CN113654327A - Biological particle raw material drying device - Google Patents

Abstract

The invention discloses a drying device for biological particle raw materials, which comprises a drying box body, a feeding groove and a bearing screen plate piece, wherein the drying box body is provided with a feeding groove; the supporting net plate is flexible, and two opposite sides of the supporting net plate are provided with side baffles; the drying box is characterized by further comprising an air dispelling component, a driving and dispersing component and an electric heating rod, wherein the driving and dispersing component is arranged in the drying box body and located between the feeding groove and the bearing screen plate, the driving and dispersing component is connected with the two side baffles and is used for intermittently driving the two side baffles to move towards each other at the same time and disperse surrounding raw materials through the material stirring part of the side baffles, and the electric heating rod is arranged on the driving and dispersing component and dissipates heat to the periphery through the material stirring part of the electric heating rod; the wind dispelling assembly is arranged on the outer wall of the drying box body and is used for spraying airflow into the drying box body through the two side baffles. The device forms the material of throwing to the drying of STREAMING through constantly changing space and throwing the material, and the air current fully contacts with the material, improves drying effect.

Description

Biological particle raw material drying device

Technical Field

The invention relates to the technical field of biological material treatment, in particular to a drying device for biological particle raw materials.

Background

Research and development of a biological energy technology become one of the world major hot topics, and attention of governments and scientists of various countries and countries in the world is paid, so that the biological particles are formed by performing cold compact forming on crushed biomass straws, forestry waste and other raw materials by using a compression roller and a ring die at normal temperature, the storage and transportation are convenient, the combustion performance of biomass is greatly improved, the research and development of the biological energy technology become one of the world major hot topics, and the biomass fuel is biomass material combustion as fuel.

Some biomass materials are prepared into various shapes and then stored after being crushed, mixed, extruded, dried and the like; but needs to be dried before storage; the existing biological particle material drying is that the biological particle raw material is directly placed on a tray and is dried in a heating air box or the biological base material is turned over in the heating air box in a reciprocating way; however, both of the two methods adopted by the drying device can not ensure that the raw material of the biological particles is fully contacted with the air flow to influence the drying effect.

Disclosure of Invention

The invention aims to provide a drying device for biological particle raw materials, which solves the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

a biological particle raw material drying device comprises a drying box body, a feeding groove and a supporting screen plate, wherein the feeding groove is arranged at the top end part of the drying box body, and the supporting screen plate is arranged in the drying box body and used for supporting a raw material; the supporting net plate is flexible, two opposite sides of the supporting net plate are provided with side baffles, and the end parts of the side baffles are arranged in the drying box body through elastic reset guide assemblies; the drying box is characterized by further comprising an air dispelling component, a driving and dispersing component and an electric heating rod, wherein the driving and dispersing component is arranged in the drying box body and located between the feeding groove and the bearing screen plate, the driving and dispersing component is connected with the two side baffles and is used for intermittently driving the two side baffles to move towards each other at the same time and disperse surrounding raw materials through the material stirring part of the side baffles, the electric heating rod is arranged on the driving and dispersing component, and the electric heating rod is arranged on the driving and dispersing component and heats the material stirring part of the driving and dispersing component; the air driving assembly is arranged on the outer wall of the drying box body and is used for spraying airflow into the drying box body through the two side baffles; elasticity reset guide subassembly can be dialled the subassembly and stop driving the side shield and remove when moving the side shield fast and order about the side shield to dry box lateral part removal.

On the basis of the technical scheme, the invention also provides the following optional technical scheme:

in one alternative: the elastic reset guide assembly comprises a support guide rod, a guide sleeve and an elastic piece, the support guide rod is transversely fixed inside the drying box body, the guide sleeve is arranged on the support guide rod in a sliding mode and fixedly connected with the bottom of the side baffle, and the elastic piece is arranged between the guide sleeve and the side wall of the drying box body and is connected with the guide sleeve and the side wall of the drying box body at the end portion.

In one alternative: the driving and stirring assembly comprises a rotating rod shaft, an incomplete gear, two fixed racks and a plurality of groups of stirring plates, wherein the rotating rod shaft is rotatably arranged in the drying box body and is driven to rotate by a power part arranged on the outer wall of the drying box body; the incomplete gear is arranged at the end part of the rotating rod and is intermittently meshed with the two fixed racks, and the two fixed racks are respectively arranged on the two side baffles; the kickoff plate is established on the outer wall of rotatory pole axle and can dial scattered material while to the heat dissipation all around.

In one alternative: the rotating rod shaft is hollow, and the electric heating rod is arranged inside the rotating rod shaft.

In one alternative: the air driving assembly comprises an air outlet plate, a telescopic air duct and a diversion fan, the diversion fan is arranged on the outer wall of the drying box body, the air outlet plate is arranged on the side baffle plate, a plurality of air injection holes are formed in the surface of the air outlet plate, and the air outlet end of the diversion fan is communicated with the air outlet plate through the telescopic air duct.

In one alternative: and a blanking port is formed in the middle of the supporting mesh plate.

In one alternative: the drying box body is also internally provided with a material guiding screen plate positioned on the lower side of the supporting screen plate part, and the middle part of the material guiding screen plate is arched upwards; the bottom of the drying box body is provided with a lower air heater, and the side wall of the drying box body is provided with a discharge hole positioned at the side part of the material guide screen plate.

In one alternative: the device still includes and removes the stirring subassembly, removes the stirring subassembly and is two and establish respectively in the bottom of side shield, remove the stirring subassembly and can move and spread to the material on the guide otter board along with removing the stirring subassembly.

In one alternative: the movable material turning assembly comprises an installation plate and a plurality of convex rods, the installation plate is arranged at the bottom of the side baffle and provided with a plurality of guide grooves towards the side edge of the material guide screen plate, and the plurality of convex rods are correspondingly inserted into the inner parts of the guide grooves and the end parts of the convex rods inserted into the guide grooves are connected with the end walls of the inner cavities of the guide grooves through elastic pieces.

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

the device drives the scattering component to intermittently drive the two side baffles to move in opposite directions, the supporting screen plate piece is tightened and sunken, when the scattering component is driven to stop driving the two side baffles to move in opposite directions, the two side baffles move in opposite directions rapidly under the action of resilience force of the elastic reset guide component, and the supporting screen plate piece directly throws raw materials on the supporting screen plate piece upwards due to rapid expansion; the raw materials of throwing can be dialled the material part effect of loosing under the drive and scatter the subassembly and scatter to and the electric heating stick heating makes raw materials surrounding air heating with utilizing to dial the material part, makes raw materials moisture evaporation and drying, and the subassembly that dispels the wind is by the relative efflux of two side shields and form the convection current, makes air current and raw materials fully contact, obviously improves the drying effect of raw materials. The device forms the material of throwing to the drying of STREAMING through constantly changing space and throwing the material, and the air current fully contacts with the material, improves drying effect.

Drawings

Fig. 1 is a schematic view of the overall structure of the device in one embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a driving dispersion assembly according to an embodiment of the present invention.

Fig. 3 is a schematic structural view of a moving upender assembly in an embodiment of the present invention.

Notations for reference numerals: the device comprises a drying box body 1, a feeding chute 2, a supporting net plate 3, a side baffle 4, an elastic reset guide assembly 5, a supporting guide rod 51, a guide sleeve 52, an elastic piece 53, a driving dispersion assembly 6, a rotating rod shaft 61, an incomplete gear 62, a fixed rack 63, a material stirring plate 64, an electric heating rod 7, an air driving assembly 8, an air outlet plate 81, a telescopic air guide pipe 82, a flow guide fan 83, a discharging port 9, a material guide net plate 10, a lower hot air fan 11, a movable material stirring assembly 12, an installation plate 121, a convex rod 122, a guide groove 123 and an elastic piece 124.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments; in the drawings or the description, the same reference numerals are used for similar or identical parts, and the shape, thickness or height of each part may be enlarged or reduced in practical use. The examples are given solely for the purpose of illustration and are not intended to limit the scope of the invention. Any obvious modifications or variations can be made to the present invention without departing from the spirit or scope of the present invention.

In one embodiment, as shown in fig. 1 and 2, a drying apparatus for raw material of biological particles comprises a drying box 1, a feeding chute 2 and a supporting screen member 3, wherein the feeding chute 2 is arranged at the top end part of the drying box 1, and the supporting screen member 3 is arranged inside the drying box 1 and is used for supporting the raw material; the supporting net plate 3 is flexible, two opposite sides of the supporting net plate are provided with side baffles 4, and the end parts of the side baffles 4 are arranged in the drying box body 1 through elastic reset guide components 5; the drying box is characterized by further comprising an air dispelling component 8, a driving and dispersing component 6 and an electric heating rod 7, wherein the driving and dispersing component 6 is arranged inside the drying box body 1 and located between the feeding chute 2 and the bearing screen plate 3, the driving and dispersing component 6 is connected with the two side baffles 4 and is used for intermittently driving the two side baffles 4 to move towards each other at the same time and disperse surrounding raw materials through the material stirring part of the side baffles 4, the electric heating rod 7 is arranged on the driving and dispersing component 6, and the electric heating rod 7 is arranged on the driving and dispersing component 6 and heats the material stirring part of the driving and dispersing component 6; the wind dispelling assembly 8 is arranged on the outer wall of the drying box body 1 and is used for spraying airflow into the drying box body 1 through the two side baffles 4; the elastic reset guide assembly 5 can rapidly drive the side baffle 4 to move towards the side part of the drying box body 1 when the driving dispersion assembly 6 stops driving the side baffle 4 to move;

in the implementation process of the embodiment, biological particle raw materials are introduced into the drying box body 1 through the feeding chute 2 and fall on the supporting net plate 3, the driving dispersion assembly 6 intermittently drives the two side baffles 4 to move oppositely, the supporting net plate 3 is tightened and sunken, when the driving dispersion assembly 6 stops driving the two side baffles 4 to move oppositely, the two side baffles 4 rapidly move in opposite directions under the effect of resilience force of the elastic reset guide assembly 5, and the supporting net plate 3 directly throws the raw materials on the supporting net plate upwards due to rapid expansion; the upward thrown raw materials are scattered under the action of the material stirring part of the material stirring component 6, the electric heating rod 7 is used for heating and the material stirring part is used for heating air around the raw materials, so that the moisture of the raw materials is evaporated and dried, the wind dispelling component 8 is formed by opposite jet flows of the two side baffles 4 to form convection, so that the airflow is fully contacted with the raw materials, and the drying effect of the raw materials is obviously improved; the drying efficiency can be improved by the reciprocating operation; as an embodiment, the left, right, up and down positions of the components shown in the drawings are only one arrangement, and the specific positions are set according to specific requirements; wherein, the supporting screen plate 3 is a plate material woven by steel wires;

in one embodiment, as shown in fig. 1, the elastic reset guide assembly 5 includes a support guide 51, a guide sleeve 52 and an elastic member 53, the support guide 51 is transversely fixed inside the drying cabinet 1, the guide sleeve 52 is slidably disposed on the support guide 51 and fixedly connected to the bottom of the side baffle 4, and the elastic member 53 is disposed between the guide sleeve 52 and the side wall of the drying cabinet 1 and has an end connected to both; the guide sleeve 52 slides on the support guide rod 51 to guide the movement of the side baffle 4, and when the side baffle 4 is not driven by the driving dispersion assembly 6 to move, the contraction elastic force of the support guide rod 51 can quickly pull the side baffle 4 to move towards the side wall of the drying box 1; wherein, the support guide rod 51 is a spring or an arch rod;

the elastic reset guide assembly 5 can be a guide groove formed in the side wall of the drying box body 1 and a slider fixed on the side part of the side baffle 4 besides the structure disclosed in the above embodiment, and the side part of the side baffle 4 is connected with the side wall of the drying box body 1 through an elastic part 53;

in one embodiment, as shown in fig. 1 and 2, the driving scattering assembly 6 comprises a rotating rod shaft 61, an incomplete gear 62, two fixed racks 63 and a plurality of groups of material stirring plates 64, wherein the rotating rod shaft 61 is rotatably arranged inside the drying box body 1 and is driven to rotate by a power piece arranged on the outer wall of the drying box body 1; the incomplete gear 62 is arranged at the end part of the rotating rod shaft 61 and is intermittently meshed with two fixed racks 63, and the two fixed racks 63 are respectively arranged on the two side baffles 4; the material stirring plate 64 is arranged on the outer wall of the rotating rod shaft 61 and can stir and disperse materials and radiate the materials to the periphery; the power member drives the rotating shaft 61 to rotate, and the rotating shaft 61 rotates to enable the two side baffles 4 to approach each other when the incomplete gear 62 and the fixed gear rack 63 are meshed; the rotating rod shaft 61 also drives the material stirring plate 64 to rotate, stir and disperse the materials thrown up by the bearing net plate 3 and radiate the materials to the periphery, so that hot air flow is fully contacted with the materials, and the drying effect is improved; wherein, the power part is a motor or a pneumatic motor;

the driving dispersion component 6 can be a double-end screw rod driven by a motor besides the structure disclosed in the embodiment, the end part of the double-end screw rod spirally penetrates through the two side baffles 4, and the middle part of the double-end screw rod is provided with a rotary dispersion piece;

in one embodiment, as shown in fig. 2, the rotating shaft 61 is hollow, and the electric heating rod 7 is disposed inside the rotating shaft 61, so as to heat the rotating shaft 61 and the material-stirring plate 64;

in one embodiment, as shown in fig. 1, the air driving assembly 8 includes an air outlet plate 81, a telescopic air duct 82 and a guiding fan 83, the guiding fan 83 is disposed on the outer wall of the drying cabinet 1, the air outlet plate 81 is disposed on the side baffle 4, a plurality of air injection holes are formed on the surface of the air outlet plate, and an air outlet end of the guiding fan 83 is communicated with the air outlet plate 81 through the telescopic air duct 82; the diversion fan 83 guides the external air flow into the air outlet plate 81 through the telescopic air duct 82, the air outlet plate 81 sprays the air flow into the drying box body 1 through the air spraying holes, and the air outlet plate 81 can move along with the side baffle 4 due to the flexibility of the telescopic air duct 82; the full contact between the airflow and the materials is improved;

in one embodiment, as shown in fig. 1, a blanking port 71 is formed in the middle of the supporting mesh plate 3, and the blanking port 71 is arranged to facilitate the falling of the dried material when the supporting mesh plate is opened;

in one embodiment, as shown in fig. 1, a material guiding mesh plate 10 located at the lower side of the supporting mesh plate 3 is further disposed in the drying box 1, and the material guiding mesh plate 10 has a structure with an upward arched middle; the bottom of the drying box body 1 is provided with a lower air heater 11, and the side wall of the drying box body 1 is provided with a discharge hole 9 positioned at the side part of the material guiding screen plate 10; the material falling from the electric heating rod 7 falls on the material guiding screen plate 10, and the material slides to two sides because the middle part of the material guiding screen plate 10 is arched upwards and is discharged through the discharge hole 9, and when the material slides, the hot air flow is blown into the material by the lower hot air fan 11 to further dry the material; wherein, the material guiding screen plate 10 is an inclined plate with a plurality of air holes on the plate body;

in one embodiment, as shown in fig. 1, the device further comprises two moving stirring assemblies 12, wherein the two moving stirring assemblies 12 are respectively arranged at the bottom of the side baffle 4, and the moving stirring assemblies 12 can move along with the moving stirring assemblies 12 and scatter materials on the material guiding screen plate 10; the materials on the material guide screen plate 10 can be scattered by the movable material stirring assembly 12 and can be further dried by matching with the lower hot air blower 11;

in one embodiment, as shown in fig. 3, the moving stirring assembly 12 includes a mounting plate 121 and a plurality of protruding rods 122, the mounting plate 121 is disposed at the bottom of the side baffle 4 and opens a plurality of guide slots 123 towards the side portions of the material guiding net plate 10, the plurality of protruding rods 122 are correspondingly inserted into the guide slots 123, and the ends of the protruding rods 122 inserted into the guide slots 123 are connected with the inner cavity end walls of the guide slots 123 through elastic members 124; when the mounting plate member 121 moves along with the side baffle 4, a plurality of materials on the material guiding screen plate 10 are scattered, and the convex rod 122 can extend and retract in the guide groove 123 due to the elasticity of the elastic member 124, so that the material guiding screen plate can adapt to the arched tilting of the material guiding screen plate 10; the elastic member 124 is a spring or a spring plate;

the embodiment discloses a biological particle raw material drying device, wherein a biological particle raw material is guided into a drying box body 1 through a feeding chute 2 and falls on a supporting net plate 3, a driving dispersion component 6 intermittently drives two side baffles 4 to move oppositely, the supporting net plate 3 is tightened and sunken, when the driving dispersion component 6 stops driving the two side baffles 4 to move oppositely, the two side baffles 4 rapidly move in opposite directions under the action of resilience force of an elastic reset guide component 5, and the supporting net plate 3 directly throws the raw material on the supporting net plate upwards due to rapid expansion; the upward thrown raw materials are scattered under the action of the material stirring part of the material stirring component 6, the electric heating rod 7 is used for heating and the material stirring part is used for heating air around the raw materials, so that the moisture of the raw materials is evaporated and dried, the wind dispelling component 8 is formed by opposite jet flows of the two side baffles 4 to form convection, so that the airflow is fully contacted with the raw materials, and the drying effect of the raw materials is obviously improved; the reciprocating operation can improve the drying efficiency.

The above description is only for the specific embodiments of the present disclosure, but the scope of the present disclosure is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present disclosure, and all the changes or substitutions should be covered within the scope of the present disclosure. Therefore, the protection scope of the present disclosure shall be subject to the protection scope of the claims.

Claims (9)

1. A biological particle raw material drying device comprises a drying box body, a feeding groove and a supporting screen plate, wherein the feeding groove is arranged at the top end part of the drying box body, and the supporting screen plate is arranged in the drying box body and used for supporting a raw material; the drying box is characterized in that the supporting screen plate piece is flexible, two opposite sides of the supporting screen plate piece are respectively provided with a side baffle, and the end part of each side baffle is arranged in the drying box body through an elastic reset guide component;

the device also comprises a wind dispelling component, a driving and dispersing component and an electric heating rod;

the driving scattering component is arranged in the drying box body and is positioned between the feeding groove and the bearing screen plate piece;

the driving dispersing assembly is connected with the two side baffles and is used for intermittently driving the two side baffles to move towards each other at the same time and dispersing surrounding raw materials through the material dispersing part of the side baffles;

the electric heating rod is arranged on the driving dispersion component and heats the material stirring part of the driving dispersion component;

the air driving assembly is arranged on the outer wall of the drying box body and is used for spraying airflow into the drying box body through the two side baffles;

elasticity reset guide subassembly can be dialled the subassembly and stop driving the side shield and remove when moving the side shield fast and order about the side shield to dry box lateral part removal.

2. The raw biological particle material drying apparatus as set forth in claim 1, wherein the elastic return guide assembly includes a support guide, a guide sleeve and an elastic member;

the supporting guide rod is transversely fixed in the drying box body;

the guide sleeve is arranged on the support guide rod in a sliding manner and is fixedly connected with the bottom of the side baffle;

the elastic piece is arranged between the guide sleeve and the side wall of the drying box body, and the end part of the elastic piece is connected with the guide sleeve and the side wall of the drying box body.

3. The biological granular raw material drying apparatus as set forth in claim 1, wherein the driving scattering assembly includes a rotary rod shaft, an incomplete gear, two fixed racks and a plurality of groups of stirring plates;

the rotating rod shaft is rotatably arranged in the drying box body and is driven to rotate by a power piece arranged on the outer wall of the drying box body;

the incomplete gear is arranged at the end part of the rotating rod and is intermittently meshed with the two fixed racks, and the two fixed racks are respectively arranged on the two side baffles;

the kickoff plate is established on the outer wall of rotatory pole axle and can dial scattered material while to the heat dissipation all around.

4. The drying apparatus for raw material for biological particles as set forth in claim 3, wherein the rotary shaft is hollow and the electric heating rod is provided inside the rotary shaft.

5. The raw biological particle material drying device as claimed in claim 1, wherein the air driving assembly comprises an air outlet plate, a telescopic air duct and a flow guiding fan;

the flow guide fan is arranged on the outer wall of the drying box body, the air outlet plate is arranged on the side baffle, and a plurality of air injection holes are formed in the plate surface;

the air outlet end of the diversion fan is communicated with the air outlet plate through a telescopic air duct.

6. The apparatus for drying raw material of biological particles as set forth in claim 1, wherein a blanking port is opened at a central portion of the supporting mesh member.

7. The raw material drying device for biological particles as claimed in claim 6, wherein a material guiding screen plate is arranged in the drying box body and positioned on the lower side of the supporting screen plate, and the middle of the material guiding screen plate is in an upward arched structure;

the bottom of the drying box body is provided with a lower air heater, and the side wall of the drying box body is provided with a discharge hole positioned at the side part of the material guide screen plate.

8. The apparatus as claimed in claim 7, further comprising two movable stirring assemblies respectively disposed at the bottom of the side shield, wherein the movable stirring assemblies can move along with the movable stirring assemblies and scatter the material on the material guiding screen.

9. The raw bio-particulate material drying apparatus according to claim 8, wherein the moving upender assembly includes a mounting plate and a plurality of protruding rods;

the mounting plate is arranged at the bottom of the side baffle and provided with a plurality of guide grooves facing the side part of the material guide screen plate;

the plurality of convex rods are correspondingly inserted into the guide grooves, and the end parts of the convex rods inserted into the guide grooves are connected with the end walls of the inner cavities of the guide grooves through elastic pieces.

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