阅读说明：本技术 一种用于生物质燃料颗粒预处理的装置 (Device for pretreating biomass fuel particles ) 是由 李永建 李水兰 李宇钢 于 2020-04-22 设计创作，主要内容包括：本发明属于生物质燃料破碎领域,尤其涉及一种用于生物质燃料颗粒预处理的装置,它包括辊筒、轴套、破碎模块,其中中空的辊筒旋转于破碎设备中,对称安装于辊筒两端中心处的两个轴套与破碎设备旋转配合；相对于公开号为“CN 107520019 A”的“一种生物质燃料破碎机”中因其结构特点而导致的两种刀具数量较少破碎效率较低的情况,本发明通过在辊筒外柱面均匀布置若干内部同时成对包含切刀和冲击刀的破碎模块来实现若干冲击刀在辊筒外柱面的分布均匀和若干切刀在辊筒外柱面的分布均匀,从而在一定程度上增加辊筒外柱面上单位面积的单一刀种数量,进而提高切刀或冲击刀对单一刀种对某种硬度的生物质燃料进行破碎的效率。(The invention belongs to the field of biomass fuel crushing, and particularly relates to a device for pretreating biomass fuel particles, which comprises a roller, shaft sleeves and a crushing module, wherein the hollow roller rotates in crushing equipment, and the two shaft sleeves symmetrically arranged at the centers of two ends of the roller are in rotating fit with the crushing equipment; compared with the situation that the crushing efficiency is low due to the fact that the number of two cutters is small in a biomass fuel crusher with the publication number of CN 107520019A due to the structural characteristics of the biomass fuel crusher, the crushing efficiency is low due to the fact that the crushing modules which simultaneously comprise the cutters and the impact cutters in pairs are uniformly arranged on the outer cylindrical surface of the roller, the uniform distribution of the impact cutters on the outer cylindrical surface of the roller and the uniform distribution of the impact cutters on the outer cylindrical surface of the roller are achieved, the number of single cutters in unit area on the outer cylindrical surface of the roller is increased to a certain extent, and the efficiency of crushing the biomass fuel with certain hardness by the cutters or the impact cutters on the single cutters is improved.)

1. An apparatus for the pretreatment of biomass fuel particles, characterized by: the crusher comprises a roller, shaft sleeves and crushing modules, wherein the hollow roller rotates in crushing equipment, and the two shaft sleeves symmetrically arranged at the centers of two ends of the roller are in rotating fit with the crushing equipment; crushing modules for performing soft and hard classification crushing on the biomass fuel entering the crushing equipment are arranged in a plurality of mounting grooves uniformly distributed on the outer cylindrical surface of the roller;

the crushing module comprises a base, a volute spiral spring A, a sleeve A, an impact knife, a volute spiral spring B, a sleeve B, an arc plate B and a cutter, wherein the base is fixedly arranged in a corresponding mounting groove; a shaft B which is the same with the column groove and has the same central axis is matched with the base in a rotating way, and a volute spiral spring A which resets the shaft B in a rotating way is arranged on the shaft B; the sleeve A and the two sleeves B which rotate in the column groove are coaxially arranged on the shaft B, and the two sleeves B are symmetrically distributed on two sides of the sleeve A; the sleeve A is rotationally matched with the shaft B, and the sleeve B is fixedly connected with the shaft B; the sleeve A is provided with an impact knife matched with the swing groove A on the base, the two sleeves B are symmetrically provided with two arc plates B matched with the swing groove B on the base, and the tail ends of the two arc plates B are provided with cutters; the shaft B is in transmission connection with the sleeve A through a pre-stored energy volute spring B;

a structure for limiting the rotation amplitude of the sleeve A relative to the base is arranged between the sleeve A and the base; a structure for limiting the rotation amplitude of the sleeve B relative to the base is arranged between the sleeve B and the base, and the structure for limiting the rotation amplitude of the sleeve B relative to the base forms incomplete limitation on the relative position between the sleeve B and the base;

the crushing module, the roller and the shaft sleeve are provided with structures for actively switching the impact knife and the cutter.

2. The apparatus of claim 1 for the pretreatment of biomass fuel pellets, characterized in that: a shaft A is rotatably matched on the central axis of the roller, and two ends of the shaft A are respectively rotatably matched with the two shaft sleeves; a plurality of supporting frames which are rotationally matched with the shaft A are axially arranged in the roller at intervals; two ends of a shaft B in the crushing module are respectively in rotating fit with two circular grooves on the side walls of two ends of the corresponding cylindrical groove; the inner wall of each circular groove is provided with a circular groove A; the shaft B is provided with a wire winding wheel B, and the coaxial wire winding wheel B and the volute spiral spring A are respectively positioned in the two annular grooves A; one end of the volute spiral spring A is connected with the corresponding shaft B, and the other end of the volute spiral spring A is connected with the inner wall of the corresponding annular groove A; a plurality of winding wheels A are axially and uniformly arranged on the shaft A at intervals, and each winding wheel A is in transmission connection with winding wheels B in a plurality of crushing modules which are uniformly distributed in the circumferential direction on the same plane through a plurality of thin steel wires wound on the winding wheels A in the same direction; a worm wheel is installed at one end of the shaft A, a worm meshed with the worm wheel is matched with a fixed seat installed on a corresponding shaft sleeve in a rotating mode, and a crank is installed at one end of the worm.

3. The apparatus of claim 1 for the pretreatment of biomass fuel pellets, characterized in that: the outer cylindrical surface of the sleeve A is provided with an arc plate A with a concentric axis, and the arc plate A slides in an arc groove B on the cylindrical surface of the corresponding cylindrical groove around the central axis of the shaft B.

4. The apparatus of claim 1 for the pretreatment of biomass fuel pellets, characterized in that: the inner wall of the sleeve A is provided with a ring groove B, and a volute spiral spring B nested on the shaft B is positioned in the ring groove B; one end of the volute spiral spring B is connected with the inner wall of the ring groove B, and the other end of the volute spiral spring B is connected with the shaft B; a clamping block A arranged on the inner wall of the ring groove B is matched with a clamping block B arranged on the shaft B; the spiral spring B is always in a compressed state.

5. The apparatus of claim 1 for the pretreatment of biomass fuel pellets, characterized in that: two fixture blocks C are symmetrically arranged on the outer cylindrical surfaces of two sleeves B in the crushing module, and the two fixture blocks C respectively move in two arc grooves A on the cylindrical surface of the cylindrical groove around the central axis of the shaft B; a sliding groove is formed in the arc surface of each arc groove A, and a limiting block slides in each sliding groove along the radial direction of the shaft B; a limit spring for resetting the corresponding limit block is arranged in the sliding groove; one end of the limiting block is provided with an inclined plane A and an inclined plane B which are matched with the corresponding clamping blocks C; two guide blocks are symmetrically installed on the limiting block, the two guide blocks slide in two guide grooves in the inner wall of the corresponding sliding groove respectively, the guide grooves and the guide blocks are matched to play a positioning and guiding role in sliding of the limiting block in the sliding groove, and meanwhile, the limiting spring is guaranteed to be in a compressed state.

6. The apparatus of claim 1 for the pretreatment of biomass fuel pellets, characterized in that: two partition plates which are rotatably matched with the shaft B are arranged in the column groove, and the two partition plates are respectively positioned in a gap between the sleeve A and the two sleeves B; a rubber sleeve is matched between the shaft B and the partition plate, and the rubber sleeves are respectively matched between the shaft B and the inner walls of the corresponding two circular grooves.

7. The apparatus of claim 1 for the pretreatment of biomass fuel pellets, characterized in that: the slope of the inclined plane A on the limiting block is larger than that of the inclined plane B.

Technical Field

The invention belongs to the field of biomass fuel crushing, and particularly relates to a device for pretreating biomass fuel particles.

Background

Along with economic development, a large amount of waste is generated in the social construction process, wherein a large amount of biomass combustible waste is directly discarded or incinerated, so that the environment is polluted and resources are wasted; under the guidance of the sustainable development concept, biomass fuel crushing equipment for reasonably treating, recycling and reusing the combustible biomass wastes is provided.

The traditional biomass fuel crushing equipment can only crush biomass fuel with hardness in a certain range due to single cutting or crushing cutter arranged in the traditional biomass fuel crushing equipment, so that the application range of the crusher is limited, and the universality is poor. In addition, the traditional biomass fuel crusher has poor universality, and the utilization rate of cutters in the crusher is high, so that the cutters are seriously abraded, and the service life of the cutters is greatly shortened. The published 'a biomass fuel crusher' with the publication number 'CN 107520019 a' expands the use range thereof by arranging a plurality of impact tool claws for hard biomass fuel and cutting tools for soft biomass fuel on a roller in a circumferentially staggered manner. Simultaneously, reduce the wearing and tearing of cutting knife through the swing of design cutting knife when meetting stereoplasm biomass fuel, nevertheless, to the quantity of arranging of arbitrary kind cutter reducing to some extent to two kinds of cutters to biomass fuel's crushing efficiency has been reduced.

On the basis of ensuring to solve the problems of poor universality and easy abrasion of cutters of the traditional biomass fuel crusher, in order to solve the problems of the biomass fuel crusher with the publication number of CN 107520019A, a device for pretreating biomass fuel particles is necessary.

The invention designs a device for pretreating biomass fuel particles, which solves the problems.

Disclosure of Invention

In order to solve the defects in the prior art, the invention discloses a device for pretreating biomass fuel particles, which is realized by adopting the following technical scheme.

In the description of the present invention, it should be noted that the terms "inside", "outside", "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally use, which are merely for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, or be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

An apparatus for the pretreatment of biomass fuel particles, characterized by: the crusher comprises a roller, shaft sleeves and crushing modules, wherein the hollow roller rotates in crushing equipment, and the two shaft sleeves symmetrically arranged at the centers of two ends of the roller are in rotating fit with the crushing equipment; crushing modules for performing soft and hard classification crushing on biomass fuel entering the crushing equipment are arranged in a plurality of mounting grooves uniformly distributed on the outer cylindrical surface of the roller.

The crushing module comprises a base, a volute spiral spring A, a sleeve A, an impact knife, a volute spiral spring B, a sleeve B, an arc plate B and a cutter, wherein the base is fixedly arranged in a corresponding mounting groove; a shaft B which is the same with the column groove and has the same central axis is matched with the base in a rotating way, and a volute spiral spring A which resets the shaft B in a rotating way is arranged on the shaft B; the sleeve A and the two sleeves B which rotate in the column groove are coaxially arranged on the shaft B, and the two sleeves B are symmetrically distributed on two sides of the sleeve A; the sleeve A is rotationally matched with the shaft B, and the sleeve B is fixedly connected with the shaft B; the sleeve A is provided with an impact knife matched with the swing groove A on the base, the two sleeves B are symmetrically provided with two arc plates B matched with the swing groove B on the base, and the tail ends of the two arc plates B are provided with cutters; the shaft B is in transmission connection with the sleeve A through a pre-stored energy volute spring B.

A structure for limiting the rotation amplitude of the sleeve A relative to the base is arranged between the sleeve A and the base; the sleeve B and the base are provided with a structure for limiting the rotation amplitude of the sleeve B relative to the base, and the structure for limiting the rotation amplitude of the sleeve B relative to the base forms incomplete limitation on the relative position between the sleeve B and the base.

The crushing module, the roller and the shaft sleeve are provided with structures for actively switching the impact knife and the cutter.

As a further improvement of the technology, a shaft A is rotationally matched on the central axis of the roller, and two ends of the shaft A are respectively rotationally matched with the two shaft sleeves. A plurality of support frames which are rotationally matched with the shaft A are axially arranged in the roller at intervals, and the support frames effectively support the shaft A, so that the strength of the shaft A is improved. Two ends of a shaft B in the crushing module are respectively in rotating fit with two circular grooves on the side walls of two ends of the corresponding cylindrical groove; the inner wall of each circular groove is provided with a circular groove A; the shaft B is provided with a wire winding wheel B, and the coaxial wire winding wheel B and the volute spiral spring A are respectively positioned in the two annular grooves A; one end of the volute spiral spring A is connected with the corresponding shaft B, and the other end of the volute spiral spring A is connected with the inner wall of the corresponding annular groove A; a plurality of winding wheels A are axially and uniformly arranged on the shaft A at intervals, and each winding wheel A is in transmission connection with winding wheels B in a plurality of crushing modules which are uniformly distributed in the circumferential direction on the same plane through a plurality of thin steel wires wound on the winding wheels A in the same direction; a worm wheel is installed at one end of the shaft A, a worm meshed with the worm wheel is matched with a fixed seat installed on a corresponding shaft sleeve in a rotating mode, and a crank is installed at one end of the worm. The annular groove A is used for improving the accommodating space for the winding wheel B and the volute spiral spring A. The worm and worm wheel are matched to realize the rotation of the shaft A relative to the shaft sleeve, and meanwhile, the self-locking fixing function is realized on the relative position of the shaft A relative to the shaft sleeve after the shaft A rotates.

As a further improvement of the technology, the outer cylindrical surface of the sleeve A is provided with an arc plate A with a concentric axis, and the arc plate A slides in an arc groove B on the cylindrical surface of a corresponding cylindrical groove around the central axis of the shaft B. The cooperation of arc board A and arc groove B stops the impact reaction that produces when the broken biomass fuel of impact sword when restricting the swing range of impact sword, guarantees that the impact sword keeps broken position and then effectively exerts its crushing effect to biomass fuel.

As a further improvement of the technology, the inner wall of the sleeve A is provided with a ring groove B, and a volute spiral spring B nested on the shaft B is positioned in the ring groove B; one end of the volute spiral spring B is connected with the inner wall of the ring groove B, and the other end of the volute spiral spring B is connected with the shaft B; a clamping block A arranged on the inner wall of the ring groove B is matched with a clamping block B arranged on the shaft B; the spiral spring B is always in a compressed state. The annular groove B provides accommodating space for the volute spiral spring B, the clamping block A and the clamping block B, and the occupied space of the clamping block A, the clamping block B and the volute spiral spring B on the shaft B is reduced.

As a further improvement of the technology, two fixture blocks C are symmetrically installed on the outer cylindrical surfaces of two sleeves B in the crushing module, and the two fixture blocks C respectively move in two arc grooves a on the cylindrical surface of the cylindrical groove around the central axis of the shaft B; a sliding groove is formed in the arc surface of each arc groove A, and a limiting block slides in each sliding groove along the radial direction of the shaft B; a limit spring for resetting the corresponding limit block is arranged in the sliding groove; one end of the limiting block is provided with an inclined plane A and an inclined plane B which are matched with the corresponding clamping blocks C; two guide blocks are symmetrically arranged on the limiting block and respectively slide in two guide grooves on the inner wall of the corresponding sliding groove. The cooperation of guide way and guide block plays the location guide effect to the slip performance of stopper in the spout, guarantees simultaneously that spacing spring is in compression state. The mutual action of the fixture block C and the arc groove A realizes that the cutter has a better cutting angle to soft biomass fuel by limiting the swing amplitude of the cutter, and meanwhile, the cooperation of the fixture block C and the limiting block enables the cutter to swing under the action of the biomass fuel when meeting the biomass fuel with higher hardness and enables the cutter to smoothly swing back and reset after the biomass fuel with higher hardness is broken by the impact cutter, so that the abrasion of the cutter is reduced, and the service life of the cutter is prolonged.

As a further improvement of the technology, two partition plates which are rotatably matched with the shaft B are arranged in the column groove, and the two partition plates are respectively positioned in a gap between the sleeve A and the two sleeves B; a rubber sleeve is matched between the shaft B and the partition plate, and the rubber sleeves are respectively matched between the shaft B and the inner walls of the corresponding two circular grooves. The rubber sleeve absorbs the impact conducted to the shaft B through the sleeve A or the sleeve B when the cutter, particularly the impact cutter and the hard biomass fuel interact, so that the shaft B is prevented from being broken due to repeated impact for a long time, the service life of the shaft B is prolonged, and the maintenance cost of equipment is reduced.

Compared with the traditional biomass fuel crushing equipment, the crushing module which simultaneously comprises the paired cutters and the impact cutters is uniformly arranged on the outer cylindrical surface of the roller to realize cutting, crushing and impact crushing of biomass fuels with different hardness and forms, so that the equipment is more suitable for crushing the biomass fuels with wider hardness range, and the universality is improved.

As a further improvement of the technology, the slope of the inclined plane A on the limiting block is larger than that of the inclined plane B, so that a certain cutting force is ensured when the cutter cuts the biomass fuel under the indirect action of the inclined plane A and the fixture block C, when the cutter encounters hard biomass materials which are not suitable for being cut by the cutter, the fixture block C overcomes the limitation of the inclined plane A under the interaction of the cutter and the hard biomass fuels and swings along with the sleeve B, and the sleeve B drives the cutter to swing through the arc plate B so as to avoid the impact damage of the hard biomass fuels to the cutter. The smaller slope of the inclined plane B is beneficial to the smooth resetting of the cutter under the resetting action of the volute spiral spring A by overcoming the limitation of the inclined plane B through the fixture block C.

Meanwhile, the cutter and the impact cutter in the crushing module can realize mutual conversion aiming at biomass fuels with different hardness under the passive action of the biomass fuels entering the crushing equipment or the active action of manual selection, so that the problem of serious cutter abrasion caused by single cutter use range in the traditional biomass fuel crusher is solved.

Compared with the situation that the crushing efficiency is low due to the fact that the number of two cutters is small in a biomass fuel crusher with the publication number of CN 107520019A due to the structural characteristics of the biomass fuel crusher, the crushing efficiency is low due to the fact that the crushing modules which simultaneously comprise the cutters and the impact cutters in pairs are uniformly arranged on the outer cylindrical surface of the roller, the uniform distribution of the impact cutters on the outer cylindrical surface of the roller and the uniform distribution of the impact cutters on the outer cylindrical surface of the roller are achieved, the number of single cutters in unit area on the outer cylindrical surface of the roller is increased to a certain extent, and the efficiency of crushing the biomass fuel with certain hardness by the cutters or the impact cutters on the single cutters is improved.

In addition, compared with the biomass fuel crusher with the publication number of CN 107520019A, the biomass fuel crusher can also realize the active switching between the cutter and the impact cutter, thereby realizing the effective cutting or crushing of single type of biomass fuel, realizing the classified batch cutting or crushing of biomass fuels with different materials while actively reducing the abrasion of the cutter, and realizing the approximate classification of the crushed biomass fuel while improving the universality of single type of biomass fuel. The invention has simple structure and better use effect.

Drawings

Fig. 1 is an overall schematic view of the present invention.

Fig. 2 is an overall sectional view of the present invention.

Fig. 3 is a schematic view of the crushing module, the thin steel wire and the corresponding wire winding wheel A matched with each other and a partial section of the thin steel wire and the corresponding wire winding wheel A.

Figure 4 is a schematic view of a roll.

Fig. 5 is a schematic view of a crushing module.

Fig. 6 is a schematic cross-sectional view of the sleeve B, the fixture block C and the limiting block.

Fig. 7 is a schematic cross-sectional view of the sleeve a, the latch B and the shaft B.

Fig. 8 is a schematic view of the crushing module in overall section.

Fig. 9 is a schematic view of a base.

Fig. 10 is a schematic cross-sectional view of the base from two perspectives.

FIG. 11 is a schematic view of the combination of the cutter, arc plate B, sleeve B, shaft B, sleeve A and impact knife.

Fig. 12 is a schematic cross-sectional view of the impact knife engaged with the sleeve a.

Number designation in the figures: 1. a roller; 2. mounting grooves; 3. a shaft sleeve; 4. an axis A; 5. a worm gear; 6. a worm; 7. a fixed seat; 8. a crank; 9. a support frame; 10. a winding wheel A; 11. thin steel wires; 12. a crushing module; 13. a base; 14. a column groove; 15. a swinging groove A; 16. a swing groove B; 17. an arc groove A; 18. a chute; 19. a guide groove; 20. an arc groove B; 21. a circular groove; 22. a ring groove A; 23. a cutter; 25. a partition plate; 26. a rubber sleeve; 27. a winding wheel B; 28. a volute spiral spring A; 29. a sleeve A; 30. a ring groove B; 31. an arc plate A; 32. an impact knife; 33. a volute spiral spring B; 34. a clamping block A; 35. a clamping block B; 36. a sleeve B; 37. a clamping block C; 38. a limiting block; 39. an inclined plane A; 40. a bevel B; 41. a guide block; 42. a limiting spring; 43. and an arc plate B.

Detailed Description

The drawings are schematic illustrations of the implementation of the present invention to facilitate understanding of the principles of structural operation. The specific product structure and the proportional size are determined according to the use environment and the conventional technology.

As shown in fig. 1 and 2, the crushing device comprises a roller 1, shaft sleeves 3 and a crushing module 12, wherein as shown in fig. 2, the hollow roller 1 rotates in the crushing device, and the two shaft sleeves 3 symmetrically arranged at the centers of two ends of the roller 1 are in rotating fit with the crushing device; as shown in fig. 1, 2 and 4, crushing modules 12 for performing soft and hard classification crushing on biomass fuel entering into the crushing equipment are respectively installed in a plurality of installation grooves 2 which are uniformly distributed on the outer cylindrical surface of a roller 1.

As shown in fig. 5 and 8, the crushing module 12 includes a base 13, a volute spring a28, a sleeve a29, an impact knife 32, a volute spring B33, a sleeve B36, an arc plate B43 and a cutter 23, wherein as shown in fig. 2 and 3, the base 13 is fixedly installed in the corresponding installation groove 2; as shown in fig. 2, 9 and 10, a column groove 14 is formed in the base 13, and the central axis of the column groove 14 is parallel to the central axis of the roller 1; as shown in fig. 8, 9 and 11, a shaft B having the same center axis as the cylindrical groove 14 is rotatably fitted to the base 13, and a spiral spring a28 for rotationally returning the shaft B is mounted on the shaft B; the sleeve A29 and the two sleeves B36 which rotate in the column groove 14 are coaxially arranged on the shaft B, and the two sleeves B36 are symmetrically distributed at two sides of the sleeve A29; the sleeve A29 is rotationally matched with the shaft B, and the sleeve B36 is fixedly connected with the shaft B; as shown in fig. 6, 7 and 8, the sleeve a29 is provided with an impact knife 32 which is matched with a swing groove a15 on the base 13, two sleeves B36 are symmetrically provided with two arc plates B43 which are matched with a swing groove B16 on the base 13, and the tail ends of the two arc plates B43 are provided with cutting knives 23; shaft B is drivingly connected to sleeve a29 by a pre-energized volute spring B33.

As shown in fig. 7, 10 and 11, the sleeve a29 and the base 13 have a structure for limiting the rotation amplitude of the sleeve a29 relative to the base 13; as shown in fig. 6, 10, and 11, the sleeve B36 and the base 13 have a structure between them that limits the amplitude of rotation of the sleeve B36 relative to the base 13, and the structure that limits the amplitude of rotation of the sleeve B36 relative to the base 13 creates an incomplete limit on the relative position between the sleeve B36 and the base 13.

As shown in fig. 1, 2 and 3, the crushing module 12, the roller 1 and the shaft sleeve 3 are provided with a structure for actively switching the impact knife 32 and the cutting knife 23.

As shown in fig. 1, 2 and 3, a shaft a4 is rotatably fitted on the central axis of the roller 1, and both ends of the shaft a4 are rotatably fitted to the two bushings 3, respectively. A plurality of supporting frames 9 which are rotatably matched with the shaft A4 are axially arranged in the roller 1 at intervals, and the supporting frames 9 effectively support the shaft A4, so that the strength of the shaft A4 is improved. As shown in fig. 8 and 10, two ends of the shaft B in the crushing module 12 are respectively rotatably matched with two circular grooves 21 on the side walls of two ends of the corresponding cylindrical groove 14; the inner wall of each circular groove 21 is provided with a circular groove A22; a spool B27 is arranged on the shaft B, and the coaxial spool B27 and the volute spiral spring A28 are respectively positioned in the two ring grooves A22; one end of the scroll spring A28 is connected with the corresponding shaft B, and the other end is connected with the inner wall of the corresponding ring groove A22; as shown in fig. 2 and 3, a plurality of winding wheels a10 are axially and uniformly installed on a shaft a4 at intervals, and each winding wheel a10 is in transmission connection with winding wheels B27 in a plurality of crushing modules 12 which are uniformly distributed in the circumferential direction on the same plane through a plurality of thin steel wires 11 wound on the winding wheels in the same direction; worm wheel 5 is installed to axle A4 one end, and the worm 6 with worm wheel 5 meshing cooperates with the fixing base 7 of installation on corresponding axle sleeve 3 rotation, and crank 8 is installed to worm 6 one end. The annular groove A22 improves the accommodation space for the coiler B27 and the volute spiral spring A28. The worm 6 and the worm wheel 5 are matched to realize the rotation of the shaft A4 relative to the shaft sleeve 3 and simultaneously have a self-locking fixing function on the relative position of the shaft A4 relative to the shaft sleeve 3 after the shaft A4 rotates.

As shown in fig. 7, 10 and 11, the outer cylindrical surface of the sleeve a29 is provided with concentric arc plates a31, and the arc plates a31 slide around the central axis of the shaft B in the arc grooves B20 on the cylindrical surface of the corresponding cylindrical groove 14. The cooperation of arc board A31 and arc groove B20 is when restricting the swing range of impact sword 32 to the impact reaction that produces when the broken biomass fuel of impact sword 32 forms and stops, guarantees that impact sword 32 keeps broken position and then effectively exerts its crushing effect to the biomass fuel.

As shown in fig. 7, 8 and 12, the inner wall of the sleeve a29 is provided with a ring groove B30, and a scroll spring B33 nested on the shaft B is positioned in the ring groove B30; one end of the scroll spring B33 is connected with the inner wall of the ring groove B30, and the other end is connected with the shaft B; a fixture block A34 arranged on the inner wall of the ring groove B30 is matched with a fixture block B35 arranged on the shaft B; the wrap spring B33 is always in compression. Annular groove B30 provides accommodation space for volute spring B33, latch a34 and latch B35, and reduces the space occupied by latch a34, latch B35 and volute spring B33 on axis B.

As shown in fig. 6, 10 and 11, two blocks C37 are symmetrically installed on the outer cylindrical surfaces of two sleeves B36 in the crushing module 12, and the two blocks C37 move around the central axis of the shaft B in two arc grooves a17 on the cylindrical surface of the cylindrical groove 14 respectively; as shown in fig. 6 and 10, a sliding groove 18 is formed on the arc surface of each arc groove a17, and a limiting block 38 slides in each sliding groove 18 along the radial direction of the shaft B; a limit spring 42 for resetting the corresponding limit block 38 is arranged in the sliding groove 18; one end of the limiting block 38 is provided with a slope A39 and a slope B40 which are matched with the corresponding fixture block C37; two guide blocks 41 are symmetrically installed on the limiting block 38, and the two guide blocks 41 respectively slide in the two guide grooves 19 on the inner wall of the corresponding sliding groove 18. The cooperation of the guide groove 19 and the guide block 41 plays a positioning and guiding role in the sliding of the limit block 38 in the slide groove 18, and simultaneously ensures that the limit spring 42 is in a compressed state. The interaction of the fixture block C37 and the arc groove A17 realizes that the cutter 23 has a better cutting angle for soft biomass fuel by limiting the swing amplitude of the cutter 23, and meanwhile, the fixture block C37 is matched with the limiting block 38, so that the cutter 23 can swing under the action of the biomass fuel when meeting the biomass fuel with higher hardness and smoothly swings back and return to reset after the biomass fuel with higher hardness is broken by the impact knife 32, thereby reducing the abrasion of the cutter 23 and prolonging the service life of the cutter 23.

As shown in fig. 5 and 8, two partition plates 25 rotatably engaged with the shaft B are installed in the column groove 14, and the two partition plates 25 are respectively located in gaps between the sleeve a29 and the two sleeves B36; a rubber sleeve 26 is matched between the shaft B and the partition plate 25, and the rubber sleeves 26 are respectively matched between the shaft B and the inner walls of the corresponding two circular grooves 21. The rubber sleeve 26 absorbs the impact transmitted to the shaft B through the sleeve A29 or the sleeve B36 when the cutter 23, particularly the impact cutter 32 interacts with the hard biomass fuel, so that the shaft B is prevented from being broken due to repeated impact for a long time, the service life of the shaft B is prolonged, and the maintenance cost of the equipment is reduced.

As shown in fig. 6, the slope of the inclined plane a39 on the limiting block 38 is greater than the slope of the inclined plane B40, so that a certain cutting force is ensured when the cutting knife 23 cuts the biomass fuel under the indirect action of the inclined plane a39 and the fixture block C37, when the cutting knife 23 encounters a hard biomass material which is not suitable for being cut by the cutting knife 23, the fixture block C37 swings with the sleeve B36 under the interaction between the cutting knife 23 and the hard biomass fuel, overcoming the limitation of the inclined plane a39, and the sleeve B36 drives the cutting knife 23 to swing through the arc plate B43 so as to avoid the impact damage of the hard biomass fuel on the cutting knife 23. The smaller slope of the inclined plane B40 is beneficial to the smooth reset of the cutting knife 23 by the fixture block C37 against the limit of the inclined plane B40 under the reset action of the scroll spring a 28.

The two clapboards 25 in the invention can effectively support the shaft B, and simultaneously can block the gap between the sleeve A29 and the two sleeves B36, so as to prevent broken biomass fuel particles from entering the gap between the sleeve A29 and the sleeve B36 to block the rotation of the sleeve A29 and the sleeve in the column groove 14.

The working process of the invention is as follows: in the initial state, the thin wire 11 between the reel a10 and the reel B27 is in a taut state. The shaft a4 and the shaft sleeve 3 are kept in a fixed relative rotation position due to the self-locking function of the worm 6 and the worm wheel 5. The scroll spring A28 and the scroll spring B33 in the crushing module 12 are both in the pre-compression energy storage state, and the clamping block A34 contacts with the corresponding clamping block B35 to ensure that the scroll spring B33 is in the pre-compression energy storage state. The two clamping blocks C37 are respectively and simultaneously located at the extreme positions in the corresponding arc grooves A17 to ensure that the cutting knife 23 arranged on the arc plate B43 is maintained at the position state for cutting and crushing the soft biomass fuel. The arc plate A31 is located at the extreme position of the corresponding arc groove B20, and the inclined surface A39 of the limiting block 38 interacts with the corresponding clamping block C37, so that the cutter 23 cannot swing when cutting biomass fuel, and the cutter 23 is guaranteed to have certain cutting force on the biomass fuel. The cutter 23 is positioned outside the swinging groove B16 and is in a cutting state for the soft biomass fuel, and the impact knife 32 is positioned in the corresponding swinging groove A15.

In the initial state, the guide block 41 is located at the extreme position of the corresponding guide groove 19, and the limit spring 42 is in the pre-compression energy storage state.

When the biomass fuel entering the crushing equipment in the running state is soft straw biomass fuel, the cutting knife 23 in the crushing module 12 rotating synchronously with the roller 1 cuts and crushes the entering straw. Due to the uniform arrangement of the crushing modules 12 on the roller 1, the number of the cutters 23 is obviously increased, and the cutting and crushing efficiency of the cutters 23 on the straw biomass fuel is improved.

In the process that the cutter 23 cuts and crushes the straw biomass fuel, the volute spiral spring a28 in the energy storage state in the crushing module 12 improves the support for the interaction between the cutter 23 and the straw, so that the cutter 23 cannot swing around the central axis of the shaft B along with the sleeve B36 under the reaction of the biomass fuel.

When the biomass fuel entering the crushing device in the operating state is biomass fuel such as hard branches or waste wood boards, the biomass fuel is difficult to cut and crush by the cutter 23 due to the high hardness of the biomass fuel. At this time, the biomass fuel such as the branches or the wood boards acts on the cutting knife 23 rotating with the roller 1, so that the cutting knife 23 swings into the swinging groove B16 rapidly around the central axis of the shaft B. Meanwhile, the cutter 23 drives the corresponding shaft B to rotate through the corresponding two arc plates B43 and two sleeves B36, the sleeve B36 drives the arc plate a31 mounted on the sleeve B to move from one end limit position of the arc groove B20 to the other end limit position, the shaft B drives the sleeve a29 to rotate in the same direction by further compressing the corresponding volute spiral spring B33, and the sleeve a29 drives the corresponding impact knife 32 to rapidly swing out of the corresponding swing groove a15 and be in the radial direction of the roller 1 to act on the hard biomass fuel entering the crushing device. At the same time, the scroll spring a28 in crushing module 12 is further compressed and stored energy by the rotating shaft B, and cartridge a34 disengages from cartridge B35 mounted on shaft B as shaft B rotates.

When the cutter 23 swings under the action of the hard biomass fuel, the cutter 23 drives the sleeve B36 to overcome the limitation of the block C37 by the inclined plane A39 on the limiting block 38 through the arc plate B43, so that the limiting block 38 retracts towards the inside of the sliding groove 18 to remove the limitation on the rotation of the sleeve B36, and the limiting spring 42 is further compressed to store energy. After the latch C37 clears the ramp A39, the stop 38 returns to the initial position within the slide slot 18 and disengages from the moving latch C37 under the influence of the stop spring 42.

Due to the fact that the size and the thickness parameters of the impact knife 32 are large, the impact knife 32 can smoothly complete impact crushing on the hard biomass fuel along with the rotation of the roller 1. When the impact knife 32 breaks the hard biomass fuel, the cutting knife 23 is in a lodging state, and the cutting edge of the cutting knife 23 deviates from the hard biomass fuel in the rotating direction of the roller 1, so that the hard biomass fuel is prevented from damaging or wearing the cutting edge of the cutting knife 23, and the service life of the cutting knife 23 is prolonged.

When the hard biomass fuel entering the crushing device is completely crushed and completely separated from the crushing device, the impact knife 32 interacting with the hard biomass fuel loses the function of the biomass fuel. At this time, under the reset action of the volute spiral spring a28, the shaft B drives the cutter 23 to rapidly swing back to the initial state through the sleeve B36 and the arc plate B43. Meanwhile, the rotation of the shaft B releases the restriction of the volute spiral spring B33, and under the reset action of the volute spiral spring B33, the sleeve a29 drives the impact knife 32 and the fixture block a34 to rapidly swing back to the initial state, and the fixture block a34 and the fixture block B35 are in contact again. At this time, the latch C37 overcomes the ramp B40 on the stopper 38 and clears the stopper 38 to the initial position to re-contact the ramp A39 on the stopper 38. The limiting block 38 completes incomplete limiting of the sleeve B36 again under the action of the limiting spring 42, and the sleeve A29 drives the arc plate A31 to return to the initial position in the arc groove B20.

When the invention is needed to crush only hard biomass fuel, in order to avoid impact damage or abrasion damage to the cutting knife 23 when hard material enters the crushing device in the initial stage, the cutting knife 23 and the impact knife 32 on the crushing module 12 can be switched together before the invention is operated. The specific switching process is as follows:

before the crushing equipment runs, the crank 8 is shaken, the crank 8 drives the worm 6 to rotate, the worm 6 drives the shaft A4 to rotate through the worm wheel 5, and the shaft A4 drives the plurality of winding wheels A10 to synchronously rotate. The plurality of winding wheels simultaneously wind the plurality of thin steel wires 11 wound on the plurality of winding wheels, and the plurality of thin steel wires 11 respectively and simultaneously pull the winding wheels B27 in the corresponding crushing modules 12 to rotate. The reel B27 in the crushing module 12 drives the corresponding shaft B to rotate synchronously, the shaft B drives the cutter 23 to rapidly swing into the corresponding swing groove B16 through the sleeve B36 and the arc plate B43, so that the cutter 23 is in a lodging state, and the volute spiral spring A28 is further compressed to store energy. The cutter 23 drives the sleeve B36 through the arc plate B43 to overcome the limitation of the block C37 by the inclined plane A39 on the limiting block 38, so that the limiting block 38 retracts towards the sliding groove 18 to remove the limitation on the rotation of the sleeve B36, and the limiting spring 42 is further compressed to store energy. After the latch C37 clears the ramp A39, the stop 38 returns to the initial position within the slide slot 18 and disengages from the moving latch C37 under the influence of the stop spring 42. Meanwhile, the shaft B drives the sleeve A29 to rotate in the same direction by further compressing the scroll spring B33, and the sleeve A29 drives the impact knife 32 to rapidly swing out of the swing groove A15.

When the arc plate A31 moves to the other end limit position of the arc groove along with the sleeve A29, the sleeve A29 stops swinging, and the impact knife 32 is positioned in the radial direction of the roller 1. At this time, the rocking of the crank 8 is stopped, and the self-locking function of the worm wheel 5 and the worm 6 secures a new relative rotational position of the shaft a4 and the sleeve 3, thereby completing the fixing of the position at which the impact knife 32 performs the crushing operation.

If the impact knife 32 needs to be switched to the cutting knife 23 again, the crank 8 is turned back before the crushing equipment runs, the crank 8 drives the shaft A4 to rotate through the worm 6 and the worm wheel 5, the shaft A4 drives the winding wheels A10 to discharge the thin steel wires 11 wound on the winding wheels A3526, and therefore the winding wheels B27 in the crushing module 12 are relieved from being pulled by the thin steel wires 11. The shaft B in the crushing module 12 rapidly rotates to the initial state under the reset action of the corresponding volute spiral spring A28, and the shaft B drives the arc plate A31, the arc plate B43 and the cutter 23 to rapidly rotate back to the initial state through the two sleeves B36. The compression limitation on the scroll spring B33 is released while the shaft B rotates, the sleeve A29 drives the impact knife 32 to quickly swing back to the initial state under the reset action of the scroll spring B33, and the clamping block A34 is quickly contacted with the clamping block B35 again. The latch C37 overcomes the ramp B40 on the stop block 38 and clears the stop block 38 to the initial position to re-engage the ramp A39 on the stop block 38. Then, the rocking of the crank 8 is stopped, and the self-locking function of the worm wheel 5 and the worm 6 ensures the fixing of the relative rotational position of the shaft a4 and the boss 3.

In conclusion, the beneficial effects of the invention are as follows: according to the invention, the crushing modules 12 which simultaneously comprise the paired cutters 23 and the impact cutters 32 are uniformly arranged on the outer cylindrical surface of the roller 1 to realize cutting, crushing and impact crushing of biomass fuels with different hardness and forms, so that the equipment is more suitable for crushing the biomass fuels with wider hardness range, and the universality is improved.

Meanwhile, the cutter 23 and the impact cutter 32 in the crushing module 12 can realize mutual conversion aiming at biomass fuels with different hardness under the passive action of the biomass fuels entering into the crushing equipment or the manually selected active action, so that the problem of serious cutter abrasion caused by single cutter use range in the traditional biomass fuel crusher is solved.

Compared with the situation that the crushing efficiency is low due to the fact that the number of two cutters is small in a biomass fuel crusher with the publication number of CN 107520019A due to the structural characteristics of the biomass fuel crusher, the crushing efficiency is low due to the fact that the crushing modules 12 which are internally provided with the cutters 23 and the impact cutters 32 in pairs are uniformly arranged on the outer cylindrical surface of the roller 1, the distribution of the impact cutters 32 on the outer cylindrical surface of the roller 1 is uniform, the distribution of the cutters 23 on the outer cylindrical surface of the roller 1 is uniform, the number of single cutters of a unit area on the outer cylindrical surface of the roller 1 is increased to a certain extent, and the crushing efficiency of the cutters 23 or the impact cutters 32 on the biomass fuel with certain hardness is improved.

In addition, compared with the biomass fuel crusher with the publication number of CN 107520019A, the invention can also realize the active switching between the cutter 23 and the impact knife 32, thereby realizing the effective cutting or crushing of the invention on single type of biomass fuel, realizing the classified batch cutting or crushing of biomass fuel with different materials while actively reducing the abrasion of the cutter 23, and realizing the approximate classification of the crushed biomass fuel while improving the universality of single type of biomass fuel.