CN109174380B - Vortex type small-sized pulverizer for constructional engineering - Google Patents

Abstract

The invention belongs to the technical field of flour mills, and particularly relates to a vortex type small flour mill used in constructional engineering, which comprises a feeding structure, a recovery shell, a fixed vortex plate, a driving motor and a driving vortex plate, wherein when people use the flour mill designed by the invention, the driving motor is controlled to work, and the driving motor can enable a filtering driving plate to swing to drive the driving vortex plate to rotate relative to the fixed vortex plate in a static state; the material is extruded and ground through the relative motion of the fixed scroll plate and the driving scroll plate; the ground material powder flows into the containing shell through the filter driving plate; because the fixed scroll plate and the driving scroll plate have smaller clearance relative to the clearance between the extrusion plates of the traditional pulverizer in the relative rotation process, the extrusion effect is better; compared with the traditional pulverizer, the pulverizer has better pulverizing effect.

Description

Vortex type small-sized pulverizer for constructional engineering

Technical Field

The invention belongs to the technical field of flour mills, and particularly relates to a vortex type small flour mill used in constructional engineering.

Background

At present, with the development of the Chinese crushing and grinding equipment industry driven by the industries such as mine exploitation, cement, traffic construction, metallurgy, chemical industry, electric power, water conservancy, real estate and the like, Chinese crushing and grinding equipment enterprises get qualitative leaps in the aspects of capacity scale, economic strength, product technology, management level and the like, and are highly singed in the international market. A pulverizer converts a non-hydraulic bulk material such as clinker, gypsum, or a mixture into a hydraulic powdery material. In order to meet the high requirements of modern buildings on powdery materials, it is necessary to design a pulverizer with high pulverizing quality.

The invention designs a vortex type small-sized pulverizer for constructional engineering to solve the problems.

Disclosure of Invention

In order to solve the defects in the prior art, the invention discloses a vortex type small-sized pulverizer for constructional engineering, which is realized by adopting the following technical scheme.

A small-size pulverizer of vortex formula that building engineering used which characterized in that: it comprises a feeding structure, a sealed outer ring, a recycling shell, a fixed block, a triggering adjusting mechanism, an adjusting baffle, a shunting block, a telescopic scraping rod, a fixed vortex plate, a driving motor, a driving vortex plate, a containing shell, a filtering driving plate, a first annular guide rail block, a second annular guide rail block, a mounting cavity, a guide groove, a feeding hole, a cylindrical groove, a conical feeding groove, a fixed plate, an adjusting motor, a connecting rod, a first spring, a driving guide rail block, a guide block, a second spring, a connecting ring, a sealed inner ring, a first guide block, a second guide block, a connecting plate, a first guide groove, a driving block, a driving shaft, a hydraulic pipeline, a square guide groove, a third spring, a driving rotating shaft, a square guide block, a hydraulic pipe, a mounting groove, a motor groove, a circular groove, a second guide groove and a driving ring, wherein the fixed block is cylindrical, the upper end of the fixed block is provided with a circular groove, the lower side of the circular groove, one end of the placing groove is communicated with the outside; the driving motor is arranged in the motor groove; the lower end of the driving shaft is connected with an output shaft of the driving motor; a square guide groove is formed in the upper side of the driving block, a hydraulic pipeline is formed in one side face of the square guide groove and penetrates out of the upper side face of the driving block; the driving block is arranged at the upper end of the driving shaft; the axis of the hydraulic pipeline opened on the driving block, which penetrates through one end of the upper side of the driving block, is collinear with the axis of the driving shaft; the square guide block is arranged on the driving block through the matching with the square guide groove formed on the driving block; a hydraulic pipe is arranged between the square guide block and the square guide groove; one end of the hydraulic pipe, which is far away from the square guide block, is provided with a hydraulic outlet which is communicated with a hydraulic pipeline arranged on the driving block; the driving rotating shaft is arranged on the upper side of the square guide block; the recovery shell is in a barrel shape; the recycling shell is arranged in a placing groove formed in the fixed block; the inner side of the recovery shell is provided with a containing shell; the containing shell is in a barrel shape; the receiving shell is positioned in the center of the recovery shell; the filter driving plate is a circular plate, and a plurality of filter holes are formed in the filter driving plate; the outer circular surface of the filter driving plate is provided with a driving ring; two second guide blocks are uniformly arranged on the outer circular surface of the driving ring in the circumferential direction; a connecting plate is arranged on the outer circular surface of the driving ring, and a circular shaft hole is formed in the connecting plate; the connecting plate and the two second guide blocks form an included angle of 90 degrees; the filter driving plate is arranged on the driving block through the matching of a circular shaft hole on the connecting plate and the driving rotating shaft; the filter driving plate is matched with the accommodating shell; two first through guide grooves are uniformly formed in the inner circular surface of the first annular guide rail block in the circumferential direction; two first guide blocks are uniformly arranged on the outer circular surface of the first annular guide rail block in the circumferential direction; the first annular guide rail block is arranged on the outer side of the filter driving plate through the matching of the two first guide grooves and the two second guide blocks; two through second guide grooves are uniformly formed in the inner circular surface of the second annular guide rail block in the circumferential direction; the second annular guide rail block is arranged on the outer side of the first annular guide rail block through the matching of the two second guide grooves and the two first guide blocks; the connecting line of the two first guide blocks is vertical to the connecting line of the two second guide blocks; the second annular guide rail block is fixedly arranged on the upper side of the fixed block; the driving vortex plate is arranged on the upper side of the filtering driving plate, and the vortex center of the driving vortex plate is positioned on the extension line of the axis of the filtering driving plate; the sealing outer ring is arranged on the upper side of the second annular guide rail block; the sealing inner ring is arranged on the inner side of the sealing outer ring through a connecting ring, the fixed scroll plate is arranged on the sealing inner ring, and the fixed scroll plate and the driving scroll plate are in up-and-down staggered fit; the lower part of the fixed scroll plate is completely superposed with the upper part of the driving scroll plate after the fixed scroll plate rotates 180 degrees around the axis of the filtering driving plate; the feeding structure is cylindrical; a conical feeding groove is formed in the upper end face of the feeding structure; a cylindrical groove is formed in the lower end face of the feeding structure; a feed inlet is arranged between the cylindrical groove and the conical feed groove; the inner side of the feeding structure is provided with an installation cavity; one side of the mounting cavity is provided with a guide groove communicated with the cylindrical groove; the feeding structure is arranged on the upper side of the sealing outer ring; the trigger adjusting mechanism is arranged in an installation cavity formed in the feeding structure; the trigger adjusting mechanism is connected with a hydraulic pipeline on the driving block through a pipeline; one end of the connecting rod is arranged on the trigger adjusting mechanism; the other end of the connecting rod passes through a guide groove formed in the feeding structure and is positioned in a cylindrical groove formed in the feeding structure, and the adjusting baffle is arranged at one end, positioned in the cylindrical groove, of the connecting rod; the adjusting baffle is matched with a feeding hole formed in the feeding structure; the adjusting motor is arranged in a cylindrical groove formed in the feeding structure through three fixing plates which are uniformly distributed in the circumferential direction; a square guide rail groove is formed in the driving guide rail block; the driving guide rail block is arranged on the lower side of the output shaft of the adjusting motor; the telescopic scraping rod consists of a telescopic inner rod and a telescopic outer sleeve, wherein one end of the telescopic inner rod is arranged in the telescopic outer sleeve; the other end of the telescopic inner rod is provided with a conical surface; a second spring is arranged between one end of the telescopic inner rod positioned at the inner side of the telescopic outer sleeve and the bottom side surface of the telescopic outer sleeve; one end of the telescopic outer sleeve, which is far away from the telescopic inner rod, is provided with a guide block; the telescopic scraping rod is arranged on the lower side of the driving guide rail block through the matching of the guide block and a square guide rail groove formed on the driving guide rail block; the telescopic scraping rod is matched with the driving vortex plate and the fixed vortex plate; two first springs are symmetrically arranged between the guide block and a square guide rail groove formed in the driving guide rail block; the shunting block is in an inverted cone shape; the shunting block is arranged on the upper side of the adjusting motor.

As a further improvement of the present technology, the first spring is a compression spring; the second spring is a compression spring; the third spring is a compression spring.

As a further improvement of the technology, the square guide block is arranged in a square guide groove formed in the driving block through a linear bearing.

As a further improvement of the technology, the driving rotating shaft is connected with the connecting plate through a bearing.

As a further improvement of the technology, the recovery shell is provided with a pulling handle.

When the driving motor works, the driving motor can drive the driving shaft to rotate through the output shaft; the driving shaft rotates to drive the driving block arranged on the driving shaft to rotate around the axis of the driving shaft; the driving block rotates to drive the square guide block arranged on the driving block to rotate around the axis of the driving shaft; the square guide block rotates around the axis of the driving shaft to drive the driving rotating shaft to rotate around the axis of the driving shaft; the driving rotating shaft rotates to drive the connecting plate arranged on the driving rotating shaft to rotate around the axis of the driving shaft; the rotation of the connecting plate can lead the driving ring to swing; the driving ring swings to drive the filtering driving plate arranged on the inner side to swing; the filter driving plate swings to drive the driving vortex plate arranged on the filter driving plate to rotate relative to the fixed vortex plate which is arranged on the sealing inner ring and is in a static state; the size of the gap between the arc-shaped side surfaces of the driving vortex plate and the fixed vortex plate is continuously changed; the filter driving board designed by the invention has a filtering function; the second guide block arranged on the driving ring can slide in the first guide groove formed on the first annular guide rail block; the first guide block arranged on the first annular guide rail block can slide in a second guide groove formed on the second annular guide rail block; through the matching of the first annular guide rail block and the second annular guide rail block, the filter driving plate can realize universal swing in a plane where the first annular guide rail block and the second annular guide rail block are located.

In the invention, when the driving rotating shaft rotates, if the driving rotating shaft is subjected to extrusion force which enables the driving rotating shaft to move towards one side provided with the hydraulic pipe, the driving rotating shaft can drive the square guide block to move towards one side provided with the hydraulic pipe; the square guide block moves towards one side provided with the hydraulic pipe and can extrude the inner rod of the hydraulic pipe, so that the inner rod extrudes liquid in the hydraulic rod; the liquid in the hydraulic rod is extruded and flows into the trigger adjusting mechanism through a hydraulic pipeline opened on the driving block through a hydraulic outlet on the hydraulic rod; the trigger adjusting mechanism drives the connecting rod to move by sensing the amount of liquid flowing into the trigger adjusting mechanism; so that the connecting rod drives the adjusting baffle to move towards one side of the feeding hole formed in the feeding structure.

The shunting block has the function of guiding and dispersing the added materials; the material entering through the feeding structure is scattered around the shunting blocks under the action of the shunting blocks; the material is prevented from being concentrated at one position because of not being dispersed, and the work of the fixed scroll plate and the driving scroll plate is prevented from being influenced; so that the grinding efficiency is reduced. The containing shell is used for collecting and processing ground materials; in the invention, because the fixed scroll plate is in a vortex shape and the sealing inner ring for installing the fixed scroll plate is in a cylindrical shape, a gap is formed at the joint of the fixed plate and the sealing inner ring; the added unground materials can fall to the lower side of the fixed scroll plate through the gap without being ground, and in order to prevent the grinding effect from being influenced, the recovery shell is designed, a certain gap is formed between the recovery shell and the containing shell, and the gap is used for recovering the fallen unground materials; and then processed again.

When the adjusting motor works, the adjusting motor drives the driving guide rail block to rotate through the output shaft; the driving guide rail block rotates to drive the telescopic scraping rod arranged on the driving guide rail block to rotate; the telescopic scraping rod can be telescopic and can slide relative to the driving guide rail block; the telescopic scraping rod can adapt to the relative rotation of the fixed scroll plate and the driving scroll plate by controlling the adjusting motor; the telescopic inner rod of the telescopic scraping rod can move along with the gap between the fixed scroll plate and the driving scroll plate; the telescopic inner rod can clean the stuck materials between the fixed scroll plate and the driving scroll plate in the moving process; the material is prevented from being stuck between the fixed scroll plate and the driving scroll plate to reduce the grinding effect; when the telescopic inner rod moves to the innermost side along with the gap between the fixed scroll plate and the driving scroll plate, the fixed scroll plate and the driving scroll plate can extrude the telescopic inner rod; the telescopic inner rod moves upwards and finally moves to the upper side of the fixed scroll plate completely; the first spring can be compressed when the telescopic inner rod moves along the gap between the fixed scroll plate and the driving scroll plate; when the telescopic inner rod moves upwards to the upper side of the fixed scroll plate, the telescopic scraping rod can be restored to the outermost side of the fixed scroll plate and the driving scroll plate under the action of the first spring; when the telescopic scraping rod is in a recovery process, the lowest end of a telescopic inner rod of the telescopic scraping rod is in contact with the fixed scroll plate and the part, located between the starting end and the ending end, of the driving scroll plate in a moving process, the fixed scroll plate and the driving scroll plate can extrude the telescopic inner rod, and the telescopic inner rod is enabled to move upwards again under the action of the upper conical surface of the telescopic inner rod; prevent flexible scraping bar under the effect of second spring, flexible scraping bar has not just been stretched when recovering fixed vortex board and drive vortex board's the outside yet, and the card is between fixed vortex board and drive vortex board.

Compared with the traditional pulverizer technology, the pulverizer designed by the invention performs extrusion grinding on the materials to be ground through the relative rotation of the fixed scroll plate and the driving scroll plate; because the fixed scroll plate and the driving scroll plate have smaller clearance relative to the clearance between the extrusion plates of the traditional pulverizer in the relative rotation process, the extrusion effect is better; compared with the traditional pulverizer, the pulverizer has better pulverizing effect.

Drawings

Fig. 1 is an external view of an entire part.

Fig. 2 is a schematic view of the overall component distribution.

Fig. 3 is a schematic plan view of the internal structural distribution of the integral component.

Fig. 4 is a schematic view of the internal structural distribution of the integral component.

Fig. 5 is a schematic view of the feeding structure.

FIG. 6 is a schematic view of a cylindrical groove distribution.

Fig. 7 is a schematic view of the trigger adjustment mechanism installation.

Fig. 8 is a schematic view of the adjustment flap installation.

Fig. 9 is a schematic view of the drive rail block installation.

Fig. 10 is a schematic view of the structure of the telescopic wiper blade.

Fig. 11 is a schematic view of the telescopic wiper blade in cooperation with a driving scroll plate and a fixed scroll plate.

FIG. 12 is a schematic view of the seal inner ring installation.

FIG. 13 is a schematic view of the fixed scroll plate mounting.

Fig. 14 is a filter drive plate installation schematic.

FIG. 15 is a schematic view of a first circular guide block and a first circular guide block configuration.

Fig. 16 is a schematic view of the connection plate mounting.

Fig. 17 is a drive block mounting schematic.

Fig. 18 is a schematic view of hydraulic tube installation.

Fig. 19 is a schematic view of a fixed block structure.

Fig. 20 is a schematic view of the mounting block.

FIG. 21 is a schematic view of the operation of the fixed scroll plate and the drive scroll plate.

Fig. 22 is a schematic view showing the operation of the telescopic wiper blade.

Number designation in the figures: 1. a feeding structure; 2. sealing the outer ring; 3. recovering the shell; 4. a fixed block; 5. triggering an adjusting mechanism; 6. adjusting the baffle; 7. a shunting block; 8. a telescopic scraping rod; 9. a fixed scroll plate; 10. a drive motor; 11. a drive scroll plate; 12. a housing case; 13. a filter drive plate; 14. a first annular guide rail block; 15. a second annular rail block; 16. a mounting cavity; 17. a guide groove; 18. a feed inlet; 19. a cylindrical groove; 20. a conical feed chute; 21. a fixing plate; 22. adjusting the motor; 23. a connecting rod; 24. a first spring; 25. driving the guide rail block; 26. a telescopic inner rod; 27. a telescopic outer sleeve; 28. a guide block; 29. a second spring; 30. connecting the circular rings; 31. sealing the inner ring; 32. a first guide block; 33. a second guide block; 34. a connecting plate; 35. a first guide groove; 36. a drive block; 37. a drive shaft; 38. a hydraulic conduit; 39. a square guide groove; 40. a third spring; 41. driving the rotating shaft; 42. a square guide block; 43. a hydraulic tube; 44. a placing groove; 45. a motor slot; 46. a circular groove; 47. a second guide groove; 48. driving the ring.

Detailed Description

As shown in fig. 1 and 2, the device comprises a feeding structure 1, a sealing outer ring 2, a recovery shell 3, a fixed block 4, a trigger adjusting mechanism 5, an adjusting baffle 6, a flow dividing block 7, a telescopic scraping rod 8, a fixed scroll plate 9, a driving motor 10, a driving scroll plate 11, a receiving shell 12, a filtering driving plate 13, a first annular guide rail block 14, a second annular guide rail block 15, a mounting cavity 16, a guide groove 17, a feeding hole 18, a cylindrical groove 19, a conical feeding groove 20, a fixed plate 21, an adjusting motor 22, a connecting rod 23, a first spring 24, a driving guide rail block 25, a guide block 28, a second spring 29, a connecting ring 30, a sealing inner ring 31, a first guide block 32, a second guide block 33, a connecting plate 34, a first guide groove 35, a driving block 36, a driving shaft 37, a hydraulic pipeline 38, a square guide groove 39, a third spring 40, a driving rotating shaft 41, a square guide block 42, a hydraulic pipe 43, a mounting groove 44, a, A motor groove 45, a circular groove 46, a second guide groove 47 and a driving ring 48, wherein as shown in fig. 19, the fixing block 4 is cylindrical, the circular groove 46 is formed at the upper end of the fixing block 4, the motor groove 45 and the placement groove 44 are formed at the lower side of the circular groove 46, and one end of the placement groove 44 is communicated with the outside; as shown in fig. 3 and 4, the driving motor 10 is installed in the motor slot 45; the lower end of the driving shaft 37 is connected with an output shaft of the driving motor 10; as shown in fig. 18, the upper side of the driving block 36 is provided with a square guide groove 39, one side surface of the square guide groove 39 is provided with a hydraulic pipeline 38, and the hydraulic pipeline 38 penetrates through the upper side surface of the driving block 36; as shown in fig. 17, a drive block 36 is mounted on the upper end of a drive shaft 37; the axis of the hydraulic pipeline opened on the driving block 36 and penetrating out of one end of the upper side of the driving block 36 is collinear with the axis of the driving shaft 37; as shown in fig. 18, the square guide block 28 is mounted on the driving block 36 by engagement with a square guide groove 39 formed in the driving block 36; a hydraulic pipe 43 is arranged between the square guide block 42 and the square guide groove 39; one end of the hydraulic pipe 43, which is far away from the square guide block 42, is provided with a hydraulic outlet, and the hydraulic outlet is communicated with the hydraulic pipeline 38 opened on the driving block 36; the driving rotating shaft 41 is installed on the upper side of the square guide block 42; as shown in fig. 20, the recovery casing 3 is cylindrical; as shown in fig. 4, the recovery casing 3 is installed in a mounting groove 44 formed on the fixing block 4; the inner side of the recovery shell 3 is provided with a containing shell 12; the containing shell 12 is cylindrical; the housing case 12 is located at the center of the recovery case 3; as shown in fig. 16, the filter driving plate 13 is a circular plate, and a plurality of filter holes are formed in the filter driving plate 13; a driving ring 48 is arranged on the outer circular surface of the filter driving plate 13; two second guide blocks 33 are circumferentially and uniformly mounted on the outer circumferential surface of the drive ring 48; the outer circular surface of the driving ring 48 is provided with a connecting plate 34, and the connecting plate 34 is provided with a circular shaft hole; the connecting plate 34 and the two second guide blocks 33 form an included angle of 90 degrees; as shown in fig. 17, the filter driving plate 13 is mounted on the driving block 36 through the circular shaft hole of the connecting plate 34 and the matching of the driving rotating shaft 41; the filter driving plate 13 is matched with the accommodating shell 12; as shown in fig. 15, two first guide grooves 35 are circumferentially and uniformly formed on the inner circumferential surface of the first circular rail block 14; as shown in fig. 14, two first guide blocks 32 are circumferentially and uniformly mounted on the outer circumferential surface of the first annular rail block 14; the first annular guide rail block 14 is arranged on the outer side of the filter driving plate 13 through the matching of the two first guide grooves 35 and the two second guide blocks 33; as shown in fig. 15, two second guide grooves 47 are circumferentially and uniformly formed on the inner circumferential surface of the second annular rail block 15; as shown in fig. 14, the second annular rail block 15 is mounted on the outer side of the first annular rail block 14 by the cooperation of the two second guide grooves 47 with the two first guide blocks 32; the connecting line of the two first guide blocks 32 is perpendicular to the connecting line of the two second guide blocks 33; as shown in fig. 3, the second annular rail block 15 is fixedly installed on the upper side of the fixed block 4; as shown in fig. 14, the driving scroll plate 11 is installed on the upper side of the filter driving plate 13, and the center of the scroll of the driving scroll plate 11 is on the extension line of the axis of the filter driving plate 13; as shown in fig. 4, the seal outer ring 2 is mounted on the upper side of the second annular rail block 15; as shown in fig. 12, the seal inner ring 31 is installed inside the seal outer ring 2 through the connection ring 30, as shown in fig. 13, the fixed scroll plate 9 is installed on the seal inner ring 31, and the fixed scroll plate 9 and the driving scroll plate 11 are vertically cross-fitted; the lower part of the fixed scroll plate is completely overlapped with the upper part of the driving scroll plate 11 after rotating 180 degrees around the axis of the filter driving plate 13; as shown in fig. 5, the feeding structure 1 is cylindrical; a conical feeding groove 20 is formed in the upper end face of the feeding structure 1; a cylindrical groove 19 is formed in the lower end face of the feeding structure 1; a feed inlet 18 is arranged between the cylindrical groove 19 and the conical feed groove 20; as shown in fig. 6, the inner side of the feeding structure 1 is provided with a mounting cavity 16; one side of the mounting cavity 16 is provided with a guide groove 17 communicated with the cylindrical groove 19; the feeding structure 1 is arranged on the upper side of the sealing outer ring 2; as shown in fig. 7, the trigger adjusting mechanism 5 is installed in an installation cavity 16 formed on the feeding structure 1; the trigger adjusting mechanism 5 is connected with a hydraulic pipeline 38 on the driving block 36 through a pipeline; one end of the connecting rod 23 is arranged on the trigger adjusting mechanism; the other end of the connecting rod 23 passes through the guide groove 17 formed in the feeding structure 1 and is positioned in the cylindrical groove 19 formed in the feeding structure 1, and as shown in fig. 8, the adjusting baffle 6 is arranged at one end of the connecting rod 23 positioned in the cylindrical groove 19; the adjusting baffle 6 is matched with a feeding hole 18 formed in the feeding structure 1; as shown in fig. 7, the adjusting motor 22 is mounted in the cylindrical groove 19 formed on the feeding structure 1 through three fixing plates 21 uniformly distributed in the circumferential direction; as shown in fig. 9, the driving rail block 25 is provided with a square rail groove; as shown in fig. 11, a driving rail block 25 is installed at a lower side of an output shaft of the adjusting motor 22; as shown in fig. 10, the telescopic scraping bar 8 is composed of a telescopic inner bar 26 and a telescopic outer sleeve 27, wherein one end of the telescopic inner bar 26 is installed in the telescopic outer sleeve 27; the other end of the telescopic inner rod 26 is provided with a conical surface; a second spring 29 is arranged between one end of the telescopic inner rod 26 positioned at the inner side of the telescopic outer sleeve 27 and the bottom side surface of the telescopic outer sleeve 27; a guide block 28 is arranged at one end of the telescopic outer sleeve 27 far away from the telescopic inner rod 26; the telescopic scraping rod 8 is arranged on the lower side of the driving guide rail block 25 through the matching of the guide block 28 and a square guide rail groove formed on the driving guide rail block 25; the telescopic scraping rod 8 is matched with the driving scroll plate 11 and the fixed scroll plate 9; two first springs 24 are symmetrically arranged between the guide block 28 and a square guide rail groove formed on the driving guide rail block 25; the shunting block 7 is in an inverted cone shape; the diverter block 7 is mounted on the upper side of the adjustment motor 22.

The first spring 24 is a compression spring; the second spring 29 is a compression spring; the third spring 40 is a compression spring.

The square guide block 42 is mounted by linear bearings in the square guide groove 39 formed in the drive block 36.

The driving rotating shaft 41 is connected with the connecting plate 34 through a bearing.

The recovery case 3 has a pulling handle.

In summary, the following steps:

the beneficial effects of the design of the invention are as follows: the pulverizer performs extrusion grinding on materials to be ground through the relative rotation of the fixed scroll plate 9 and the driving scroll plate 11; because the fixed scroll plate 9 and the driving scroll plate 11 have smaller clearance relative to the clearance between the extrusion plates of the traditional pulverizer in the relative rotation process, and the extrusion is carried out in the whole spiral space, the extrusion effect is better; compared with the traditional pulverizer, the pulverizer has better pulverizing effect.

When the driving motor 10 works, the driving motor 10 drives the driving shaft 37 to rotate through the output shaft; the driving shaft 37 rotates to drive the driving block 36 mounted on the driving shaft 37 to rotate around the axis of the driving shaft 37; the driving block 36 rotates to drive the square guide block 42 mounted on the driving block to rotate around the axis of the driving shaft 37; the square guide block 42 rotates around the axis of the driving shaft 37 to drive the driving rotating shaft 41 to rotate around the axis of the driving shaft 37; the driving rotating shaft 41 rotates to drive the connecting plate 34 mounted thereon to rotate around the axis of the driving shaft 37; rotation of the link plate 34 causes the drive ring 48 to oscillate; the driving ring 48 swings to drive the filter driving plate 13 arranged at the inner side to swing; as shown in fig. 21a and 21b, the filter driving plate 13 swings to rotate the driving scroll plate 11 mounted thereon relative to the stationary scroll plate 9 mounted on the seal inner ring 31 in a stationary state; as shown in fig. 21b and 21c, the size of the gap between the arc-shaped side surfaces of the driving scroll plate 11 and the fixed scroll plate 9 is changed; the filter driving plate 13 designed by the invention has a filtering function; the second guide block 33 mounted on the drive ring 48 in the present invention can slide in the first guide groove 35 opened on the first annular rail block 14; the first guide block 32 mounted on the first annular rail block 14 is slidable in a second guide groove 47 formed in the second annular rail block 15; the first annular guide rail block 14 and the second annular guide rail block 15 are matched to enable the filter driving plate 13 to realize universal swing in a plane where the first annular guide rail block 14 and the second annular guide rail block 15 are located.

In the invention, when the driving rotating shaft 41 rotates, if the driving rotating shaft 41 is subjected to an extrusion force which causes the driving rotating shaft 41 to move towards the side provided with the hydraulic pipe 43, the driving rotating shaft 41 drives the square guide block 42 to move towards the side provided with the hydraulic pipe 43, generally, the particles of an extruded object are large, and the eccentric movement of the scroll plate 11 is influenced by a reaction force generated by incapable of extruding and crushing at one time; the square guide block 42 moves towards the side where the hydraulic pipe 43 is installed to press the inner rod of the hydraulic pipe 43 so that the inner rod presses the liquid in the hydraulic rod; the liquid in the hydraulic rod is extruded and flows into the trigger adjusting mechanism 5 through a hydraulic outlet on the hydraulic rod and a hydraulic pipeline 38 opened on the driving block 36; the trigger adjusting mechanism 5 drives the connecting rod 23 to move by sensing the amount of liquid flowing into the trigger adjusting mechanism; so that the connecting rod 23 drives the adjusting baffle 6 to move towards one side of the feeding hole 18 formed in the feeding structure 1, the feeding amount is reduced, and the particles which are difficult to crush are ensured to have sufficient time and space for crushing.

The shunting block 7 has the function of guiding and dispersing the added materials; so that the material entering through the feeding structure 1 is scattered around the shunting blocks 7 under the action of the shunting blocks 7; the material is prevented from being concentrated at one position without being dispersed, and the work of the fixed scroll plate 9 and the driving scroll plate 11 is prevented from being influenced; so that the grinding efficiency is reduced. The containing shell 12 is used for collecting and processing ground materials; in the invention, because the fixed scroll plate 9 is in a spiral shape and the sealing inner ring 31 for installing the fixed scroll plate 9 is in a cylindrical shape, a gap is formed at the joint of the fixed plate 21 and the sealing inner ring 31; the material added with the unground material can fall to the lower side of the fixed scroll plate 9 through the gap without being ground, and in order to prevent the influence of the gap on the grinding effect, the recovery shell 3 is designed, a certain gap is formed between the recovery shell 3 and the containing shell 12, and the gap is used for recovering the fallen unground material; and then processed again.

When the adjusting motor 22 works, the adjusting motor 22 drives the driving guide rail block 25 to rotate through the output shaft; the driving guide rail block 25 rotates to drive the telescopic scraping rod 8 arranged on the driving guide rail block to rotate; the telescopic scraping rod 8 can be telescopic, and meanwhile, the telescopic scraping rod 8 can slide relative to the driving guide rail block 25; as shown in fig. 22a, 22b, the adjusting motor 22 is controlled so that the telescopic scraping bar 8 can accommodate the relative rotation of the fixed scroll plate 9 and the driving scroll plate 11; as shown in fig. 22b, 22c, so that the telescopic inner bar 26 of the telescopic wiper bar 8 can follow the gap between the fixed scroll plate 9 and the drive scroll plate 11; the telescopic inner rod 26 can clean and scrape the stuck materials between the fixed scroll plate 9 and the driving scroll plate 11 in the moving process; the material is prevented from being stuck between the fixed scroll plate 9 and the driving scroll plate 11 to reduce the grinding effect; when the telescopic inner rod 26 moves to the innermost side following the gap between the fixed scroll plate 9 and the driving scroll plate 11, the fixed scroll plate 9 and the driving scroll plate 11 will extrude the telescopic inner rod 26; so that the telescopic inner rod 26 moves upwards and finally moves to the upper side of the fixed scroll plate 9 completely; since the telescopic inner rod 26 is compressed in the process of following the movement of the gap between the fixed scroll plate 9 and the driving scroll plate 11; when the telescopic inner rod 26 moves upward to the upper side of the fixed scroll plate 9, the telescopic wiper bar 8 is restored to the outermost side of the fixed scroll plate 9 and the driving scroll plate 11 by the first spring 24; when the telescopic scraping rod 8 is in the recovery process, the lowest end of the telescopic inner rod 26 of the telescopic scraping rod 8 is in contact with the parts, between the initial end and the final end, of the fixed scroll plate 9 and the driving scroll plate 11 in the moving process, the fixed scroll plate 9 and the driving scroll plate 11 can extrude the telescopic inner rod 26, and the telescopic inner rod 26 can move upwards again under the action of the upper conical surface of the telescopic inner rod 26; the telescopic wiper blade 8 is prevented from being stretched by the second spring 29 and caught between the fixed scroll plate 9 and the driving scroll plate 11 when the telescopic wiper blade 8 is not restored to the outermost side of the fixed scroll plate 9 and the driving scroll plate 11.

The specific implementation mode is as follows: when people use the pulverizer designed by the invention, firstly, the driving motor 10 is controlled to work, and the driving motor 10 can drive the driving shaft 37 to rotate through the output shaft; the driving shaft 37 rotates to drive the driving block 36 to rotate around the axis of the driving shaft 37; the driving block 36 rotates to drive the square guide block 42 to rotate around the axis of the driving shaft 37; the square guide block 42 rotates around the axis of the driving shaft 37 to drive the driving rotating shaft 41 to rotate around the axis of the driving shaft 37; the driving rotating shaft 41 rotates to drive the connecting plate 34 to rotate around the axis of the driving shaft 37; rotation of the link plate 34 causes the drive ring 48 to oscillate; the driving ring 48 swings to drive the filter driving plate 13 to swing; the filter driving plate 13 swings to drive the driving scroll plate 11 to rotate relative to the fixed scroll plate 9 in a static state; the size of the gap between the arc-shaped side surfaces of the driving scroll plate 11 and the fixed scroll plate 9 is constantly changed; at the moment, the material to be ground enters between the fixed scroll plate 9 and the driving scroll plate 11 through the conical feed chute 20 and the feed inlet 18 on the feeding structure 1; the material is extruded and ground through the relative movement of the fixed scroll plate 9 and the driving scroll plate 11; the ground material powder flows into the containing shell 12 through the filter driving plate 13; and the material dropped into the gap between the recovery case 3 and the housing case 12 and not ground is recovered and processed again.

Claims (5)

1. A small-size pulverizer of vortex formula that building engineering used which characterized in that: it comprises a feeding structure, a sealed outer ring, a recycling shell, a fixed block, a triggering adjusting mechanism, an adjusting baffle, a shunting block, a telescopic scraping rod, a fixed vortex plate, a driving motor, a driving vortex plate, a containing shell, a filtering driving plate, a first annular guide rail block, a second annular guide rail block, a mounting cavity, a guide groove, a feeding hole, a cylindrical groove, a conical feeding groove, a fixed plate, an adjusting motor, a connecting rod, a first spring, a driving guide rail block, a guide block, a second spring, a connecting ring, a sealed inner ring, a first guide block, a second guide block, a connecting plate, a first guide groove, a driving block, a driving shaft, a hydraulic pipeline, a square guide groove, a third spring, a driving rotating shaft, a square guide block, a hydraulic pipe, a mounting groove, a motor groove, a circular groove, a second guide groove and a driving ring, wherein the fixed block is cylindrical, the upper end of the fixed block is provided with a circular groove, the lower side of the circular groove, one end of the placing groove is communicated with the outside; the driving motor is arranged in the motor groove; the lower end of the driving shaft is connected with an output shaft of the driving motor; a square guide groove is formed in the upper side of the driving block, a hydraulic pipeline is formed in one side face of the square guide groove and penetrates out of the upper side face of the driving block; the driving block is arranged at the upper end of the driving shaft; the axis of the hydraulic pipeline opened on the driving block, which penetrates through one end of the upper side of the driving block, is collinear with the axis of the driving shaft; the square guide block is arranged on the driving block through the matching with the square guide groove formed on the driving block; a hydraulic pipe is arranged between the square guide block and the square guide groove; one end of the hydraulic pipe, which is far away from the square guide block, is provided with a hydraulic outlet which is communicated with a hydraulic pipeline arranged on the driving block; the driving rotating shaft is arranged on the upper side of the square guide block; the recovery shell is in a barrel shape; the recycling shell is arranged in a placing groove formed in the fixed block; the inner side of the recovery shell is provided with a containing shell; the containing shell is in a barrel shape; the receiving shell is positioned in the center of the recovery shell; the filter driving plate is a circular plate, and a plurality of filter holes are formed in the filter driving plate; the outer circular surface of the filter driving plate is provided with a driving ring; two second guide blocks are uniformly arranged on the outer circular surface of the driving ring in the circumferential direction; a connecting plate is arranged on the outer circular surface of the driving ring, and a circular shaft hole is formed in the connecting plate; the connecting plate and the two second guide blocks form an included angle of 90 degrees; the filter driving plate is arranged on the driving block through the matching of a circular shaft hole on the connecting plate and the driving rotating shaft; the filter driving plate is matched with the accommodating shell; two first through guide grooves are uniformly formed in the inner circular surface of the first annular guide rail block in the circumferential direction; two first guide blocks are uniformly arranged on the outer circular surface of the first annular guide rail block in the circumferential direction; the first annular guide rail block is arranged on the outer side of the filter driving plate through the matching of the two first guide grooves and the two second guide blocks; two through second guide grooves are uniformly formed in the inner circular surface of the second annular guide rail block in the circumferential direction; the second annular guide rail block is arranged on the outer side of the first annular guide rail block through the matching of the two second guide grooves and the two first guide blocks; the connecting line of the two first guide blocks is vertical to the connecting line of the two second guide blocks; the second annular guide rail block is fixedly arranged on the upper side of the fixed block; the driving vortex plate is arranged on the upper side of the filtering driving plate, and the vortex center of the driving vortex plate is positioned on the extension line of the axis of the filtering driving plate; the sealing outer ring is arranged on the upper side of the second annular guide rail block; the sealing inner ring is arranged on the inner side of the sealing outer ring through a connecting ring, the fixed scroll plate is arranged on the sealing inner ring, and the fixed scroll plate and the driving scroll plate are in up-and-down staggered fit; the lower part of the fixed scroll plate is completely superposed with the upper part of the driving scroll plate after the fixed scroll plate rotates 180 degrees around the axis of the filtering driving plate; the feeding structure is cylindrical; a conical feeding groove is formed in the upper end face of the feeding structure; a cylindrical groove is formed in the lower end face of the feeding structure; a feed inlet is arranged between the cylindrical groove and the conical feed groove; the inner side of the feeding structure is provided with an installation cavity; one side of the mounting cavity is provided with a guide groove communicated with the cylindrical groove; the feeding structure is arranged on the upper side of the sealing outer ring; the trigger adjusting mechanism is arranged in an installation cavity formed in the feeding structure; the trigger adjusting mechanism is connected with a hydraulic pipeline on the driving block through a pipeline; one end of the connecting rod is arranged on the trigger adjusting mechanism; the other end of the connecting rod passes through a guide groove formed in the feeding structure and is positioned in a cylindrical groove formed in the feeding structure, and the adjusting baffle is arranged at one end, positioned in the cylindrical groove, of the connecting rod; the adjusting baffle is matched with a feeding hole formed in the feeding structure; the adjusting motor is arranged in a cylindrical groove formed in the feeding structure through three fixing plates which are uniformly distributed in the circumferential direction; a square guide rail groove is formed in the driving guide rail block; the driving guide rail block is arranged on the lower side of the output shaft of the adjusting motor; the telescopic scraping rod consists of a telescopic inner rod and a telescopic outer sleeve, wherein one end of the telescopic inner rod is arranged in the telescopic outer sleeve; the other end of the telescopic inner rod is provided with a conical surface; a second spring is arranged between one end of the telescopic inner rod positioned at the inner side of the telescopic outer sleeve and the bottom side surface of the telescopic outer sleeve; one end of the telescopic outer sleeve, which is far away from the telescopic inner rod, is provided with a guide block; the telescopic scraping rod is arranged on the lower side of the driving guide rail block through the matching of the guide block and a square guide rail groove formed on the driving guide rail block; the telescopic scraping rod is matched with the driving vortex plate and the fixed vortex plate; two first springs are symmetrically arranged between the guide block and a square guide rail groove formed in the driving guide rail block; the shunting block is in an inverted cone shape; the shunting block is arranged on the upper side of the adjusting motor.

2. The scroll type small size pulverizer for construction engineering use according to claim 1, wherein: the first spring is a compression spring; the second spring is a compression spring; the third spring is a compression spring.

3. The scroll type small size pulverizer for construction engineering use according to claim 1, wherein: the square guide block is arranged in a square guide groove formed in the driving block through a linear bearing.

4. The scroll type small size pulverizer for construction engineering use according to claim 1, wherein: the driving rotating shaft is connected with the connecting plate through a bearing.

5. The scroll type small size pulverizer for construction engineering use according to claim 1, wherein: the recovery shell is provided with a pulling handle.

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