Anti-splashing drying equipment for snake slough powder processing

By using heat-insulating pads to separate the heating space and an automated loading and unloading mechanism in the drying equipment, the problem of splashing during the drying process of snake slough powder was solved, and efficient and continuous automated operation was achieved.

CN116576646BActive Publication Date: 2026-06-23GUANGDONG MINGCHENTANG HEALTH IND SHARES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
GUANGDONG MINGCHENTANG HEALTH IND SHARES CO LTD
Filing Date
2023-05-25
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing drying equipment is prone to particle breakage, cracking, and splashing during the drying process of snake slough powder. In addition, the equipment is inefficient, cannot operate continuously, and requires multiple loading and unloading operations.

Method used

The chamber is divided into independent heating spaces by heat-insulating pads. The temperature is gradually increased by heaters at different temperatures controlled by the control panel. The loading and unloading operations are automated through moving and loading/unloading mechanisms to avoid splashing and improve efficiency.

Benefits of technology

It realizes the automated and continuous drying process of snake slough powder, avoids splashing, and improves equipment efficiency and ease of operation.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN116576646B_ABST
    Figure CN116576646B_ABST
Patent Text Reader

Abstract

The application discloses a kind of anti-splashing drying equipment for snake slough powder processing, belongs to drying equipment technical field.A kind of anti-splashing drying equipment for snake slough powder processing, including box, control panel being installed on the box;Drying mechanism, the drying mechanism is arranged on the box, for heating inside the box;Moving mechanism, is arranged in the box interior, for material is transported to make it be placed in different chamber and is heated;Feeding mechanism, is arranged on the top of the box, for the raw material of drying is fed;Discharging mechanism, is arranged in the box interior, for the raw material of processing completion is discharged, brings four groups of heaters respectively heats different temperature, so that the temperature inside the box gradually increases from lower to upper, so that the device can be gradually heated, so as to facilitate subsequent processing of raw material, so as to facilitate subsequent drying of snake slough, effectively avoid its splashing phenomenon.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This application relates to the field of drying equipment technology, and in particular to an anti-splash drying device for processing snake slough powder. Background Technology

[0002] Snake slough powder is a traditional Chinese medicine material, also known as snake skin powder. It is made by processing and grinding the slough of snakes. Before grinding, the slough of snakes needs to be dried, which is usually done with the help of drying equipment.

[0003] However, existing drying equipment generally maintains a stable internal temperature. During the drying process of snake slough powder, due to its high moisture content and the presence of tiny pores inside, the moisture evaporates rapidly after being exposed to high temperatures, forming expanding gas. This causes a sudden increase in internal pressure of the particles. When the internal pressure equals or exceeds the pressure resistance limit of the particle surface, particle breakage, bursting, and splashing will occur. If the temperature is gradually increased, the overall efficiency of the equipment is relatively low, and the equipment cannot operate continuously, further reducing its overall efficiency. In addition, the equipment requires multiple feeding and unloading operations to complete the drying of snake slough powder. In view of this, we propose an anti-splash drying equipment for processing snake slough powder. Summary of the Invention

[0004] The purpose of this application is to provide a splash-proof drying device for processing snake slough powder, so as to solve the problems mentioned in the background art.

[0005] This application provides a splash-proof drying device for processing snake slough powder, which adopts the following technical solution:

[0006] A splash-proof drying device for processing snake slough powder includes a housing and a control panel installed on the housing;

[0007] A drying mechanism, which is mounted on the chamber and is used to heat the interior of the chamber;

[0008] The moving mechanism, located inside the housing, is used to convey materials and place them in different chambers for heating;

[0009] The feeding mechanism, located at the top of the chamber, is used to feed the raw materials to be dried.

[0010] The feeding mechanism, located inside the box, is used to feed the processed raw materials.

[0011] By adopting the above technical solution, the device can automatically load and unload materials and gradually increase the temperature to complete the drying operation.

[0012] Optionally, the drying mechanism includes a fan fixedly installed at the front end of the box, and a main air supply pipe is fixedly connected to the air outlet of the fan. A branch pipe is fixedly connected to the main air supply pipe, and the other end of the branch pipe extends into the inside of the box. A heater is fixedly installed inside each branch pipe, and an air outlet is fixedly installed on the other side of the box.

[0013] By adopting the above technical solution, the device can simultaneously heat the inside of the chamber to different temperatures, thereby performing drying operations at different temperatures.

[0014] Optionally, the moving mechanism includes five sets of heat-insulating pads fixedly connected inside the housing. The five sets of heat-insulating pads are evenly distributed inside the housing, and the heat-insulating pads cooperate with the branch pipes and air outlets to form four independent heating spaces. The two sides of the top center of the heat-insulating pads are attached together. The upper and lower sides of the front and rear ends of the inner wall of the housing are respectively rotatably connected to the transmission rods through bearings. The external sides of the transmission rods at both ends are fixedly connected to the chain wheels, and the external sides of the four sets of transmission rods at both ends are movably connected through the transmission chain. The two sides of the transmission chain are fixedly connected to the ends that are close to each other, and the two sides of the movable shafts are fixedly connected to the ends that are close to each other.

[0015] By adopting the above technical solution, the device can divide its internal space, thereby allowing it to produce different temperatures.

[0016] Optionally, both ends of the mobile compartment are arc-shaped, and the upper side of the mobile compartment has a hole, and the upper side of the mobile compartment has a storage cavity.

[0017] By adopting the above technical solution, the mobile compartment can fit tightly with the heat insulation pad when passing through it, ensuring its sealing effect.

[0018] Optionally, a fixed connecting plate is fixedly connected to the lower side of both the front and rear ends of the box body, and a set of transmission rods on both sides extends to the outside of the box body. Pulleys are fixedly connected to both sides of the outside of the two sets of transmission rods and the outside of the rotating rod. The pulleys on both sides are movably connected to each other by a transmission belt. A motor is fixedly installed on one set of the fixed connecting plates, and the output shaft of the motor is fixedly connected to the rotating rod.

[0019] By adopting the above technical solution, the device can make a set of chain wheels on both sides rotate through the operation of the motor, thereby making the transmission chains on both sides rotate synchronously.

[0020] Optionally, the feeding mechanism includes a centralized cavity fixedly installed at the top of the box, and a discharge port fixedly connected to the bottom of the centralized cavity. Two sets of fixing plates are fixedly connected to both sides of the top of the box. Limiting rods are fixedly connected to both sides of the centralized cavity, and a discharge cavity is sleeved on the outside of the limiting rods. Limiting springs are sleeved on the outside of the limiting rods, and the two ends of the limiting springs are welded to the fixing plates and the discharge cavity, respectively. Guide plates are fixedly connected to the upper and lower sides inside the discharge cavity.

[0021] By adopting the above technical solution, the raw materials inside the feeding port can be placed inside the feeding chamber for quantitative storage, which facilitates subsequent feeding operations.

[0022] Optionally, rotating rods are rotatably connected to both sides of the bottom of the feeding chamber via bearings. A baffle plate is fixedly connected to one end of the rotating rods that are close to each other, and a torsion spring is sleeved on the outside of the rotating rod. The two ends of the torsion spring are respectively welded to the feeding chamber and the baffle plate.

[0023] By adopting the above technical solution, the material inside the feeding chamber can be quantitatively dropped through the rotating baffle plate, thus enabling quantitative feeding operations.

[0024] Optionally, transmission gears are fixedly connected to the ends of the two sets of rotating rods that are far apart from each other, and first connecting plates are fixedly connected to both sides of the top of the housing, and first rack plates are fixedly connected to the first connecting plates. The first rack plates and transmission gears cooperate with each other. Guide plates are fixedly connected to both sides of the bottom of the feeding chamber, and guide plates cooperate with the movable shaft. An auxiliary baffle is fixedly connected to the upper right side of the feeding chamber.

[0025] By adopting the above technical solution, the guide plate and the entire unloading chamber can be moved simultaneously by the transmission chain while the moving chamber is being transported. Then, the material can be automatically fed through the meshing of the transmission gear and the first rack plate.

[0026] Optionally, the feeding mechanism includes a second connecting plate fixedly connected to the upper sides of the front and rear ends of the inner wall of the box, and a second rack plate fixedly connected to the other end of each of the two sets of second connecting plates. A rotating gear is fixedly connected to the outside of each of the movable shafts. The rotating gear and the second rack plate cooperate with each other. Storage cavities are fixedly connected to the left and right sides of the inside of the box, and a discharge port is provided at the bottom of each storage cavity. A feeding guide groove that cooperates with the storage cavity is provided on the box.

[0027] By adopting the above technical solution, when the transmission chain drives the moving bin to move, the rotating gear can mesh with the second rack plate, thereby allowing the moving bin to rotate and perform the unloading operation.

[0028] In summary, this application includes at least one of the following beneficial technical effects:

[0029] 1. By individually installing heaters inside the four sets of branch pipes and dividing the internal space of the chamber with heat-insulating pads, four independent spaces can be formed inside. The four sets of heaters are controlled by the control panel to heat at different temperatures, so that the temperature inside the chamber gradually increases from bottom to top. This allows the device to gradually increase the temperature, which is beneficial for subsequent processing of raw materials and drying of snake slough, and effectively prevents splashing.

[0030] 2. By controlling the rotation of the rotating rod, four sets of moving chambers can rotate periodically, passing through the interior of the box from bottom to top, thereby gradually heating the raw materials inside the moving chambers. When the transmission chain rotates and drives the moving chambers, the movable shaft on the moving chamber abuts against the guide plate, which allows the feeding chamber to move and the limit spring to block the feeding port. As the feeding chamber continues to move, the baffle plate rotates, allowing the raw materials inside the feeding chamber to fall in a measured amount, thus enabling the device to automatically perform the feeding operation. Afterwards, when the guide plate releases from the movable shaft, the feeding chamber can be reset. The transmission chain continues to rotate, causing the rotating gear to mesh with the second rack plate, which allows the moving chamber to rotate, thus removing the dried raw materials inside the moving chamber. The materials are then guided by the feeding guide chute and placed in the storage chamber, enabling the device to automatically perform the feeding and unloading operations. The device does not require manual operation. Furthermore, the entire device can operate continuously, and the feeding is uniform each time, which is beneficial for subsequent drying, thus effectively increasing the drying efficiency of the device. Attached Figure Description

[0031] Figure 1 This is a top-down view of the three-dimensional structure of this application;

[0032] Figure 2 This is a side-view top view of the three-dimensional structure of this application;

[0033] Figure 3 This is a three-dimensional sectional view of the structure of this application;

[0034] Figure 4 For this application Figure 1 A three-dimensional structural diagram of the middle box in its concealed state;

[0035] Figure 5 For this application Figure 4 Enlarged structural diagram at point A;

[0036] Figure 6 For this application Figure 3 Enlarged structural diagram at point B;

[0037] Figure 7 For this application Figure 4 A partial three-dimensional structural diagram of the fixed connecting plate in the middle;

[0038] Figure 8 For this application Figure 4 A schematic diagram of the local three-dimensional structure at the central cavity;

[0039] Figure 9 For this application Figure 8 A three-dimensional structural diagram of the auxiliary baffle and the limiting spring;

[0040] Figure 10 For this application Figure 9 Enlarged schematic diagram of the structure at point C;

[0041] Figure 11 For this application Figure 4 Enlarged structural diagram at point D;

[0042] Figure 12 This is a three-dimensional structural diagram of the mobile warehouse in this application.

[0043] Explanation of the numbers in the diagram: 111. Housing; 112. Control panel; 211. Fan; 212. Main air supply duct; 213. Branch duct; 214. Air outlet; 311. Insulation pad; 312. Drive rod; 313. Sprocket; 314. Drive chain; 315. Movable shaft; 316. Moving compartment; 317. Fixed connecting plate; 318. Rotating rod; 319. Pulley; 320. Drive belt; 321. Motor; 322. Rotating gear; 411. 412. Concentrated cavity; 413. Discharge port; 414. Fixing plate; 415. Limiting rod; 416. Limiting spring; 417. Discharge cavity; 418. Guide plate; 419. Rotating rod; 420. Baffle plate; 421. Torsion spring; 422. Transmission gear; 423. First connecting plate; 424. First rack plate; 425. Guide stop plate; 516. Auxiliary baffle plate; 517. Second connecting plate; 518. Second rack plate; 519. Discharge guide groove; 510. Storage cavity. Detailed Implementation

[0044] The present application will be further described in detail below with reference to the accompanying drawings.

[0045] Reference Figure 1 The present application provides a splash-proof drying device for processing snake slough powder, including a housing 111 and a control panel 112 installed on the housing 111;

[0046] Reference Figure 1 and Figure 2The drying mechanism provided in this application is installed on the housing 111 and is used to heat the inside of the housing 111. The drying mechanism includes a fan 211 fixedly installed at the front end of the housing 111, and a main air supply pipe 212 is fixedly connected to the air outlet of the fan 211. A branch pipe 213 is fixedly connected to the main air supply pipe 212, and the other end of the branch pipe 213 extends into the inside of the housing 111. A heater is fixedly installed inside each branch pipe 213. An air outlet 214 is fixedly installed on the other side of the housing 111, so that the device can heat the inside of the housing 111 to different temperatures at the same time, thereby performing drying operations at different temperatures. The control panel 112 controls the operation and operating temperature of the heater inside the branch pipe 213, the operation of the motor 321, and the operation of the fan 211, which is prior art and is not the main object of protection of this invention, so it is not described in detail again.

[0047] Reference Figure 5 , Figure 5 and Figure 7The moving mechanism provided in this application is located inside the housing 111 and is used to transport materials to different chambers for heating. The moving mechanism includes five sets of heat-insulating pads 311 fixedly connected inside the housing 111. The five sets of heat-insulating pads 311 are evenly distributed inside the housing 111, and the heat-insulating pads 311 cooperate with the branch pipes 213 and the air outlets 214 to form four independent heating spaces. The air outlets 214 are prior art. The two sides of the top center of the heat-insulating pads 311 are attached, and the upper and lower sides of the front and rear ends of the inner wall of the housing 111 are also attached. Each of the four sets of transmission rods 312 is rotatably connected via bearings. Chain wheels 313 are fixedly connected to the exterior of each transmission rod 312. All four sets of transmission rods 312 at both ends are movably connected via transmission chains 314. Four sets of movable shafts 315 are fixedly connected to the ends of the transmission chains 314 on both sides that are close to each other. A movable chamber 316 is fixedly connected to the ends of the movable shafts 315 on both sides that are close to each other, allowing the device to divide its internal space and thus achieve different temperatures. Both ends of the movable chamber 316 are arc-shaped, and the interior of the movable chamber 316... An opening is provided on the upper side of the housing 111, and a storage cavity is provided on the upper side of the movable compartment 316, so that the movable compartment 316 can fit tightly with the heat insulation pad 311 when passing through it to ensure its sealing effect. Fixed connecting plates 317 are fixedly connected to the lower sides of both the front and rear ends of the housing 111. A set of transmission rods 312 on both sides extends to the outside of the housing 111. Pulleys 319 are fixedly connected to the outside of the two sets of transmission rods 312 and the outside of the rotating rod 318 on both sides. The two pulleys 319 are movably connected to each other by a transmission belt 320. A fixed connecting plate 317 is also provided. A motor 321 is fixedly installed on the plate 317, and the output shaft of the motor 321 is fixedly connected to the rotating rod 318. This allows the device to rotate a set of chain wheels 313 on both sides through the operation of the motor 321, thereby allowing the transmission chains 314 on both sides to rotate synchronously. This allows the entire device to rotate counterclockwise through the operation of the motor 321, thereby allowing the mobile compartment 316 to move as a whole. This allows the mobile compartment 316 to periodically move across the heat-insulating soft pad 311.

[0048] Reference Figure 1-10The feeding mechanism provided in this application is located at the top of the box 111 and is used to feed the dried raw materials. The feeding mechanism includes a centralized cavity 411 fixedly installed at the top of the box 111, and a discharge port 412 is fixedly connected to the bottom end of the centralized cavity 411. Two sets of fixing plates 413 are fixedly connected to both sides of the top of the box 111. Limiting rods 414 are fixedly connected to both centralized cavities 411, and a discharge cavity 416 is sleeved on the outside of the limiting rods 414. Limiting springs 415 are sleeved on the outside of the limiting rods 414, and the two ends of the limiting springs 415 are welded to the fixing plates 413 and the discharge cavity 416, respectively. The discharge cavity 416 contains... Guide plates 417 are fixedly connected to both the upper and lower sides to allow the raw material inside the discharge port 412 to be placed inside the discharge cavity 416 for quantitative storage, thus facilitating subsequent feeding operations. Rotary rods 418 are rotatably connected to both sides of the bottom end of the discharge cavity 416 via bearings. A baffle plate 419 is fixedly connected to the end of the two rotating rods 418 that is close to each other. Torsion springs 420 are sleeved on the outside of the rotating rods 418. The two ends of the torsion springs 420 are welded to the discharge cavity 416 and the baffle plate 419 respectively, allowing the raw material inside the discharge cavity 416 to fall quantitatively through the rotation of the baffle plate 419 for quantitative feeding operations. The two sets of rotating rods 417... 18. A transmission gear 421 is fixedly connected to each other at the opposite ends. A first connecting plate 422 is fixedly connected to both sides of the top of the housing 111. A first rack plate 423 is fixedly connected to the first connecting plate 422. The first rack plate 423 and the transmission gear 421 cooperate with each other. A guide plate 424 is fixedly connected to both sides of the bottom of the discharge cavity 416. The guide plate 424 cooperates with the movable shaft 315. An auxiliary baffle 425 is fixedly connected to the upper right side of the discharge cavity 416. This allows the guide plate 424 and the entire discharge cavity 416 to move while the movable conveyor 316 is being transported via the transmission chain 314. Then, through the meshing of the transmission gear 421 and the first rack plate 423, the material can be automatically fed. The auxiliary baffle 425 is fitted with limiting blocks on both sides, and the ends of the limiting blocks that are far apart from each other are fixedly connected to the fixing plates 413 on both sides, so that the limiting blocks can limit the auxiliary baffle 425, thereby keeping the auxiliary baffle 425 stable. When the device is working, the rotation of the transmission chain 314 can drive the guide plate 424 to move, so that the guide plate 424 can drive the feeding chamber 416 and the auxiliary baffle 425 to move and reset periodically, thereby completing the subsequent automatic quantitative and periodic feeding operation.

[0049] Reference Figure 4 and Figure 12The feeding mechanism provided in this application is installed inside the housing 111 and is used to feed the processed raw materials. The feeding mechanism includes a second connecting plate 511 fixedly connected to the upper sides of the front and rear ends of the inner wall of the housing 111. A lower second rack plate 512 is fixedly connected to the other end of each of the two sets of second connecting plates 511. A rotating gear 322 is fixedly connected to the outside of the movable shaft 315. The rotating gear 322 and the second rack plate 512 cooperate with each other. A storage cavity 514 is fixedly connected to the left and right sides inside the housing 111, and a discharge port is provided at the bottom of each storage cavity 514. A feeding guide groove 513 is provided on the housing 111 to cooperate with the storage cavity 514 so that when the transmission chain 314 drives the moving chamber 316 to move, the rotating gear 322 can mesh with the second rack plate 512, thereby allowing the moving chamber 316 to rotate and perform the feeding operation. When the device passes through the feeding mechanism, it can automatically feed the dried raw materials.

[0050] The implementation principle of the anti-splash drying equipment for processing snake slough powder in this application embodiment is as follows:

[0051] First, the raw materials to be dried can be placed inside the central chamber 411. Then, the four sets of heaters, fans 211 and motors 321 are controlled by the control panel 112. When the heaters and fans 211 are working, the cavity formed by the heat insulation pad 311 and the box 111 can be heated.

[0052] When the motor 321 operates, it drives the rotating rod 318 to rotate, which in turn drives a set of transmission rods 312 on both sides to rotate via the pulley 319 and the transmission belt 320. This, in turn, causes a set of chain wheels 313 to rotate. When the set of chain wheels 313 rotates, it drives the entire transmission chain 314 to rotate. When the transmission chain 314 rotates, it drives the movable shaft 315 and the moving chamber 316 to move. When the moving chamber 316 moves to the top, the movable shaft 315 on the moving chamber 316 abuts against the guide plate 424, causing the guide plate 424 to move to the left. When the guide plate 424 moves, it drives the feeding chamber 416 to move. When the feeding chamber 416 moves, it compresses the limit spring 415. Then, the feeding chamber 416 continues to move, causing the auxiliary baffle 425 to block the feeding port 412. As it continues to move, it causes the transmission gear 421 to... The first rack plate 423 engages, causing the transmission gear 421 to rotate counterclockwise. When the transmission gear 421 rotates counterclockwise, the baffle plate 419 rotates counterclockwise, thereby opening the feeding chamber 416 and causing the torsion spring 420 to deform, allowing the material inside to fall into the moving chamber 316. Subsequently, the feeding chamber 416 and the guide plate 424 continue to move, causing the transmission gear 421 to disengage, thus allowing the torsion spring 420 to return to its original shape and drive the baffle plate 419 to reset. Then, the moving chamber 316 continues to move, causing the moving chamber 316 to disengage from the guide plate 424, thus allowing the limit spring 415 to return to its original shape and drive the feeding chamber 416 to reset. Subsequently, the material inside the concentrating chamber 411 falls back into the feeding chamber 416, thereby causing the subsequent moving chamber 316 and the movable shaft 315 to continue to move and abut against the guide plate 424, thus feeding material again.

[0053] The drive chain 314 then continues to move, positioning it at the bottom of the housing 111. This allows the movable chamber 316 to enter the housing 111, bringing it into contact with the heat-insulating pad 311. This causes the top of the heat-insulating pad 311 to deform, allowing one set of movable chambers 316 to enter the space created by that set of heat-insulating pads 311 for initial drying. This set of movable chambers 316 then passes through five sets of heat-insulating pads 311 in sequence to complete the drying process, and then moves out from the top heat-insulating pad 311. As the movable chambers 316 move out, the heat-insulating pad 311 returns to its original shape, maintaining a close fit. After the drying operation is completed, the transmission chain 314 continues to move, causing the rotating gears 322 on both sides of the moving chamber 316 to mesh with the second rack plates 512 on both sides, thereby causing the rotating gears 322 to rotate. When the rotating gears 322 rotate, they can drive the moving chamber 316 to rotate, thereby causing the dried raw materials inside the moving chamber 316 to be poured out. Then, guided by the top heat insulation pad 311 and the material guide groove 513, they are placed inside the storage cavity 514 for storage. Since the transmission chain 314 can rotate periodically, the moving chamber 316 can perform loading, unloading and drying operations periodically.

[0054] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A splash-proof drying device for processing snake slough powder, characterized in that, include: The enclosure (111) and the control panel (112) mounted on the enclosure (111). A drying mechanism is provided on the box (111) for heating the inside of the box (111); The moving mechanism, located inside the housing (111), is used to convey materials and place them in different chambers for heating; The feeding mechanism is located on the top of the box (111) and is used to feed the dried raw materials. The feeding mechanism is located inside the box (111) and is used to feed the processed raw materials. The drying mechanism includes a fan (211) fixedly installed at the front end of the housing (111), and a main air supply pipe (212) is fixedly connected to the air outlet end of the fan (211). A branch pipe (213) is fixedly connected to the main air supply pipe (212), and the other end of the branch pipe (213) extends into the housing (111). A heater is fixedly installed inside the branch pipe (213). An air outlet (214) is fixedly installed on the other side of the housing (111). The moving mechanism includes five sets of heat-insulating pads (311) fixedly connected inside the housing (111). The five sets of heat-insulating pads (311) are evenly distributed inside the housing (111), and the heat-insulating pads (311) cooperate with the branch pipe (213) and the air outlet (214) to form four independent heating spaces. The two sides of the top center of the heat-insulating pads (311) are attached together. The upper and lower sides of the front and rear ends of the inner wall of the housing (111) are respectively connected to the transmission rods (312) through bearings. The transmission rods (312) at both ends are fixedly connected to the outside of the transmission rods (312), and the four sets of transmission rods (312) at both ends are movably connected to the outside of the transmission chains (314). The ends of the transmission chains (314) on both sides that are close to each other are movably connected to four sets of movable shafts (315) through rotating shafts. The ends of the movable shafts (315) on both sides that are close to each other are fixedly connected to the movable chambers (316). The feeding mechanism includes a central cavity (411) fixedly installed at the top of the box (111), and a discharge port (412) is fixedly connected to the bottom end of the central cavity (411). Two sets of fixing plates (413) are fixedly connected to the two sides of the top of the box (111). Limiting rods (414) are fixedly connected to both sides of the central cavity (411), and a discharge cavity (416) is sleeved on the outside of the limiting rods (414). Limiting springs (415) are sleeved on the outside of the limiting rods (414), and the two ends of the limiting springs (415) are welded to the fixing plate (413) and the discharge cavity (416) respectively. Guide plates (417) are fixedly connected to the upper and lower sides inside the discharge cavity (416). The bottom of the feeding chamber (416) is connected to rotating rods (418) on both sides by bearings. A baffle plate (419) is fixedly connected to the end of the rotating rods (418) that are close to each other. A torsion spring (420) is sleeved on the outside of the rotating rod (418). The two ends of the torsion spring (420) are welded to the feeding chamber (416) and the baffle plate (419) respectively. Both sets of rotating rods (418) are fixedly connected to a transmission gear (421) at their ends that are far apart from each other. A first connecting plate (422) is fixedly connected to both sides of the top of the housing (111). A first rack plate (423) is fixedly connected to the first connecting plate (422). The first rack plate (423) and the transmission gear (421) cooperate with each other. A guide plate (424) is fixedly connected to both sides of the bottom of the feeding chamber (416). The guide plate (424) cooperates with the movable shaft (315). An auxiliary baffle (425) is fixedly connected to the upper right side of the feeding chamber (416).

2. The anti-splash drying equipment for processing snake slough powder according to claim 1, characterized in that: Both ends of the mobile compartment (316) are arc-shaped, and the upper side of the interior of the mobile compartment (316) has a hole, and the upper side of the interior of the mobile compartment (316) has a storage cavity.

3. The anti-splash drying equipment for processing snake slough powder according to claim 2, characterized in that: Fixed connecting plates (317) are fixedly connected to the lower sides of both the front and rear ends of the housing (111). A set of transmission rods (312) on both sides extends to the outside of the housing (111). Pulleys (319) are fixedly connected to the outside of the two sets of transmission rods (312) and the outside of the rotating rod (318). The two sets of pulleys (319) are movably connected to each other by a transmission belt (320). A motor (321) is fixedly installed on a set of fixed connecting plates (317), and the output shaft of the motor (321) is fixedly connected to the rotating rod (318).

4. The anti-splash drying equipment for processing snake slough powder according to claim 1, characterized in that: The feeding mechanism includes a second connecting plate (511) fixedly connected to the upper sides of the front and rear ends of the inner wall of the box (111). A second rack plate (512) is fixedly connected to the other end of each of the two sets of second connecting plates (511). A rotating gear (322) is fixedly connected to the outside of the movable shaft (315). The rotating gear (322) and the second rack plate (512) cooperate with each other. Storage cavities (514) are fixedly connected to the left and right sides inside the box (111). A discharge port is provided at the bottom of each storage cavity (514). A feeding guide groove (513) that cooperates with the storage cavity (514) is opened on the box (111).