CN115430331A

CN115430331A - Raw material mixing equipment is used in production of biomass energy granule

Info

Publication number: CN115430331A
Application number: CN202210981237.7A
Authority: CN
Inventors: 袁芳
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-08-16
Filing date: 2022-08-16
Publication date: 2022-12-06

Abstract

The invention provides raw material mixing equipment for biomass energy particle production, which structurally comprises a main body, a discharge pipe, a support ring, a mixing mechanism and a feeding pipe, wherein the outer wall of the rear end of the discharge pipe is fixedly attached to the outer wall in front of the lower end of the main body, the outer wall of the lower end of the support ring is fixedly welded to the outer wall of the upper end of the main body, and the outer walls of the lower ends of the front side and the rear side of the mixing mechanism are movably clamped to the outer wall of the upper end of the support ring.

Description

Raw material mixing equipment is used in production of biomass energy granule

Technical Field

The invention relates to the field of biomass energy, in particular to raw material mixing equipment for biomass energy particle production.

Background

Biomass refers to an energy substance produced by a biomass through obtaining natural energy in various ways and converting the natural energy by itself, including all animals, plants and microorganisms, and biomass is an energy form in which solar energy is stored in the biomass in a chemical energy form, and among various renewable energy sources, due to potential ecological environment risks of nuclear energy and large hydropower, regional resource constraints such as wind energy and geothermal energy are greatly limited and questioned, while biomass is generally characterized by ubiquity, richness, renewability and the like, the uniqueness of biomass not only lies in the ability to store solar energy, but also is a renewable carbon source, and can be converted into conventional solid, liquid and gaseous fuels, and energy sources such as coal, petroleum, natural gas and the like are also extremely converted from biomass energy, and have renewability, so that attention is paid to the utilization of biomass energy sources according to the characteristics of biomass energy sources, while in the production of biomass energy particles, mixing of a plurality of raw materials needs to be performed by using a mixing device for producing biomass energy particles, and mixing of raw materials is not performed by using a mixing device in a mixing manner, and then, so that all raw materials cannot be mixed and mixed in a mixing process is completely completed in a mixing process.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a raw material mixing device for biomass energy particle production, which solves the problems that when biomass energy particles are produced, a plurality of raw materials are required to be mixed, when the raw materials are mixed, one raw material mixing device for biomass energy particle production is required to be used for mixing the raw materials, the existing mixing device usually adopts a stirring mode to mix the raw materials, but when the raw materials are stirred, the raw materials cannot completely cover all surfaces in the device, so that part of the raw materials can be clamped into dead corners, the raw materials can not be completely mixed after the mixing process is finished, and the raw materials are required to be mixed again manually.

Aiming at the above purpose, the invention is realized by the following technical scheme: a raw material mixing device for biomass energy particle production structurally comprises a main body, a discharge pipe, a support ring, a mixing mechanism and a feeding pipe, wherein the outer wall of the rear end of the discharge pipe is fixedly attached to the outer wall in front of the lower end of the main body;

mixing mechanism comprises support frame, dwang, blender, support frame rear end outer wall activity block in support ring front end outer wall, dwang outer wall nested fit in support frame central inner wall, the nested block in dwang rear end outer wall of blender inner wall, blender upper end outer wall movable fit is in pan feeding pipe lower extreme outer wall, blender outer wall movable fit is in the main part inner wall.

Preferably, the mixer comprises a stirring mechanism, a clamping ring and stirring blocks, wherein the inner wall of the stirring mechanism is nested and clamped on the outer wall of the rear end of the rotating rod, the inner wall of the clamping ring is nested and matched on the outer wall of the front end of the rotating rod, the outer wall of the left upper end of each stirring block is fixedly attached to the outer wall of the stirring mechanism, and six stirring blocks are annularly arranged on the outer wall of the stirring mechanism.

Preferably, the stirring mechanism comprises a stirring ring, a driving rod, a conducting mechanism and a rotating ring, wherein the outer wall of the stirring ring is welded and fixed on the inner wall of the stirring block, the outer wall of the driving rod is attached and fixed on the inner wall of the stirring ring, the inner wall of the outer end of the conducting mechanism is nested and clamped on the outer wall of the right lower end of the driving rod, and the outer wall of the rotating ring is movably matched with the inner wall of the conducting mechanism.

Preferably, the conduction mechanism comprises a rotator, three connecting rods, a clamping rod and a reinforcing rod, wherein the inner wall of the rotator is in nested fit with the outer wall of the matching mechanism, the outer wall of the rear side of the upper end of each connecting rod is fixedly embedded and clamped in the inner wall of the front end of the rotator, the outer wall of the clamping rod is in nested fit with the inner wall of the rotator, the outer wall of the rear end of each reinforcing rod is attached and fixed to the outer wall of the front end of each connecting rod, and the three connecting rods are annularly arranged on the inner wall of the surface of the front end of the rotator.

Preferably, the rotator comprises a ring body, a friction ring, a vibration mechanism and a matching ring, wherein the inner wall of the ring body is nested and clamped on the outer wall of the clamping rod, the outer wall of the friction ring is in friction fit with the outer wall of the matching ring, the outer wall of the vibration mechanism is nested and clamped on the inner wall of the friction ring, and the outer wall of the matching ring is nested and fixed on the inner wall of the ring body.

Preferably, the vibration mechanism is internally provided with three swinging rings, clamping and fixing rods and an expansion mechanism, the outer walls of the swinging rings are nested and clamped on the inner wall of the vibration mechanism, the outer walls of the clamping and fixing rods are nested and fixed on the outer walls of two ends of the expansion mechanism, the outer wall of the expansion mechanism is movably matched with the inner wall of the friction ring, the three swinging rings are annularly arranged on the inner wall of the vibration mechanism, and the positions of the three swinging rings are limited by elastic collars arranged at two ends of the vibration mechanism.

Preferably, the expansion mechanism comprises a moving device, positioning frames, embedded connecting rods and fixing frames, wherein the outer walls of two ends of the moving device are attached and fixed between the fixing frames, the inner wall of the left side of each embedded connecting rod is embedded and fixed on the outer wall of the center of the positioning frame, the outer wall of the center of the fixing frame is fixed on the inner wall of the right side of each embedded connecting rod in a closed manner, the inner walls of the upper end and the lower end of each positioning frame are embedded and clamped on the outer wall of each clamping and fixing rod, and the two positioning frames and the two embedded connecting rods are arranged on the outer walls of two ends of the moving device in a mirror image manner.

Preferably, the mover comprises a magnetic frame, a shell, a rotary ring, expansion rings and positioning magnetic rings, wherein the outer wall of the upper end of the magnetic frame is in friction fit with the outer wall of the expansion ring, the inner wall of the rotary ring is fixed on the outer wall of the magnetic frame in an embedded mode, the outer wall of the expansion ring is fixed on the inner wall of the shell in an attached mode, the outer wall of each positioning magnetic ring is fixedly clamped on the central inner wall of the shell in an embedded mode, the outer walls of two ends of the shell are fixed between the fixing frames in an attached mode, and the number of the magnetic frames is six and the magnetic frames are arranged on the inner wall of the rotary ring in an annular mode.

Advantageous effects

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

when the biomass mixer is used, the equipment is started and operated, the biomass filled in the equipment and other raw materials are driven to be mixed through the rotation of the mixer, the rotation of the mixer can enable the rotating device and the vibrating mechanism arranged in the mixer to carry out mutual friction when the mixing is carried out, the vibrating mechanism is vibrated through centrifugal inertia force generated by the rotation and acting force generated by the friction, the raw materials around the inner part are driven through high-frequency vibration of the vibrating mechanism, and the raw materials are further uniformly mixed through vibration.

Drawings

FIG. 1 is a schematic structural diagram of a raw material mixing apparatus for biomass energy particle production according to the present invention.

Fig. 2 is a schematic top view of the mixing mechanism of the present invention.

FIG. 3 is a schematic diagram of the mixer of the present invention.

Fig. 4 is a schematic sectional structure view of the stirring mechanism of the invention.

Fig. 5 is a schematic structural diagram of the inventive conducting mechanism.

Fig. 6 is a schematic sectional view of the inventive rotor.

Fig. 7 is a schematic sectional structure view of the vibration mechanism of the invention.

Fig. 8 is a schematic structural view of the inventive stent.

Fig. 9 is a schematic cross-sectional view of an inventive mover.

In the figure: the device comprises a main body-1, a discharge pipe-2, a support ring-3, a mixing mechanism-4, a feeding pipe-5, a support frame-41, a rotating rod-42, a mixer-43, a stirring mechanism-a 1, a clamping ring-a 2, a stirring block-a 3, a stirring ring-b 1, a driving rod-b 2, a conducting mechanism-b 3, a rotating ring-b 4, a rotator-c 1, a connecting rod-c 2, a clamping rod-c 3, a reinforcing rod-c 4, a ring body-d 1, a friction ring-d 2, a vibrating mechanism-d 3, a matching ring-d 4, a swinging ring-e 1, a clamping and fixing rod-e 2, an expanding mechanism-e 3, a mover-f 1, a positioning frame-f 2, an embedded connecting rod-f 3, a positioning frame-f 4, a magnetic frame-g 1, a shell-g 2, a rotating ring-g 3, a ring-g 4 and a positioning magnetic ring-g 5.

Detailed Description

The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is obvious that the described embodiments are some, but not all embodiments of the present invention, and all other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without creative efforts belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Example 1

As shown in fig. 1 to 6, the invention provides a raw material mixing device for biomass energy particle production, which structurally comprises a main body 1, a discharge pipe 2, a support ring 3, a mixing mechanism 4 and a feeding pipe 5, wherein the outer wall of the rear end of the discharge pipe 2 is attached and fixed to the outer wall of the front part of the lower end of the main body 1, the outer wall of the lower end of the support ring 3 is welded and fixed to the outer wall of the upper end of the main body 1, the outer walls of the lower ends of the front side and the rear side of the mixing mechanism 4 are movably clamped on the outer wall of the upper end of the support ring 3, and the outer wall of the feeding pipe 5 is movably matched with the inner wall of the main body 1;

mixing mechanism 4 comprises support frame 41, dwang 42,

blender

43, 41 rear end outer walls of support frame activity block in support ring 3 front end outer wall, dwang 42 outer wall nested fit is in 41 central inner walls of support frame, 43 inner walls nested block in dwang 42 rear end outer wall, 43 upper end outer walls of blender movable fit is in 5 lower extreme outer walls of pan feeding pipe, 43 outer walls of blender movable fit is in 1 inner wall of main part.

Wherein, blender 43 comprises rabbling mechanism a1, screens ring a2, stirring piece a3, the nested block of rabbling mechanism a1 inner wall is in dwang 42 rear end outer wall, the nested cooperation in the askew coin of dwang 42 front end of screens ring a2 inner wall, the laminating of stirring piece a3 upper left end outer wall is fixed in the rabbling mechanism a1 outer wall, stirring piece a3 is equipped with six altogether, and the annular is arranged in rabbling mechanism a1 outer wall, and stirring piece a3 through being equipped with at six ends is when rotating the stirring for the stirring can take animal material to increase.

Wherein, rabbling mechanism a1 comprises stirring ring b1, drive lever b2, conduction mechanism b3, swivel becket b4, stirring ring b1 outer wall welded fastening is in stirring piece an 3 inner wall, the laminating of drive lever b2 outer wall is fixed in stirring ring b1 inner wall, the nested joint in drive lever b2 right side lower extreme outer wall of conduction mechanism b3 outer end inner wall, swivel becket b4 outer wall movable fit is in conduction mechanism b3 inner wall.

The transmission mechanism b3 comprises a rotator c1, a connecting rod c2, a clamping rod c3 and a reinforcing rod c4, the inner wall of the rotator c1 is in nested fit with the outer wall of the matching mechanism c4, the outer wall of the rear side of the upper end of the connecting rod c2 is in embedded and clamped with the inner wall of the front end of the rotator c1, the outer wall of the clamping rod c3 is in nested fit with the inner wall of the rotator c1, the outer wall of the rear end of the reinforcing rod c4 is in fit and fixed with the outer wall of the front end of the connecting rod c2, the three connecting rods c2 are arranged in an annular arrangement on the inner wall of the surface of the front end of the rotator c1, and when the connecting rods c2 arranged at the three ends are driven to rotate, the rotating force can be transmitted to the rotator c1 through the three points, so that the rotator c1 can be more easily driven to rotate.

The rotator c1 comprises a ring body d1, a friction ring d2, a vibration mechanism d3 and a matching ring d4, the inner wall of the ring body d1 is nested and clamped on the outer wall of the clamping rod c3, the outer wall of the friction ring d2 is in friction fit with the outer wall of the matching ring d4, the outer wall of the vibration mechanism d3 is nested and clamped on the inner wall of the friction ring d2, and the outer wall of the matching ring d4 is nested and fixed on the inner wall of the ring body d 1.

The following examples are set forth: when the device is required to be used, raw material particles required to be mixed are filled into the main body 1, biomass raw materials can be filled into the main body 1 through the feeding pipe 5, the device can be started after the materials enter the main body 1, the rotating rod 42 arranged in the device is driven to rotate, the rotating rod 42 rotates, when the rotating rod 42 rotates, the rotating force of the rotating rod 42 is transmitted to the mixer 43, so that the stirring mechanism a1 arranged in the mixer 43 is acted by the rotating force to rotate, the stirring block a3 is driven through the rotation of the stirring mechanism a1, the raw materials filled in the device are stirred through the rotation of the stirring block a3, when the rotating rod 42 rotates, the rotating force of the rotating rod 42 drives the rotating ring b4 to rotate in advance, the connecting rod c2 is driven through the rotation of the rotating ring b4, the rotating device c1 is driven to rotate through the rotation of the connecting rod c2, when the rotating device c1 rotates, the rotating ring d4 arranged in the rotating device c1 rotates, and the friction ring d3 acts on the friction ring d4 to trigger the friction mechanism.

Example 2

As shown in fig. 7 to 9: the vibration mechanism d3 is internally provided with a swinging ring e1, a clamping and fixing rod e2 and an expansion mechanism e3, the outer wall of the swinging ring e1 is nested and clamped on the inner wall of the vibration mechanism d3, the outer wall of the clamping and fixing rod e2 is nested and fixed on the outer walls of two ends of the expansion mechanism e3, the outer wall of the expansion mechanism e3 is movably matched with the inner wall of the friction ring d2, the swinging rings e1 are three in number and are annularly arranged on the inner wall of the vibration mechanism d3, the positions of the swinging rings are limited by elastic collars arranged at two ends, and when the swinging ring e1 is acted by centrifugal inertia force during rotation, the swinging ring e1 can move and swing under the action of the elastic collars.

The expanding mechanism e3 comprises a mover f1, a positioning frame f2, an embedded connecting rod f3 and a fixing frame f4, the outer walls of the two ends of the mover f1 are fixed between the fixing frames f4 in an attaching mode, the inner wall of the left side of the embedded connecting rod f3 is fixed on the outer wall of the center of the positioning frame f2 in an embedded mode, the outer wall of the center of the fixing frame f4 is fixed on the inner wall of the right side of the embedded connecting rod f3 in a closed mode, the inner walls of the upper end and the lower end of the positioning frame f2 are clamped on the outer wall of the clamping rod e2 in an embedded mode, the number of the positioning frame f2 and the embedded connecting rod f3 is two, and the two expanding mechanisms are arranged on the outer walls of the two ends of the mover f1 in a mirror image mode.

The mover f1 comprises a magnetic frame g1, a shell g2, a rotary ring g3, an expansion ring g4 and positioning magnetic rings g5, the outer wall of the upper end of the magnetic frame g1 is in friction fit with the outer wall of the expansion ring g4, the inner wall of the rotary ring g3 is fixed on the outer wall of the magnetic frame g1 in a nested mode, the outer wall of the expansion ring g4 is fixed on the inner wall of the shell g2 in a fitted mode, the outer wall of the positioning magnetic rings g5 is clamped on the central inner wall of the shell g2 in an embedded mode, the outer walls of the two ends of the shell g2 are fixed between the fixing frames f4 in a fitted mode, the magnetic frames g1 are provided with six parts in a total number, the six parts are arranged on the inner wall of the rotary ring g3 in an annular mode, and magnetic suspension of the rotary ring g3 is achieved through repulsive force effect of the magnetic frames g1 and the positioning magnetic rings g5 arranged at the six ends.

The following examples are set forth: when the filling of the raw materials is completed in the equipment and the equipment is started to drive partial parts in the equipment to rotate and mix the raw materials, the rotating force generated when the partial parts in the equipment rotate to drive the raw materials to mix can rub against the outer wall surface of the upper end of the expansion mechanism e3 through the partial parts, when the outer wall surface of the upper end of the expansion mechanism e3 is rubbed, the shifter f1 arranged in the expansion mechanism e3 is under the action of the friction force, the rotary ring g3 arranged in the shifter f1 is driven to rotate under the action of the friction force, the rotary ring g3 rotates to rub against the surface of the expansion ring g4, and the expansion ring g4 is expanded under the action of the heat energy generated by the friction, after the expansion ring g4 expands, the expanded volume of the expansion ring g4 pushes the rotary ring g3 to rise, after the rotary ring g3 rises, the rotary ring g3 can collide with rotating parts inside the equipment and generate vibration force through the collision, after the heat is too high, the rising position of the rotary ring g3 can reach a limit and cannot collide, the rotary ring can be driven to rotate, the centrifugal inertia force generated during the rotation can cause the swing ring e1 to swing due to the action of inertia force, when the swing ring e1 swings, the swing ring e1 swings and vibrates through the collision, high-frequency vibration is generated through the collision vibration of the swing ring e1, and the high-frequency vibration acts on raw materials, so that the raw materials are mixed more fully.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. A raw material mixing device for biomass energy particle production structurally comprises a main body (1), a discharge pipe (2), a support ring (3), a mixing mechanism (4) and a feed pipe (5), wherein the outer wall of the rear end of the discharge pipe (2) is attached and fixed to the outer wall of the front part of the lower end of the main body (1), the outer wall of the lower end of the support ring (3) is welded and fixed to the outer wall of the upper end of the main body (1), the outer walls of the lower ends of the front side and the rear side of the mixing mechanism (4) are movably clamped on the outer wall of the upper end of the support ring (3), and the outer wall of the feed pipe (5) is movably matched with the inner wall of the main body (1);

mixing mechanism (4) comprises support frame (41), dwang (42), blender (43), support frame (41) rear end outer wall activity block is in support ring (3) front end outer wall, dwang (42) outer wall nested fit in support frame (41) central inner wall, blender (43) inner wall nested block is in dwang (42) rear end outer wall, blender (43) upper end outer wall movable fit is in pan feeding pipe (5) lower extreme outer wall, blender (43) outer wall movable fit is in main part (1) inner wall.

2. The raw material mixing apparatus for biomass energy particle production according to claim 1, wherein: mixer (43) comprise rabbling mechanism (a 1), screens ring (a 2), stirring piece (a 3), rabbling mechanism (a 1) inner wall nested card fits dwang (42) rear end outer wall, screens ring (a 2) inner wall nested card cooperates the askew coin of dwang (42) front end, the laminating of stirring piece (a 3) upper left end outer wall is fixed in rabbling mechanism (a 1) outer wall.

3. The raw material mixing apparatus for biomass energy particle production according to claim 2, characterized in that: rabbling mechanism (a 1) comprises stirring ring (b 1), drive pole (b 2), conduction mechanism (b 3), rotating ring (b 4), stirring ring (b 1) outer wall welded fastening is in stirring piece (a 3) inner wall, drive pole (b 2) outer wall laminating is fixed in stirring ring (b 1) inner wall, the nested joint of conduction mechanism (b 3) outer end inner wall is in driving pole (b 2) right side lower extreme outer wall, rotating ring (b 4) outer wall movable fit is in conduction mechanism (b 3) inner wall.

4. The raw material mixing apparatus for biomass energy particle production according to claim 3, wherein: conduction mechanism (b 3) comprises rotating ware (c 1), connecting rod (c 2), kelly (c 3), stiffener (c 4), rotation ware (c 1) inner wall nested fit cooperates the outer wall of cooperation mechanism (c 4), connecting rod (c 2) upper end rear side outer wall inlays solid block in rotating ware (c 1) front end inner wall, kelly (c 3) outer wall nested fit cooperates the inner wall in rotating ware (c 1), stiffener (c 4) rear end outer wall laminating is fixed in connecting rod (c 2) front end outer wall.

5. The raw material mixing apparatus for biomass energy particle production according to claim 4, wherein: the rotator (c 1) comprises a ring body (d 1), a friction ring (d 2), a vibration mechanism (d 3) and a matching ring (d 4), the inner wall of the ring body (d 1) is nested and clamped on the outer wall of the clamping rod (c 3), the outer wall of the friction ring (d 2) is in friction fit with the outer wall of the matching ring (d 4), the outer wall of the vibration mechanism (d 3) is nested and clamped on the inner wall of the friction ring (d 2), and the outer wall of the matching ring (d 4) is nested and fixed on the inner wall of the ring body (d 1).

6. The raw material mixing apparatus for biomass energy particle production according to claim 5, wherein: the vibration mechanism (d 3) is internally provided with a swing ring (e 1), a clamping and fixing rod (e 2) and an expansion mechanism (e 3), the outer wall of the swing ring (e 1) is embedded and clamped on the inner wall of the vibration mechanism (d 3), the outer wall of the clamping and fixing rod (e 2) is embedded and fixed on the outer walls of the two ends of the expansion mechanism (e 3), and the outer wall of the expansion mechanism (e 3) is movably matched with the inner wall of the friction ring (d 2).

7. The raw material mixing apparatus for biomass energy particle production according to claim 6, wherein: expanding mechanism (e 3) by shifter (f 1), locating rack (f 2), inlay connecting rod (f 3), position fixing frame (f 4) and constitute, the laminating of shifter (f 1) both ends outer wall is fixed in between position fixing frame (f 4), it is fixed in locating rack (f 2) center outer wall to inlay the nested of connecting rod (f 3) left side inner wall, the closed connecting rod (f 3) right side inner wall that is fixed in of position fixing frame (f 4) center outer wall, the nested joint in joint card is fixed in pole (e 2) outer wall about locating rack (f 2).

8. The raw material mixing apparatus for biomass energy particle production according to claim 7, wherein: mover (f 1) comprises magnetic frame (g 1), shell (g 2), gyration ring (g 3), expansion ring (g 4), location magnetic ring (g 5), magnetic frame (g 1) upper end outer wall friction fit expansion ring (g 4) outer wall, gyration ring (g 3) inner wall nestification is fixed in magnetic frame (g 1) outer wall, the laminating of expansion ring (g 4) outer wall is fixed in shell (g 2) inner wall, location magnetic ring (g 5) outer wall inlays solid block in shell (g 2) central inner wall, the laminating of shell (g 2) both ends outer wall is fixed in between solid position frame (f 4).