CN215864389U - Soybean meal feed drying device - Google Patents

Abstract

The utility model discloses a bean pulp feed drying device, which comprises: the stirring bin, the drying bin and the discharging bin; the stirring bin comprises a stirring mechanism and a reticular clapboard, and the stirring mechanism is arranged in the stirring bin; the reticular clapboard is fixedly arranged below the stirring mechanism; the drying bin comprises a first hot air port, a blanking plate, an air deflector and an air exhaust port, wherein the blanking plate and the air deflector are respectively arranged on two opposite side surfaces in the drying bin; the first hot air port is positioned above the blanking plate and exhausts air towards the air deflector; the exhaust port is positioned above the air deflector; the discharging bin comprises a discharging channel and a second hot air port, a feeding port of the discharging channel is communicated with a blanking port, and the inner wall of the discharging channel protrudes outwards to form a plurality of turbulence parts; the second hot air port introduces hot air to the feed inlet of the discharge channel. The utility model is used for discharging the moisture and the dust out of the drying bin through the exhaust port.

Description

Soybean meal feed drying device

Technical Field

The utility model relates to the technical field of bean pulp drying, in particular to a bean pulp feed drying device.

Background

The soybean meal has high protein content and is a main raw material for preparing livestock and poultry feed. In order to facilitate preservation of the soybean meal, a drying device is generally used to reduce the amount of water containing the soybean meal. In the traditional method, drying air is directly introduced into the device, and because a large amount of bean pulp is mutually bonded, the contact area between the heat source drying air and the bean pulp is relatively small, and the drying efficiency is poor.

In order to solve the problems, the Chinese invention patent with the publication number of CN113074537A discloses a feed bean pulp drying device, which mainly comprises the following technical points: hot air blown out from the first air inlet on the upper side of the blanking plate can play a drying role and can push bean pulp to slide on the blanking plate, so that the bean pulp is prevented from being accumulated, and the use of a motor is reduced; the bean pulp rolls when sliding on the blanking plate, so that the bean pulp is dried in multiple angles; the bean pulp falls down for many times to play a role of turning over materials, so that each part of the bean pulp can be uniformly dried.

At least the following disadvantages are associated with the prior art described above: 1. when the bean pulp is dried, a large amount of moisture evaporated by the bean pulp is gathered in the drying device and cannot be discharged, and a large amount of dust can be raised when the bean pulp slides for multiple times; 2. the hot air angle that first air intake blew out is single, to the soybean meal fodder that bonds each other, need arrange a plurality of air intakes and just can reach abundant dry effect.

SUMMERY OF THE UTILITY MODEL

In view of this, a need exists for a bean pulp feed drying device, which solves the technical problems of single hot air angle, poor drying effect and incapability of discharging moisture and dust in the prior art.

In order to achieve the technical purpose, the technical scheme of the utility model provides a bean pulp feed drying device, which comprises: the stirring bin, the drying bin and the discharging bin; the stirring bin comprises a stirring mechanism and a reticular clapboard, and the stirring mechanism is arranged in the stirring bin and is used for stirring the soybean meal feed; the reticular clapboard is fixedly arranged below the stirring mechanism; the drying bin comprises a first hot air port, a blanking plate, an air deflector and an air exhaust port, wherein the blanking plate and the air deflector are respectively arranged on two opposite side surfaces in the drying bin, the blanking plate is arranged in a downward inclined mode, the air deflector is arranged in an upward inclined mode, and the blanking plate and the air deflector are enclosed to form the blanking port; the first hot air port is positioned above the blanking plate and exhausts air towards the air deflector; the exhaust port is positioned above the air deflector and used for pumping out water vapor; the discharging bin comprises a discharging channel and a second hot air port, a feeding port of the discharging channel is communicated with the blanking port, and the inner wall of the discharging channel protrudes outwards to form a plurality of turbulence parts; the second hot air port is formed in the inner wall of the discharging bin and introduces hot air to the feeding hole of the discharging channel.

Further, rabbling mechanism includes motor, (mixing) shaft and stirring leaf, the motor install in on the stirring storehouse, the motor with the (mixing) shaft transmission is connected, in order to be used for the drive the (mixing) shaft is rotatory, a plurality of stirring leaf has crisscross connection from top to bottom to the (mixing) shaft.

Furthermore, a plurality of strip-shaped through holes are uniformly formed in the stirring blade.

Furthermore, the stirring bin is provided with a stirring bin cover which is detachably connected, and the motor is installed on the stirring bin cover.

Further, the reticular clapboard is obliquely arranged below the stirring mechanism.

Furthermore, a filter screen is arranged on the exhaust port.

Further, the exhaust port is connected with an air pump.

Furthermore, the first hot air port and the second hot air port are connected with an air heater.

Furthermore, a plurality of the burbling parts are respectively arranged above and below the discharging channel in a staggered way.

Furthermore, the turbulence part positioned above the discharging channel is provided with a downward inclined surface, and the turbulence part below the discharging channel is provided with an upward inclined surface.

Compared with the prior art, the utility model has the beneficial effects that:

1. the stirring mechanism is arranged in the stirring bin and is used for stirring the soybean meal feed; through the arrangement mode, the stirring mechanism uniformly stirs the bean pulp feed, so that the bean pulp feed cannot be bonded with each other, and the subsequent drying operation can be conveniently carried out.

2. The blanking plate is arranged in a downward inclined mode, the air guide plate is arranged in an upward inclined mode, the first hot air opening is located above the blanking plate and is used for exhausting air towards the air guide plate, and the air exhaust opening is located above the air guide plate; through above-mentioned mode of setting up, the aviation baffle is used for changing hot-blast flow direction to make the dregs of beans fodder obtain bigger space of raising, and then have bigger contact surface with steam, the gas vent is used for discharging aqueous vapor and dust dry storehouse.

3. The second hot air port is formed in the inner wall of the discharging bin and introduces hot air to the feeding hole of the discharging channel, and the inner wall of the discharging channel protrudes outwards to form a plurality of turbulence parts; through the arrangement mode, the bean pulp feed is wrapped by hot air and moves among the plurality of turbulence parts, so that the effect of sufficient drying is realized.

Drawings

Fig. 1 is a first schematic structural diagram of a soybean meal feed drying device according to an embodiment of the utility model;

fig. 2 is a schematic structural diagram ii of a soybean meal feed drying device according to an embodiment of the present invention;

in the figure: 1. the stirring device comprises a stirring bin, 11 stirring mechanisms, 111 motors, 112 stirring shafts, 113 stirring blades, 2 drying bins, 21 first hot air ports, 22 blanking plates, 23 air guide plates, 24 exhaust ports, 25 blanking auxiliary plates, 26 air guide auxiliary plates, 27 third hot air ports, 28 auxiliary exhaust ports, 2a discharge ports, 2b first blanking gaps, 2c second blanking gaps, 3 discharge bins, 31 discharge channels, 311, a flow disturbing part and 32 second hot air ports.

Detailed Description

The following detailed description of the preferred embodiments of the present invention/utility model, taken in conjunction with the accompanying drawings, forms a part of this application and together with the embodiments of the utility model/utility model, serve to explain the principles of the utility model/utility model and are not intended to limit the scope of the utility model/utility model.

As shown in fig. 1, the present invention provides a soybean meal feed drying device, comprising: stirring storehouse 1, dry storehouse 2 and play feed bin 3.

The stirring bin 1 comprises a stirring mechanism 11 and a mesh-shaped partition plate 12, wherein the stirring mechanism 11 is arranged in the stirring bin 1 and is used for stirring the soybean meal feed; the mesh partition plate 12 is fixedly arranged below the stirring mechanism 11.

The drying bin 2 comprises a first hot air port 21, a blanking plate 22, an air deflector 23 and an air exhaust port 24, wherein the blanking plate 22 and the air deflector 23 are respectively installed on two opposite side surfaces in the drying bin 2, the blanking plate 22 is arranged in a downward inclined mode, the air deflector 23 is arranged in an upward inclined mode, and a blanking port 2a is formed by enclosing the blanking plate 22 and the air deflector 23; the first hot air port 21 is located above the blanking plate 22 and exhausts air towards the air deflector 23; the exhaust port 24 is located above the air guide plate 23 for exhausting moisture.

The discharging bin 3 comprises a discharging channel 31 and a second hot air port 32, a feeding port of the discharging channel 31 is communicated with the blanking port 2a, and the inner wall of the discharging channel 31 protrudes outwards to form a plurality of turbulence portions 311; the second hot air port 32 is arranged on the inner wall of the discharging bin 3 and introduces hot air to the feeding hole of the discharging channel 31.

In this embodiment, the stirring mechanism 11 uniformly stirs the bean pulp feed in the inner cavity of the stirring bin 1, so that the bean pulp feed is not bonded with each other, and the bean pulp feed falls into the drying bin 2 through the meshes of the mesh-shaped partition plate 12; the first hot air port 21 is used for exhausting air towards the air deflector 23, the air deflector 23 is used for changing the flow direction of hot air, so that the soybean meal feed can obtain a larger upward space and further has a larger contact surface with hot air, and in the process, the evaporated water and the carried dust are separated from the soybean meal feed and are exhausted out of the drying bin 2 through the exhaust port 24; then, the bean pulp feed falls into the discharging bin 3 from the discharging port 2a, hot air is introduced into the discharging channel 31 through the second hot air port 32, and the bean pulp feed is wrapped by the hot air and moves among the plurality of turbulent flow portions 311 until being ejected from the discharging port of the discharging channel 31.

Wherein, one end of the reticular clapboard 12 close to the first hot air port 21 is inclined downwards, and the meshes of the reticular clapboard 12 are uniformly distributed at one end of the reticular clapboard 12 close to the first hot air port 21.

In this embodiment, the parallel hot air guided out by the first hot air port 21 is blocked by the air deflector 23, and then flows upward to raise the bean pulp feed, and the upward hot air is blocked by the mesh partition 12, and then flows downward, and simultaneously joins with the parallel hot air to continuously empty the bean pulp feed.

As shown in fig. 2, in addition, the number of the drying bins 2 may be set according to the actual drying requirement, for example, the number of the drying bins 2 is two, and the first drying bin 2 is surrounded by the mesh partition plate 12, the blanking plate 22 and the air deflector 23; the second drying chamber 2 comprises a blanking auxiliary plate 25, an air guide auxiliary plate 26, a third hot air port 37 and an auxiliary air outlet 38, and is formed by surrounding the blanking plate 22, the blanking auxiliary plate 25 and the air guide auxiliary plate 26.

Specifically, two opposite side surfaces in the second drying bin 2 are respectively provided with a blanking auxiliary plate 25 and an air guide auxiliary plate 26, the air guide auxiliary plate 26 is arranged in an upward inclined manner, and the blanking auxiliary plate 25 is arranged in a downward inclined manner and is surrounded with the blanking plate 22 to form a first blanking gap 2 b; the third hot air port 37 is located at the first blanking gap 2b and exhausts air towards the air guiding auxiliary plate 26; the auxiliary exhaust port 38 is positioned above the air guide auxiliary plate 26 and used for extracting moisture; the air guide auxiliary plate 26 and the blanking auxiliary plate 25 surround to form a second blanking gap 2 c.

Further, the stirring mechanism 11 includes a motor 111, a stirring shaft 112 and stirring blades 113, the motor 111 is mounted on the stirring bin 1, the motor 111 is in transmission connection with the stirring shaft 112 to drive the stirring shaft 112 to rotate, and the stirring shaft 112 is vertically connected with a plurality of stirring blades 113 in a staggered manner; and a plurality of strip-shaped through holes are uniformly formed in the stirring blade 113.

In this embodiment, the structure of the stirring mechanism 11 is further limited, and a design manner that the stirring blades 113 are vertically installed on the stirring shaft 112 in a staggered manner and the stirring blades 113 are provided with strip-shaped through holes is adopted to increase the contact area between the stirring blades 113 and the soybean meal feed, so that the soybean meal feed is uniformly stirred.

Further, the plurality of turbulence portions 311 are respectively arranged above and below the discharging channel 31 in a staggered manner; the turbulent portion 311 above the discharging channel 31 has a downward inclined surface, and the turbulent portion 311 below the discharging channel 31 has an upward inclined surface.

In this embodiment, the structure of the turbulence portion 311 is further limited, wherein the upper turbulence portion 311 has a downward inclined surface, the lower turbulence portion 311 has an upward inclined surface, and the upper turbulence portion 311 and the lower turbulence portion 311 are respectively disposed in a staggered manner, so that the soybean meal feed collides between the upper turbulence portion 311 and the lower turbulence portion 311 to obtain a larger contact area with hot air.

Firstly, uniformly stirring the bean pulp feed in the inner cavity of the stirring bin 1 by the stirring mechanism 11, so that the bean pulp feed cannot be bonded with each other, and the bean pulp feed can fall into the drying bin 2 through meshes on the mesh-shaped partition plate 12, wherein the design mode that the stirring blades 113 are vertically and alternately arranged on the stirring shaft 112 and strip-shaped through holes are formed in the stirring blades 113 is adopted, so that the contact area between the stirring blades 113 and the bean pulp feed is increased, and the bean pulp feed is uniformly stirred; secondly, the first hot air port 21 exhausts air towards the air deflector 23, the air deflector 23 is used for changing the flow direction of hot air, so that the soybean meal feed obtains a larger upward space and further has a larger contact surface with hot air, and in the process, the evaporated water and the carried dust are separated from the soybean meal feed and are exhausted out of the drying bin 2 through the exhaust port 24; finally, the bean pulp feed falls into the discharging bin 3 from the discharging port 2a, hot air is introduced into the discharging channel 31 through the second hot air port 32, the bean pulp feed is wrapped by the hot air and moves among the turbulence portions 311 until being sprayed out from the discharging port of the discharging channel 31, wherein the turbulence portion 311 above has a downward inclined surface, the turbulence portion 311 below has an upward inclined surface, the turbulence portions 311 above and 311 below are respectively arranged in a staggered manner, and the mode is adopted to enable the bean pulp feed to collide between the turbulence portions 311 above and 311 below so as to obtain a larger contact area with the hot air.

The entire workflow is completed and the details not described in detail in this specification are well within the skill of those in the art.

The above description is only a preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention/utility model should be covered within the protection scope of the present invention/utility model.

Claims (10)

1. A soybean meal feed drying device, which is characterized by comprising: the stirring bin, the drying bin and the discharging bin;

the stirring bin comprises a stirring mechanism and a reticular clapboard, and the stirring mechanism is arranged in the stirring bin and is used for stirring the soybean meal feed; the reticular clapboard is fixedly arranged below the stirring mechanism;

the drying bin comprises a first hot air port, a blanking plate, an air deflector and an air exhaust port, wherein the blanking plate and the air deflector are respectively arranged on two opposite side surfaces in the drying bin, the blanking plate is arranged in a downward inclined mode, the air deflector is arranged in an upward inclined mode, and the blanking plate and the air deflector are enclosed to form the blanking port; the first hot air port is positioned above the blanking plate and exhausts air towards the air deflector; the exhaust port is positioned above the air deflector and used for pumping out water vapor;

the discharging bin comprises a discharging channel and a second hot air port, a feeding port of the discharging channel is communicated with the blanking port, and the inner wall of the discharging channel protrudes outwards to form a plurality of turbulence parts; the second hot air port is formed in the inner wall of the discharging bin and introduces hot air to the feeding hole of the discharging channel.

2. The soybean meal feed drying device according to claim 1, wherein the stirring mechanism comprises a motor, a stirring shaft and stirring blades, the motor is installed on the stirring bin, the motor is in transmission connection with the stirring shaft and used for driving the stirring shaft to rotate, and the stirring shaft is vertically and alternately connected with the stirring blades.

3. The bean pulp feed drying device of claim 2, wherein the stirring blade is uniformly provided with a plurality of strip-shaped through holes.

4. The soybean meal feed drying device of claim 3, wherein the stirring bin is provided with a stirring bin cover detachably connected, and the motor is mounted on the stirring bin cover.

5. The bean pulp feed drying device of claim 1, wherein one end of the mesh-shaped partition board close to the first hot air port is inclined downwards, and the meshes of the mesh-shaped partition board are uniformly arranged at one end of the mesh-shaped partition board close to the first hot air port.

6. The soybean meal feed drying device of claim 1, wherein a filter screen is installed on the air outlet.

7. The soybean meal feed drying device according to claim 6, wherein the air exhaust port is connected with an air pump.

8. The bean pulp feed drying device of claim 1, wherein the first hot air port and the second hot air port are connected with a hot air blower.

9. The soybean meal feed drying device of claim 1, wherein the plurality of flow disturbing portions are respectively staggered above and below the discharge channel.

10. The soybean meal feed drying device of claim 9, wherein the flow disturbing portion located above the discharge channel has a downward inclined surface, and the flow disturbing portion below the discharge channel has an upward inclined surface.

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