranged at the lower part of the inner sides of the small-aperture mesh plate 12 and the cloth layer 15 and is embedded in the inner side of the crushing outer frame 1; the vibration leading-out frame structure 18 is arranged at the middle lower part of the crushing outer frame 1; the power switch 20 is mounted on the upper part of the front side of the longitudinal fixing frame 3 through screws; the guide hopper 19 is mounted at the lower part of the rectangular frame 181 by screws, so that finished materials guided downwards from the rectangular frame 181 can be conveniently conveyed to the right side when the guide hopper is used, the discharging position of the rectangular frame 181 is conveniently adjusted, four support wheels 97 are arranged, the support wheels 97 are respectively connected to four corners of the middle lower part of the rotating disc 94 in a shaft mode, the pressure of the finished materials in the storage hopper 96 can be received when the guide hopper is used, the rotating disc 94 is inclined towards one side, the crushing blade 13 is arranged at the left side of the small-aperture mesh plate 12, meanwhile, bolts are mounted at the outer side of the rotating shaft 4, so that completely crushed materials can be crushed for the second time when the guide hopper is used, the grinding racks are respectively mounted at the peripheral positions of the inner wall of the crushing outer frame 1 by screws, and the grinding range can be expanded when the guide hopper is used; the vibration leading-out frame structure 18 comprises a rectangular frame 181, a vibration plate 182, a vibration motor 183, a fixing plate 184, a limiting plate 185, a buffer spring 186, a leading-out hole 187 and a protective pad 188, wherein the rectangular frame 181 is embedded in the middle lower part of the crushing outer frame 1; the right end of the vibrating plate 182 is axially connected with the upper right side of the inner wall of the rectangular frame 181; the vibration motor 183 is mounted on the left side of the lower part of the vibration plate 182 by screws; the number of the limit plates 185 is two, and the limit plates 185 are welded on the left upper side of the inner wall of the rectangular frame 181 and the left side of the upper end of the rectangular frame 181 respectively; two buffer springs 186 are arranged, and the buffer springs 186 are respectively installed on the inner sides of the limit plates 185 through screws; the plurality of the leading-out holes 187 are arranged, the leading-out holes 187 are respectively arranged at the middle positions of the vibrating plates 182, the power switch 20 is turned on to supply power to the vibrating motor 183, the vibrating motor 183 drives the fixing plate 184 at the left side of the vibrating plates 182 to move up and down from the buffer springs 186, so that materials qualified by the middle positions of the crushed outer frame 1 fall down, and a function of discharging finished materials in advance is realized, the plurality of the protection pads 188 are arranged, one end of each protection pad 188 is glued on the right upper side of the rectangular frame 181, the other end of each protection pad 188 is glued on the right side of the limiting plate 185, the other end of each protection pad 188 is glued on the left side of the vibrating plates 182, when the protection pads are used, the particles can be prevented from falling down from gaps at the left and right sides of the vibrating plates 182 and the rectangular frame 181, and the fixing plates 184 are welded at the middle positions at the left sides of the vibrating plates 182, meanwhile, the vibration plate is inserted into the inner side of the buffer spring 186, so that the vibration plate 182 is conveniently buffered when in use, and the stability during vibration discharging can be improved.

In the above embodiment, as shown in fig. 2, specifically, the rotating storage rack structure 9 includes a transverse plate 91, a ball bearing 92, a rotating rod 93, a rotating disk 94, a storage tank 95, a storage bucket 96 and a supporting wheel 97, wherein the transverse plate 91 is bolted to the lower inner side of the longitudinal fixing frame 3; the outer ring of the ball bearing 92 is embedded in the right position of the transverse plate 91; the rotating rod 93 is inserted into the inner ring of the ball bearing 92; the rotating disc 94 is welded on the upper part of the rotating rod 93; the storage tanks 95 are arranged at the four corners of the upper part of the rotating disc 94; the storage hoppers 96 are respectively placed on the inner sides of the storage tanks 95; the storage hopper 96 is arranged at the lower parts of the discharge hopper 17 and the derivation hopper 19 and is simultaneously placed at the inner side of the storage tank 95, when the finished product material falls down along the discharge hopper 17 or the derivation hopper 19, the finished product material is conveniently stored, when the storage hopper 96 at one side is full, the rotating disc 94 is broken off, the rotating rod 93 rotates in the ball bearing 92, the other storage hopper 96 is placed at the lower parts of the discharge hopper 17 and the derivation hopper 19, and therefore the storage hopper 96 can be replaced quickly.

As shown in fig. 2, in the above embodiment, specifically, the buffer feeding rack structure 2 includes a feeding hopper 21, a feeding pipe 22, a speed reducing motor 23, a longitudinal rod 24, a rotating pipe 25 and a spiral conveying blade 26, wherein the feeding hopper 21 is inserted into the left side of the upper portion of the feeding pipe 22; the lead-in pipe 22 is inserted at the upper part of the left side of the crushing outer frame 1; the speed reducing motor 23 is mounted at the middle position of the left side of the inlet pipe 22 through a bolt; the rotating pipe 25 is arranged at the inner side of the leading-in pipe 22, and the left side of the rotating pipe is connected with an output shaft key of the speed reducing motor 23; the spiral conveying blade 26 is arranged on the inner side of the leading-in pipe 22 and welded on the outer side of the rotating pipe 25, when the spiral conveying blade is used, the power switch 20 is turned on, the speed reduction motor 23 is used for driving the spiral conveying blade 26 to rotate through the rotating pipe 25, so that raw materials led in from the feeding hopper 21 are conveyed to the right side uniformly, the crushing effect on the raw materials is prevented from being influenced by the fact that too many raw materials are poured in at one time, the longitudinal rod 24 is arranged at the middle position of the right side of the leading-in pipe 22 in a screwed mode, meanwhile, the middle position is in shaft connection with the rotating pipe 25, when the spiral conveying blade is used, the positioning function is conveniently achieved on the right side of the rotating pipe 25, and friction between the spiral conveying blade 26 and the inner wall of the leading-in pipe 22 is avoided.

In the above embodiment, as shown in fig. 4, specifically, the auxiliary crushing frame structure 10 includes a fixed pipe 101, a turbine rotor 102, an inner connecting plate 103, a reinforcing steel rope 104, an outer connecting plate 105 and crushing teeth 106, wherein the fixed pipe 101 is bolted to the left outside of the rotating shaft 4; the turbine rotor 102 is welded on the left side of the outer part of the fixed pipe 101; the inner connecting plate 103 is mounted on the right side of the outer part of the fixed pipe 101 through bolts; the reinforcing steel bar ropes 104 are welded on the left side and the right side of one end, far away from the fixed pipe 101, of the inner side connecting plate 103; the outer connecting plate 105 is welded at one end of the reinforcing steel bar rope 104 far away from the inner connecting plate 103; the crushing teeth 106 are respectively welded on the upper and lower parts of the outer connecting plate 105, so that the material at the bottom of the crushing outer frame 1 can be collided when in use, and the material can be crushed better.

Principle of operation

In the working process of the invention, a power switch 20 is turned on to supply power to the electric parts of the pulverizer, raw materials are poured into a feeding hopper 21, a speed reduction motor 23 is utilized to drive a spiral conveying blade 26 to rotate through a rotating pipe 25, so that the interior of a raw material box crushing outer frame 1 falling downwards from the feeding hopper 21 is conveyed, a driving wheel 6 is driven to rotate by a driving motor 8 and rotates to a driven wheel 5 through a driving belt 7, so as to drive a rotating shaft 4 to rotate from the interior of the crushing outer frame 1 and respectively drive a fixed pipe 101, a crushing blade 13 and an induced fan 14 to rotate, after the raw materials enter the crushing outer frame 1, the raw materials are in contact with a grinding rack on the inner wall of the crushing outer frame 1 under the action of a turbine rotor 102 to carry out primary crushing, meanwhile, the raw materials are further crushed by utilizing a rotating crushing tooth 106, and materials on the crushed side are under the action of the induced fan 14, the finished product materials which can pass through the guide holes 187 are guided downwards by the vibration motor 183 to drive the vibration plate 182 to vibrate up and down on the left side, the finished product materials are poured into the storage hopper 96 from the guide hopper 19 through the rectangular frame 181, the other part of the finished product materials are subjected to secondary treatment through the crushing blade 13, then the finished product materials pass through the small-aperture screen plate 12 and directly fall into the storage hopper 96 from the discharge hopper 17, when the storage hopper 96 on one side is full, the rotating disc 94 is pulled off, the rotating rod 93 rotates in the ball bearing 92, and the other storage hopper 96 is placed at the lower parts of the discharge hopper 17 and the guide hopper 19, so that the storage hopper 96 can be replaced quickly.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.