An anti-fatigue deer placenta composition lyophilized powder preparation device and a method of using the same
By designing a proportioning partition, a descending drive shaft, and a piston head, the problem of poor adaptability of the proportioning adjustment mechanism in the freeze-dried powder preparation device was solved, achieving synchronous consumption and precise proportioning of raw materials, and improving product quality stability and adsorption efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- YINCHUAN YIBAISHENG BIOLOGICAL ENG CO LTD
- Filing Date
- 2026-06-05
- Publication Date
- 2026-07-03
AI Technical Summary
Traditional freeze-dried powder preparation devices have poor adaptability in their proportioning and adjustment mechanisms, resulting in a mismatch between the absorption volume and the total amount of raw materials, leading to asynchronous consumption, waste of raw materials, and unstable product quality.
It adopts a proportioning partition and a descending drive shaft design, and achieves synchronous consumption and precise proportioning of raw materials by rotating to adjust the compartment volume and adsorption mechanism; combined with piston head and elastic flap structure, it realizes filterless suction transmission and continuous adsorption; the lifting outer shaft and smoothing mechanism work together to maintain adaptive and stable adsorption height.
It achieves precise matching and consumption of raw materials with different ratios, avoids problems such as raw material residue or premature emptying, improves product quality stability and raw material utilization, and significantly improves adsorption efficiency and equipment continuous operation capability.
Smart Images

Figure CN122321709A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of dry powder preparation technology, specifically to a device for preparing freeze-dried powder of an anti-fatigue deer placenta composition and its usage method. Background Technology
[0002] Traditional equipment often uses fixed partitions or manual weighing and batching. When the product formula needs to change the components, the machine must be stopped to reconstruct the silo structure or reset the weighing parameters. The changeover cycle is long and relies on human experience. This rigid design means that a single machine can only produce a limited number of formulas, which is difficult to meet the market demand for multi-specification, small-batch customized products. The lack of equipment versatility and flexible manufacturing capabilities has become a pain point in the industry.
[0003] Conventional suction structures typically employ a constant rotation speed and a fixed suction nozzle design. The amount of material sucked in a single operation cannot be dynamically adjusted according to the amount of raw material stored. Although the initial loading amount of raw materials with different ratios is different, the suction rate is constant, resulting in inconsistent consumption rates of each component. In actual production, it is common to see some raw materials empty while other raw materials remain in large quantities. This not only causes waste of raw materials and drift in the composition ratio between batches, but also leads to the production of defective products due to continued operation after emptying the material, which seriously affects the stability of product quality and the utilization rate of raw materials.
[0004] Due to the lack of an adaptive matching mechanism between absorption and storage, the actual consumption ratio of each raw material in different production batches deviates significantly from the theoretical formula. Factors such as differences in absorption efficiency at the beginning and end of equipment operation and suction attenuation caused by changes in material level height lead to fluctuations in the proportion of active ingredients between batches exceeding the allowable range. This systematic error makes the product efficacy unstable, requiring frequent finished product testing and formula fine-tuning, increasing quality control costs and production uncertainty.
[0005] In view of this, the present invention proposes a device for preparing freeze-dried powder of anti-fatigue deer placenta composition and a method for using it. Summary of the Invention
[0006] The purpose of this invention is to provide a preparation device and method for using a freeze-dried powder of an anti-fatigue deer placenta composition, to solve the problems of poor adaptability of the ratio adjustment mechanism and mismatch between the absorption amount and the total amount of raw materials, and asynchronous consumption, in the freeze-dried powder preparation devices proposed in the background art. To achieve the above objective, this invention provides the following technical solution: a preparation device and method for using a freeze-dried powder of an anti-fatigue deer placenta composition, comprising a raw material silo, a mixing chamber fixedly connected to the outer surface of the raw material silo, a central column fixedly connected to the inner surface of the raw material silo, a top end cap fixedly connected to the top surface of the mixing chamber, a ratio partition provided on the inner surface of the raw material silo, an adjustable slide rail provided on the top surface of the ratio partition, a descending drive shaft provided on the inner surface of the central column, a smoothing mechanism provided on the outer surface of the descending drive shaft to smooth the absorbed powder and prevent depressions from affecting the next absorption effect, an adsorption mechanism provided on the outer surface of the descending drive shaft, and a collection chamber provided on the outer surface of the adsorption mechanism.
[0007] Preferably, the proportioning partition includes an inner baffle, which is slidably connected to the inner surface of the raw material hopper. A contact ball protrusion is fixedly connected to the outer surface of the inner baffle. An annular guide groove is formed on the outer surface of the raw material hopper. The inner baffle is slidably connected to the annular guide groove through the contact ball protrusion to limit the sliding path. A folding lifting plate is slidably connected to the inner surface of the inner baffle. A top mounting seat is fixedly connected to the top surface of the folding lifting plate. Side support plates are fixedly connected to both sides of the top mounting seat. The folding lifting plate can be folded and raised to match different powder heights and change the height of the top mounting seat.
[0008] Preferably, the number of the proportioning partitions is four, and the contact ball protrusion is slidably connected to the annular guide groove.
[0009] Preferably, the adjustable slide rail includes an extension bracket, which is fixedly connected to the top surface of the top mounting base. The extension bracket raises the overall height of the adjustable slide rail to prevent the limiting guide groove from sinking into the powder. A hinged groove plate is hinged to the outer surface of the extension bracket. A limiting guide groove is formed on the top surface of the hinged groove plate. An extension groove plate is slidably connected to the inner surface of the hinged groove plate to adapt to different spacings of the mixing partitions and match the required height. A side fan plate is fixedly connected to one end of the extension groove plate. A fan plate shaft is rotatably connected to one end of the side fan plate. A folding fan plate is rotatably connected to the outer surface of the fan plate shaft. The foldable folding fan plate adapts to different angles after the spacing of the mixing partitions is adjusted. A fixed guide groove is fixedly connected to the other side of the extension bracket. An outward protrusion plate is fixedly connected to the outer surface of the fixed guide groove. A shaft connecting seat is fixedly connected to the outer surface of the extension bracket, which is fixed in the mixing chamber to maintain a high position and provide support.
[0010] Preferably, the top surfaces of the extension slot plate, side fan plate, and folding fan plate are all provided with limiting guide grooves, the top surface of the top mounting base is provided with limiting guide grooves, the folding fan plates are stacked on top of each other and slidably connected, the number of fan plate shafts is three, and the outer surface of each fan plate shaft is rotatably connected to two symmetrically distributed side fan plates and four folding fan plates.
[0011] Preferably, the descending drive shaft includes a servo motor, which is fixedly connected to the inner surface of the central column. The output end of the servo motor is fixedly connected to a fixed inner shaft, and a lifting outer shaft is slidably connected to the outer surface of the fixed inner shaft. The fixed inner shaft is connected via internal and external splines to drive the lifting outer shaft to rotate, while the lifting outer shaft can move in the vertical direction. An outer groove is formed on the outer surface of the lifting outer shaft, and a top baffle is fixedly connected to the outer surface of the lifting outer shaft. Symmetrically distributed lifting connecting frames are slidably connected to the outer surface of the lifting outer shaft. The symmetrical lifting connecting frames are respectively connected to the smoothing mechanism and the adsorption mechanism, which work synchronously and do not contact each other. A side mounting seat is fixedly connected to the outer surface of the lifting connecting frame. An adaptive slide rod is slidably connected to the top surface of the side mounting seat. A compression spring is fixedly connected to the bottom surface of the adaptive slide rod, and a contact ball joint is fixedly connected to the bottom surface of the compression spring for contacting the limiting guide groove to achieve lifting.
[0012] Preferably, the lifting outer shaft is fixedly connected to the shaft connecting seat, the fixed inner shaft is connected to the lifting outer shaft through internal and external splines, the adapting slide rod slides horizontally on the top surface of the side mounting seat, and the contact ball head rod is slidably connected to the inner surface of the limiting guide groove.
[0013] Preferably, the smoothing mechanism includes a counter-connecting column, which is fixedly connected to the outer surface of the lifting connecting frame, and a serrated wall is fixedly connected to the bottom surface of the counter-connecting column, and a flat wall is fixedly connected to the bottom surface of the counter-connecting column.
[0014] Preferably, the adsorption mechanism includes an actuation chamber, which is fixedly connected to a lifting connecting frame. A drive chamber is fixedly connected to the outer surface of the actuation chamber. A motor bracket is fixedly connected to the top surface of the drive chamber. A drive motor is slidably connected to the inner surface of the motor bracket. A lifting connecting shaft is fixedly connected to the bottom surface of the drive motor. A return spring is sleeved on the outer surface of the lifting connecting shaft. A rotary output seat is rotatably connected to the inner surface of the drive chamber. A connecting crank is fixedly connected to the bottom surface of the rotary output seat. A sliding block is slidably connected to the bottom surface of the connecting crank. A piston rod is slidably connected to the inner surface of the drive chamber. A piston head is fixedly connected to one end of the piston rod. When the output seat rotates, it drives the connecting crank to cause the slider to reciprocate. Symmetrically distributed inner flap supports are fixedly connected to the inner surface of the execution cavity. Notches are formed on the outer surface of the inner flap supports. Elastic fixed flaps are fixedly connected to the outer surface of the inner flap supports. A flap spring is fixedly connected to the inner surface of the inner flap supports. An elastic movable flap is fixedly connected to the other end of the flap spring. The upper and lower distributed elastic movable flaps alternately open and close according to the direction of piston head movement to generate an adsorption effect. An output pipe is fixedly connected to the top surface of the execution cavity, and an input pipe is fixedly connected to the bottom surface of the execution cavity.
[0015] Preferably, the lifting connecting shaft and the rotating output seat are connected by internal and external splines, the connecting crank slides horizontally on the inner surface of the actuating slider, the piston head slides laterally on the inner surface of the actuating cavity, the elastic fixed petal and the elastic movable petal are symmetrically distributed on the inner surface of the actuating cavity but in the same direction, and the elastic fixed petal and the elastic movable petal are made of rubber.
[0016] Preferably, the collection chamber includes a buffer shell, which is fixedly connected to the outer surface of the execution cavity. A bottom shell is fixedly connected to the bottom surface of the buffer shell, and a bottom slide is slidably connected to the inner surface of the bottom shell. An output groove is formed on the outer surface of the bottom slide, and a slide spring is fixedly connected to the outer surface of the bottom slide.
[0017] Preferably, the input pipe passes through the buffer housing and the bottom, the bottom slide is slidably connected to the outer protrusion plate, and the two sides of the slide spring are fixedly connected to the sliding base and the bottom housing, respectively.
[0018] A method for using an apparatus for preparing an anti-fatigue deer placenta composition lyophilized powder includes the following steps:
[0019] S1. The two proportioning partitions inside the raw material silo divide the silo into three compartments, which store different deer placenta composition raw material powders respectively. The proportioning partitions can be rotated to adjust the bottom area and volume of each compartment, thereby changing the time it takes for the adsorption mechanism to pass through a single compartment. Since the compartment volume is directly proportional to the amount of adsorption per cycle, the total amount of each raw material changes synchronously with the consumption rate, ensuring that the powder in the three compartments can be consumed at the same time, thus achieving powder proportioning.
[0020] S2. The servo motor drives the adsorption mechanism and smoothing mechanism to rotate at a constant speed through the descending drive shaft. The material passes through three material compartments in sequence. The adsorption mechanism uses the reciprocating motion of the piston to generate periodic suction. Through the opening and closing control of the elastic movable flap, the powder is sucked from the input pipe into the execution chamber for temporary storage. The lifting outer shaft is connected to the adjustable slide rail through the shaft connecting seat, which can follow the height of the powder surface and descend synchronously, so that the adsorption port always keeps close to the powder and ensures stable adsorption effect.
[0021] S3. When the piston moves in the reverse direction, it pushes the temporarily stored powder into the output pipe and enters the buffer shell for temporary storage. At the same time, the smoothing mechanism immediately processes the powder surface after adsorption. The serrated wall first changes the deep depressions formed by adsorption into multiple shallow grooves, and the flat wall smooths the shallow grooves to prevent the depressions from affecting the adsorption effect next time. The adsorption mechanism and the smoothing mechanism work synchronously through symmetrically distributed lifting connecting frames to achieve adsorption and smoothing at the same time.
[0022] S4. When the collection bin rotates with the adsorption mechanism to the top of the mixing bin, the bottom slide contactes the outer protrusion on the fixed guide groove and produces a sliding displacement, so that the output groove is aligned with the mixing bin, the powder is automatically released to complete the feeding. After detaching from the outer protrusion, the slide spring drives the bottom slide to reset and re-close the buffer shell. The entire device adapts to the spacing changes after the partition rotates through the adjustable slide rail folding and telescopic structure, realizing continuous automated operation.
[0023] Compared with the prior art, the beneficial effects of the present invention are as follows:
[0024] In this invention, the simultaneous consumption and precise proportioning of the three raw materials are achieved through the coordinated adjustment of the rotation of the proportioning partition and the speed control of the descending drive shaft. When the proportioning partition is rotated to change the bottom area of the compartment, the arc length of the path of the adsorption mechanism through each compartment changes synchronously. The single adsorption amount is automatically adjusted proportionally to the compartment volume. This design ensures that even though the initial stacking height of raw materials with different proportions is the same, the total amount and the single adsorption amount are always precisely matched, and the total consumption time is strictly consistent. When the powder in a certain compartment is exhausted, the other compartments will inevitably be emptied at the same time, completely eliminating the problem of raw material residue or premature emptying caused by proportioning errors. This ensures a high degree of consistency in the composition ratio between batches and greatly improves the product quality stability and raw material utilization rate.
[0025] In this invention, the transverse arrangement of the piston head and the elastic valve structure achieve complete suction and continuous adsorption without a filter. The piston drive structure is located on the side of the powder flow path, generating suction through volume changes. The powder is transported by the alternating opening and closing of the elastic movable valve and the elastic fixed valve. The powder destination completely avoids the piston area. Compared with the defects of traditional wind-driven adsorption, which requires a filter at the air source and is prone to clogging, this design allows for unobstructed suction transmission, avoiding suction attenuation and frequent shutdowns for cleaning caused by filter clogging. The piston can reciprocate at high frequency to generate continuous pulse suction, significantly improving adsorption efficiency and the continuous operation capability of the equipment. It is particularly suitable for processing freeze-dried powders that are extremely easy to fly away.
[0026] In this invention, the synchronous descent mechanism of the lifting outer shaft and the coordinated operation of the smoothing mechanism achieve the effect of adaptive stability of adsorption height and maintenance of surface flatness. The descent drive shaft 4 is connected to the adjustable slide rail through the shaft connecting seat, so that the adsorption mechanism always follows the powder surface to descend synchronously, maintaining a constant close-range adsorption and avoiding the decrease in suction force caused by the reduction of the powder layer. After adsorption, the serrated wall and flat wall immediately perform groove treatment and flattening on the powder surface, transforming deep depressions into multiple shallow depressions and then completely filling them, effectively preventing local collapse caused by a single adsorption from affecting the uniformity of subsequent absorption. This dual guarantee of dynamic following and real-time repair ensures that the adsorption process is always in the best working condition, significantly improving the stability and repeatability of material picking. Attached Figure Description
[0027] Figure 1 This is a schematic diagram of the overall structure of the present invention;
[0028] Figure 2 This is a side view of the internal structure of the present invention;
[0029] Figure 3 This is a schematic diagram of the structure of the raw material silo, mixing silo, and proportioning partition of the present invention.
[0030] Figure 4 This is a schematic diagram of the cooperative structure of the raw material silo and the mixing silo of the present invention;
[0031] Figure 5 This is a schematic diagram of the interlocking structure of the components of the proportioning partition of the present invention;
[0032] Figure 6 This is a schematic diagram of the structure of the raw material silo and the proportioning partition of the present invention.
[0033] Figure 7 This is a schematic diagram of the structure in which the raw material silo, the proportioning partition, and the adjustable slide rail of the present invention work together.
[0034] Figure 8 This is a schematic diagram of the bottom structure of the raw material silo and mixing silo of the present invention;
[0035] Figure 9 This is a schematic diagram of the interlocking structure of the adjustable slide rail components of the present invention;
[0036] Figure 10 This is a top view of the adjustable slide rail folding according to the present invention;
[0037] Figure 11 This is a side view of the adjustable slide rail folding according to the present invention;
[0038] Figure 12 This is a schematic diagram of the interoperability of the components of the descending drive shaft of the present invention;
[0039] Figure 13 This is a schematic diagram of the interaction between the descending drive shaft and the adjustable slide rail of the present invention;
[0040] Figure 14 This is a schematic diagram of the cooperation structure between the lifting connecting frame and the side mounting base of the present invention;
[0041] Figure 15 This is a schematic diagram of the interaction between the folding lifting plate and the lifting outer shaft of the present invention;
[0042] Figure 16 This is a schematic diagram of the structure in which the lifting outer shaft, the adsorption mechanism, and the smoothing mechanism of the present invention cooperate with each other;
[0043] Figure 17 This is a schematic diagram of the interoperability of the components of the smoothing mechanism of the present invention;
[0044] Figure 18 This is a schematic diagram of the interaction between the adsorption mechanism and the collection chamber of the present invention;
[0045] Figure 19 This is a schematic diagram of the internal structure of the adsorption mechanism of the present invention;
[0046] Figure 20 This is a schematic diagram of the motion state structure of the piston head and elastic movable flap of the present invention to generate suction force.
[0047] Figure 21 This is a schematic diagram of the motion state structure of the piston head and elastic movable flap of the present invention to generate thrust.
[0048] Figure 22 This is a schematic diagram of the structure in which the inner valve support, the elastic fixed valve, and the elastic movable valve of the present invention cooperate with each other.
[0049] Figure 23 This is a schematic diagram of the interaction structure of the drive motor, connecting crank, and actuating slider of the present invention.
[0050] Figure 24 This is a schematic diagram of the cooperation structure between the lifting connecting shaft and the rotating output seat of the present invention;
[0051] Figure 25 This is a schematic diagram of the internal structure of the adsorption mechanism and collection chamber of the present invention;
[0052] Figure 26 This is a schematic diagram of the interaction between the bottom slide and the outer convex plate of the present invention.
[0053] In the diagram: 1. Raw material bin; 11. Mixing bin; 12. Central column; 13. Top end cover; 2. Proportioning partition; 21. Inner baffle; 211. Contact ball protrusion; 212. Annular guide groove; 22. Folding lifting plate; 23. Top mounting seat; 231. Side support plate; 3. Adjustable slide rail; 31. Extension bracket; 32. Hinge groove plate; 321. Limiting guide groove; 322. Extension groove plate; 33. Side fan plate; 331. Fan plate shaft; 332. Folding fan plate; 34. Fixed guide groove; 341. Outer protrusion plate; 35. Shaft connecting seat; 4. Follow-down drive shaft; 41. Servo motor; 411. Fixed inner shaft; 42. Lifting outer shaft; 421. Shaft outer groove; 422. Top baffle; 423. Lifting connecting frame; 44. Side mounting seat; 441. Adaptive slide rod; 442. Compression spring; 443. Contact ball head rod; 5. Smoothing mechanism; 51. Opposite connecting column; 52. Serrated wall; 53. Flat wall; 6. Adsorption mechanism; 61. Actuating chamber; 611. Driving chamber; 612. Motor bracket; 62. Drive motor; 621. Lifting connecting shaft; 622. Return spring; 63. Rotating output seat; 64. Connecting crank; 641. Actuating slider; 65. Piston rod; 651. Piston head; 66. Inner lobe bracket; 661. Notch; 662. Lobe spring; 663. Elastic fixed lobe; 664. Elastic movable lobe; 67. Output pipe; 671. Input pipe; 7. Collection chamber; 71. Buffer housing; 72. Bottom housing; 73. Bottom slide; 731. Output slot; 732. Slide spring. Detailed Implementation
[0054] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0055] Please see Figures 1 to 26This invention provides a technical solution: a device for preparing freeze-dried powder of an anti-fatigue deer placenta composition and its usage method, comprising a raw material silo 1, a mixing chamber 11 fixedly connected to the outer surface of the raw material silo 1, a central column 12 fixedly connected to the inner surface of the raw material silo 1, a top end cap 13 fixedly connected to the top surface of the mixing chamber 11, a proportioning partition 2 provided on the inner surface of the raw material silo 1, an adjustable slide rail 3 provided on the top surface of the proportioning partition 2, a descending drive shaft 4 provided on the inner surface of the central column 12, a smoothing mechanism 5 provided on the outer surface of the descending drive shaft 4 to smooth the absorbed powder and prevent depressions from affecting the next absorption effect, an adsorption mechanism 6 provided on the outer surface of the descending drive shaft 4, and a collection chamber 7 provided on the outer surface of the adsorption mechanism 6.
[0056] The proportioning partition 2 includes an inner baffle 21, which is slidably connected to the inner surface of the raw material silo 1. A contact ball protrusion 211 is fixedly connected to the outer surface of the inner baffle 21. An annular guide groove 212 is provided on the outer surface of the raw material silo 1. The inner baffle 21 is slidably connected to the annular guide groove 212 through the contact ball protrusion 211 to limit the sliding path. A folding lifting plate 22 is slidably connected to the inner surface of the inner baffle 21. A top mounting seat 23 is fixedly connected to the top surface of the folding lifting plate 22. Side support plates 231 are fixedly connected to both sides of the top mounting seat 23. The folding lifting plate 22 is folded and lifted to match different powder heights and change the height of the top mounting seat 23.
[0057] The number of partition plates 2 is four.
[0058] With the setting of the proportioning partition 2, during use, there are four sets of proportioning partition 2, two of which are fixed on both sides of the mixing chamber 11, and the other two are located inside the raw material chamber 1, and their positions can be changed by rotation.
[0059] Each batch of partition 2 consists of an inner baffle 21 as the main body. The internal folding lifting plate 22 can be folded and lifted. The top is mounted with a side support plate 231 via a top mounting seat 23. The side support plate 231 is lower than the top mounting seat 23 and has a large surface area, which can support the powder surface and thus lift the top mounting seat 23. As the amount of powder decreases, the top mounting seat 23 descends synchronously.
[0060] The two proportioning partitions 2 inside the raw material silo 1 divide the raw material silo 1 into three parts for storing different raw material powders. The adsorption mechanism 6 rotates at a constant speed through the descending drive shaft 4 to sequentially suck up and take out the powder in different compartments.
[0061] Since the two proportioning baffles 2 inside the raw material silo 1 can be rotated to adjust the size of the compartments, the volume and bottom area of the compartments change together. The time it takes for the adsorption mechanism 6 to pass through a single compartment also changes, thereby adjusting the adsorption amount in a single compartment so that the total amount of powder in the compartment is proportional to the amount of powder adsorbed in a single instance. In this way, after adjusting the size of the three compartments, the amount of powder adsorbed in a single instance changes together. In the initial state, the powder in different compartments falls to the same height. Since the total amount and the consumption rate change synchronously, the total consumption time is the same, so that when the powder in one compartment is consumed, the powder in the remaining compartments is consumed at the same time.
[0062] The adjustable slide rail 3 includes an extension bracket 31, which is fixedly connected to the top surface of the top mounting base 23. The outer surface of the extension bracket 31 is hinged to a hinge slot plate 32. A limit guide groove 321 is formed on the top surface of the hinge slot plate 32. The inner surface of the hinge slot plate 32 is slidably connected to an extension slot plate 322 to adapt to different spacings of the mixing partitions 2 and match the required height. One end of the extension slot plate 322 is fixedly connected to a side fan plate 33. One end of the side fan plate 33 is rotatably connected to a fan plate shaft 331. The outer surface of the fan plate shaft 331 is rotatably connected to a folding fan plate 332 to adapt to different angles after the spacing of the mixing partitions 2 is adjusted. The other side of the extension bracket 31 is fixedly connected to a fixed guide groove 34. The outer surface of the fixed guide groove 34 is fixedly connected to an outward protruding plate 341. The outer surface of the extension bracket 31 is fixedly connected to a shaft connecting seat 35, which is fixed in the mixing chamber 11 to maintain a high position and provide support.
[0063] The top surfaces of the extension slot plate 322, the side fan plate 33, and the folding fan plate 332 are all provided with limiting guide grooves 321. The top surface of the top mounting base 23 is also provided with limiting guide grooves 321. The folding fan plates 332 are stacked on top of each other and slidably connected. There are three fan plate shafts 331, and the outer surface of each fan plate shaft 331 is rotatably connected to two symmetrically distributed side fan plates 33 and four folding fan plates 332.
[0064] By setting the adjustable slide rail 3, during use, the extension bracket 31 raises the entire adjustable slide rail 3 structure from above the top mounting base 23, so as not to let the limiting guide groove 321 sink into the powder.
[0065] There are four extension brackets 31, which are connected in sequence to form a complete guide rail through hinged slot plate 32, extension slot plate 322, side fan plate 33, and folding fan plate 332. When the proportioning partition 2 inside the raw material bin 1 rotates to adjust the size of the compartment, the distance between the top mounting seats 23 on both sides of the fan plate shaft 331 changes. Since the top mounting seats 23 are hinged to the hinged slot plate 32, the distance can be adjusted by folding to adapt to the change in distance after rotation. The other end of the hinged slot plate 32 is also hinged to the side fan plate 33 through the extension slot plate 322. After the distance changes, the side fan plate 33 will be raised or lowered to adapt to the new hinge angle. The extension slot plate 322 can extend and retract to adapt to the length of the side fan plate 33 after it is raised or lowered. The four folding fan plates 332 are rotatably connected to the side fan plates 33 through the fan plate shaft 331. When the distance changes, the folding fan plates 332 are stacked on each other in different numbers to adapt to the new distance, so that the connection is maintained regardless of the distance change after the proportioning partition 2 is rotated.
[0066] Limiting guide grooves 321 are provided on the top mounting base 23, hinged groove plate 32, extension groove plate 322, side fan plate 33, folding fan plate 332 and fixed guide groove 34 as guide rail channels for the smoothing mechanism 5 and adsorption mechanism 6 to rise and fall.
[0067] When the hinged slot plate 32 changes the height of the side fan plate 33 due to rotation, that is, when the spacing and volume decrease, the height of the side fan plate 33 is lower. Then, the adsorption mechanism 6 will descend to a lower level when passing through to enhance the adsorption effect. Since the smaller volume is caused by a smaller bottom area, the amount of powder per unit thickness is less. When the adsorption mechanism 6 adsorbs the powder, the overall height of the powder decreases faster. Then, the adsorption mechanism 6 descends to a lower level simultaneously to adsorb more powder. In the case of a large volume, since the powder descends slowly, the adsorption mechanism 6 does not need to descend excessively, so that the structural components cooperate with each other and are logically consistent.
[0068] The descending drive shaft 4 includes a servo motor 41, which is fixedly connected to the inner surface of the central column 12. The output end of the servo motor 41 is fixedly connected to a fixed inner shaft 411. A lifting outer shaft 42 is slidably connected to the outer surface of the fixed inner shaft 411. An outer groove 421 is provided on the outer surface of the lifting outer shaft 42. A top baffle 422 is fixedly connected to the outer surface of the lifting outer shaft 42. Symmetrically distributed lifting connecting frames 423 are slidably connected to the outer surface of the lifting outer shaft 42. The symmetrical lifting connecting frames 423 are respectively connected to the smoothing mechanism 5 and the adsorption mechanism 6, which work synchronously and do not contact each other. A side mounting seat 44 is fixedly connected to the outer surface of the lifting connecting frame 423. An adapting slide rod 441 is slidably connected to the top surface of the side mounting seat 44. A compression spring 442 is fixedly connected to the bottom surface of the adapting slide rod 441. A contact ball head rod 443 is fixedly connected to the bottom surface of the compression spring 442 for contacting the limiting guide groove 321 to achieve lifting.
[0069] The lifting outer shaft 42 is fixedly connected to the shaft connecting seat 35, and the fixed inner shaft 411 is connected to the lifting outer shaft through inner and outer splines. The sliding rod 441 slides horizontally on the top surface of the side mounting seat 44, and the contact ball head rod 443 slides on the inner surface of the limiting guide groove 321.
[0070] With the setting of the descending drive shaft 4, during use, the servo motor 41 drives the lifting outer shaft 42 to rotate through the fixed inner shaft 411. Since they are connected by inner and outer splines, the lifting outer shaft 42 can rise and fall in the vertical direction. The lifting outer shaft 42 is connected to the extension bracket 31 through the shaft connecting seat 35. The extension bracket 31 will descend synchronously with the powder height, and the lifting outer shaft 42 will also descend synchronously, so that the relative distance between the smoothing mechanism 5 and the adsorption mechanism 6 on the lifting outer shaft 42 and the top mounting seat 23 remains unchanged. Thus, the adsorption and smoothing are always above the powder and maintain a close distance.
[0071] During the rotation of the lifting outer shaft 42, it drives the lifting connecting frames 423 on both sides to rotate synchronously. The lifting connecting frames 423 on both sides are respectively equipped with the smoothing mechanism 5 and the adsorption mechanism 6. The two mechanisms work symmetrically at the same time. After adsorbing the powder, the smoothing mechanism 5 will smooth the powder surface to prevent the depression after adsorption from reducing the adsorption effect next time.
[0072] The lifting connecting frame 423 contacts the limiting guide groove 321 through the contact ball rod 443 in the side mounting seat 44. The limiting guide groove 321 forms an alternating lifting process through the top mounting seat 23, hinged groove plate 32, extension groove plate 322, side fan plate 33, folding fan plate 332 and fixed guide groove 34. When the contact ball rod 443 lifts and lowers in the limiting guide groove 321, it will drive the lifting connecting frame 423 to lift and lower synchronously, so that the smoothing mechanism 5 and the adsorption mechanism 6 can lift and lower to contact the powder or pass through the proportioning partition 2 from above.
[0073] The side mounting base 44 rotates horizontally along the lifting outer shaft 42 in a circular path, while the limiting guide groove 321 has a rectangular trajectory in the horizontal direction. The adapting slide rod 441 can slide horizontally at the bottom of the side mounting base 44 to adapt to different distances between the circle and the rectangle. The compression spring 442 allows the ball head rod 443 to rise and fall within a certain range to adapt to the height difference at the connection of the top mounting base 23, the hinged groove plate 32, the extension groove plate 322, the side fan plate 33, the folding fan plate 332, and the fixed guide groove 34.
[0074] The smoothing mechanism 5 includes a side connecting column 51, which is fixedly connected to the outer surface of the lifting connecting frame 423. A serrated wall 52 is fixedly connected to the bottom surface of the side connecting column 51, and a flat wall 53 is fixedly connected to the bottom surface of the side connecting column 51.
[0075] With the smoothing mechanism 5 in place, during use, the serrated wall 52 and the flat wall 53 are installed on the opposite connecting column 51. During rotation, the serrated wall 52 is in front of the flat wall 53 and comes into contact with the powder first. The groove of the serrated wall 52 digs out multiple grooves in the powder, converting the deep depressions after adsorption by the adsorption mechanism 6 into multiple shallow depressions. Then, the flat wall 53 smooths out the multiple shallow depressions, thus achieving the effect of removing the deep depressions after adsorption by the adsorption mechanism 6.
[0076] The adsorption mechanism 6 includes an actuation chamber 61, which is fixedly connected to a lifting connecting frame 423. A drive chamber 611 is fixedly connected to the outer surface of the actuation chamber 61. A motor bracket 612 is fixedly connected to the top surface of the drive chamber 611. A drive motor 62 is slidably connected to the inner surface of the motor bracket 612. A lifting connecting shaft 621 is fixedly connected to the bottom surface of the drive motor 62. A return spring 622 is sleeved on the outer surface of the lifting connecting shaft 621. A rotation output seat 63 is rotatably connected to the inner surface of the drive chamber 611. The drive motor 62 controls whether it rotates synchronously with the rotation output seat 63 by its own height. A connecting crank 64 is fixedly connected to the bottom surface of the rotation output seat 63. A toggle slider 641 is slidably connected to the bottom surface of the connecting crank 64. The inner surface of the drive chamber 611 is slidably connected to... There is a piston rod 65, one end of which is fixedly connected to a piston head 651. When the output seat 63 rotates, it drives the connecting crank 64 to make the slider 641 reciprocate. The inner surface of the execution cavity 61 is fixedly connected to symmetrically distributed inner petal supports 66. The outer surface of the inner petal supports 66 has a notch 661. The outer surface of the inner petal supports 66 is fixedly connected to an elastic fixed petal 663. The inner surface of the inner petal supports 66 is fixedly connected to a petal spring 662. The other end of the petal spring 662 is fixedly connected to an elastic movable petal 664. The upper and lower distributed elastic movable petals 664 change their volume according to the piston head 651 and open and close alternately to produce an adsorption effect. The top surface of the execution cavity 61 is fixedly connected to an output pipe 67, and the bottom surface of the execution cavity 61 is fixedly connected to an input pipe 671.
[0077] The lifting connecting shaft 621 is connected to the rotating output seat 63 by internal and external splines. The connecting crank 64 slides horizontally on the inner surface of the actuating slider 641. The piston head 651 is slidably connected to the inner surface of the actuating cavity 61 and slides laterally. The elastic fixed petal 663 and the elastic movable petal 664 are symmetrically distributed on the inner surface of the actuating cavity 61 but in the same direction. The elastic fixed petal 663 and the elastic movable petal 664 are made of rubber.
[0078] With the adsorption mechanism 6 in place, during use, the execution chamber 61 also rotates with the lifting outer shaft 42 and the lifting connecting frame 423. During this process, the piston structure in the execution chamber 61 and the drive chamber 611 generates suction to adsorb the powder. The drive motor 62 drives the rotating output seat 63 to rotate through the lifting connecting shaft 621. The bottom connecting crank 64 and the sliding block 641 form a crank-slider structure to reciprocate and slide, and drive the piston rod 65 and the piston head 651 to reciprocate inside the execution chamber 61.
[0079] The execution chamber 61 is equipped with a symmetrical and oriented inner flap support 66, an elastic fixed flap 663 and an elastic movable flap 664. The elastic movable flap 664 is located above the elastic fixed flap 663. The inner flap support 66 and the elastic fixed flap 663 are both provided with notches and grooves 661. The elastic movable flap 664 and the inner flap support 66 are connected by a flap spring 662 and can move up and down within a certain range. When the piston head 651 moves back and forth, the volume inside the execution chamber 61 will periodically increase and decrease.
[0080] When the volume increases, suction is generated, and the upper and lower elastic movable petals 664 are simultaneously drawn inward. However, the upper elastic movable petal 664 cannot be moved downward, blocking the notch 661 and generating negative pressure to draw the bottom powder from the input pipe 671 into the execution chamber 61. At the same time, the lower elastic movable petal 664 is also drawn upward and opened, opening the notch 661 on the elastic fixed petal 663 and the inner petal support 66. The powder gradually enters the execution chamber 61 from the notch 661. At this time, the powder is temporarily stored between the elastic movable petals 664.
[0081] When the volume decreases, a thrust is generated, and the two elastic movable flaps 664 are pushed outward. At this time, the lower elastic movable flap 664 cannot be pushed downward, blocking the notch 661 on the elastic fixed flap 663 and the inner flap support 66. Only the upper elastic movable flap 664 is pushed upward, pushing the powder temporarily stored inside into the output pipe 67. Then the powder enters the buffer shell 71 from the output pipe 67.
[0082] Since the piston head 651, which changes volume, is located on the side of the powder path, the end point of the powder will not be located at the piston head 651 (common wind-powered adsorption requires adding a filter screen to intercept the wind source, but the effect of powder interception is not good). The piston head 651 can slide multiple times to generate multiple adsorption forces to collect the powder.
[0083] The lifting connecting shaft 621 of the drive motor 62 is also connected to the rotary output seat 63 through internal and external splines. The drive motor 62 can drive the lifting connecting shaft 621 to rise and fall to disengage, so that the rotary output seat 63 does not rotate. When the drive motor 62 rises with the execution cavity 61 to the height of the lifting outer shaft 42, it will contact the top baffle 422 and be pressed down. The lifting connecting shaft 621 descends relative to the rotary output seat 63, and the internal and external splines are no longer connected. The rotary output seat 63 stops rotating, so that the adsorption mechanism 6 does not generate suction when it is at a high position.
[0084] The collection chamber 7 includes a buffer shell 71, which is fixedly connected to the outer surface of the execution chamber 61. A bottom shell 72 is fixedly connected to the bottom surface of the buffer shell 71. A bottom slide 73 is slidably connected to the inner surface of the bottom shell 72. An output groove 731 is opened on the outer surface of the bottom slide 73. A slide spring 732 is fixedly connected to the outer surface of the bottom slide 73.
[0085] The input pipe 671 passes through the buffer housing and the bottom. The bottom slide 73 is slidably connected to the outer protrusion plate 341. The two sides of the slide spring 732 are fixedly connected to the sliding base and the bottom housing 72, respectively.
[0086] With the collection chamber 7 in place, during use, the input pipe 671 passes through the buffer shell 71, and the powder enters the buffer shell 71 through the output pipe 67 for buffering. The bottom slide 73 inside the bottom shell 72 can slide. In the initial state, the bottom slide 73 is located on the inner wall of the buffer shell 71. When the buffer shell 71 moves to the fixed guide groove 34 of the mixing chamber 11, it will contact the outer protrusion 341 and make the output groove 731 below the powder, outputting the powder. After it is separated from the outer protrusion 341, the slide spring 732 drives the bottom slide 73 to reset.
[0087] In this embodiment, as Figure 1 , Figure 2 As shown, the raw material bin 1 and the mixing bin 11 are used to buffer raw materials and output raw materials, respectively, and the interior is used to install components;
[0088] In this embodiment, as Figure 3 , Figure 4 As shown, the raw material bin 1 and the mixing bin 11 form a complete cylinder, occupying three-quarters and one-quarter of the cylinder respectively, and the raw material bin 1 and the mixing bin 11 are separated.
[0089] In this embodiment, as Figure 5 , Figure 6 As shown, the proportioning partition 2 can rotate within the raw material silo 1 to adjust the size of the compartment, and the folding lifting plate 22 can be raised and lowered to adapt to different powder heights;
[0090] In this embodiment, as Figure 7As shown, the adjustable slide rail 3 is positioned at the top of the proportioning partition 2 to prevent it from being submerged in the powder.
[0091] In this embodiment, as Figure 8 As shown, the bottom opening of the mixing chamber 11 is used for output;
[0092] In this embodiment, as Figure 9 , Figure 10 , Figure 11 As shown, the components inside the adjustable slide rail 3 are hinged to each other. When the partition plate 2 adjusts the size of the compartment, the adjustable slide rail 3 bends and folds synchronously to adapt to the new spacing. After folding, the overall depth and angle change.
[0093] In this embodiment, as Figure 12 , Figure 13 As shown, the descending drive shaft 4 contacts the top of the adjustable slide rail 3 and rises and falls with the adjustable slide rail 3, and the smoothing mechanism 5 and the adsorption mechanism 6 are respectively connected to both sides.
[0094] In this embodiment, as Figure 14 As shown, the ball-contacting rod 443 contacts the limiting guide groove 321 and can move in the horizontal direction;
[0095] In this embodiment, as Figure 15 As shown, the descending drive shaft 4 moves up and down synchronously with the folding lifting plate 22, so that the relative distance between the smoothing mechanism 5 and the adsorption mechanism 6 and the top mounting seat 23 remains unchanged. Do not change the lifting and lowering height of the adjustable slide rail 3. The lifting and lowering height of the adjustable slide rail 3 is only related to the distance.
[0096] In this embodiment, as Figure 16 , Figure 17 As shown, the smoothing mechanism 5 and the adsorption mechanism 6 are connected to the two sides of the lifting outer shaft 42 respectively. The smoothing mechanism 5 uses the groove of the serrated wall 52 to dig out multiple grooves from the powder, and then the flat wall 53 smooths out the multiple shallow depressions.
[0097] In this embodiment, as Figure 18 As shown, the adsorption mechanism 6 is connected to the collection chamber 7;
[0098] In this embodiment, as Figure 19 , Figure 20 As shown, the adsorption mechanism 6 is driven by the internal structure of the drive chamber 611 to operate the internal structure of the execution chamber 61. The internal volume is periodically controlled by the piston head 651, so that the upper and lower elastic movable petals 664 open and close alternately. When the bottom elastic movable petal 664 opens, it generates suction to draw in the powder. When the top elastic movable petal 664 opens, it outputs the powder backward.
[0099] In this embodiment, as Figure 21As shown, the notch 661 of the elastic fixed flap 663 is used for powder to pass through, while the elastic movable flap 664 does not have the notch 661, thereby controlling the opening and closing of the notch 661.
[0100] In this embodiment, as Figure 22 , Figure 23 As shown, after the drive motor 62 descends, it will not rotate synchronously with the rotation output seat 63;
[0101] In this embodiment, as Figure 24 As shown, the powder enters the execution chamber 61 through the input pipe 671, and then enters the buffer shell 71 through the output pipe 67.
[0102] In this embodiment, as Figure 26 As shown, when the buffer housing 71 moves to the outer protrusion 341, it pushes the bottom slide 73.
[0103] The invention relates to a device for preparing freeze-dried powder of an anti-fatigue deer placenta composition and its usage method. The working process is as follows:
[0104] like Figures 1 to 26 As shown, during use, the two proportioning partitions 2 inside the raw material silo 1 divide the silo into three compartments, which store different deer placenta composition raw material powders respectively. The proportioning partitions 2 can be rotated to adjust the bottom area and volume of each compartment, thereby changing the time it takes for the adsorption mechanism 6 to pass through a single compartment. Since the compartment volume is directly proportional to the amount of adsorption per time, the total amount of each raw material changes synchronously with the consumption rate, ensuring that the powder in the three compartments can be consumed at the same time, thus achieving powder proportioning.
[0105] The servo motor 41 drives the adsorption mechanism 6 and the smoothing mechanism 5 to rotate at a constant speed through the descending drive shaft 4. The adsorption mechanism 6 generates periodic suction by reciprocating piston motion. The powder is drawn from the input pipe 671 into the execution chamber 61 for temporary storage by the opening and closing control of the elastic movable flap 664. The lifting outer shaft 42 is connected to the adjustable slide rail 3 through the shaft connecting seat 35, and can descend synchronously with the height of the powder surface, so that the adsorption port always keeps close to the powder and ensures stable adsorption effect.
[0106] When the piston moves in the reverse direction, it pushes the temporarily stored powder into the output pipe 67 and into the buffer shell 71 for temporary storage. At the same time, the smoothing mechanism 5 immediately processes the powder surface after adsorption. The serrated wall 52 first changes the deep depressions formed by adsorption into multiple shallow grooves, and the flat wall 53 then smooths the shallow grooves to prevent the depressions from affecting the adsorption effect next time. The adsorption mechanism 6 and the smoothing mechanism 5 work synchronously through the symmetrically distributed lifting connecting frame 423 to achieve adsorption and smoothing at the same time.
[0107] When the collection chamber 7 rotates above the mixing chamber 11 along with the adsorption mechanism 6, the bottom slide 73 contacts the outer protrusion 341 on the fixed guide groove 34 and generates a sliding displacement, so that the output groove 731 is aligned with the mixing chamber 11, and the powder is automatically released to complete the feeding. After detaching from the outer protrusion 341, the slide spring 732 drives the bottom slide 73 to reset and re-close the buffer shell 71. The entire device adapts to the spacing changes after the partition rotates through the folding and telescopic structure of the adjustable slide rail 3, realizing continuous automated operation.
[0108] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.
Claims
1. A device for preparing freeze-dried powder of an anti-fatigue deer placenta composition, comprising a raw material silo (1), a mixing chamber (11) fixedly connected to the outer surface of the raw material silo (1), a central column (12) fixedly connected to the inner surface of the raw material silo (1), and a top end cap (13) fixedly connected to the top surface of the mixing chamber (11); characterized in that: The inner surface of the raw material bin (1) is provided with a proportioning partition (2) for adjusting the total amount of different raw materials and the amount of adsorption per time; the top surface of the proportioning partition (2) is provided with an adjustable slide rail (3) to adjust the descent depth during adsorption according to the different spacing of the proportioning partition (2); the inner surface of the central column (12) is provided with a descending drive shaft (4) to adjust the height of the upper part according to the powder height and make it rotate; the outer surface of the descending drive shaft (4) is provided with a smoothing mechanism (5) to smooth the adsorbed powder to prevent dents from affecting the next adsorption effect; the outer surface of the descending drive shaft (4) is provided with an adsorption mechanism (6) to generate suction from the side to suck up the powder; the outer surface of the adsorption mechanism (6) is provided with a collection bin (7).
2. The apparatus for preparing an anti-fatigue deer placenta composition freeze-dried powder according to claim 1, characterized in that: The proportioning partition (2) includes an inner baffle (21), which is slidably connected to the inner surface of the raw material silo (1). A contact ball protrusion (211) is fixedly connected to the outer surface of the inner baffle (21). An annular guide groove (212) is provided on the outer surface of the raw material silo (1). The inner baffle (21) is slidably connected to the annular guide groove (212) through the contact ball protrusion (211) to limit the sliding path. A folding lifting plate (22) is slidably connected to the inner surface of the inner baffle (21). A top mounting seat (23) is fixedly connected to the top surface of the folding lifting plate (22). Side support plates (231) are fixedly connected to both sides of the top mounting seat (23). The folding lifting plate (22) is folded and lifted to match different powder heights and change the height of the top mounting seat (23).
3. The apparatus for preparing freeze-dried powder of anti-fatigue deer placenta composition according to claim 2, characterized in that: The adjustable slide rail (3) includes an extension bracket (31), which is fixedly connected to the top surface of the top mounting base (23); the outer surface of the extension bracket (31) is hinged to a hinged groove plate (32), and a limit guide groove (321) is formed on the top surface of the hinged groove plate (32). The extension bracket (31) raises the overall height of the adjustable slide rail (3) to prevent the limit guide groove (321) from sinking into the powder. The inner surface of the hinged groove plate (32) is slidably connected to an extension groove plate (322) to adapt to different spacings of the mixing partition (2) and match the required height; one end of the extension groove plate (322) A side fan plate (33) is fixedly connected. One end of the side fan plate (33) is rotatably connected to a fan plate shaft (331). A folding fan plate (332) is rotatably connected to the outer surface of the fan plate shaft (331). The foldable fan plate (332) can adapt to different angles after the spacing of the proportioning partition (2) is adjusted. A fixed guide groove (34) is fixedly connected to the other side of the extension bracket (31). An outer protruding plate (341) is fixedly connected to the outer surface of the fixed guide groove (34). A shaft connecting seat (35) is fixedly connected to the outer surface of the extension bracket (31). It is fixed in the mixing chamber (11) to maintain a high position and provide support.
4. The apparatus for preparing an anti-fatigue deer placenta composition freeze-dried powder according to claim 3, characterized in that: The descending drive shaft (4) includes a servo motor (41), which is fixedly connected to the inner surface of the central column (12). The output end of the servo motor (41) is fixedly connected to a fixed inner shaft (411), and a lifting outer shaft (42) is slidably connected to the outer surface of the fixed inner shaft (411). The fixed inner shaft (411) is connected by internal and external splines to drive the lifting outer shaft (42) to rotate, while the lifting outer shaft (42) can move in the vertical direction. An outer groove (421) is provided on the outer surface of the lifting outer shaft (42), and a top baffle (422) is fixedly connected to the outer surface of the lifting outer shaft (42). The outer surface of the lifting outer shaft (42) is slidably connected to symmetrically distributed lifting connecting frames (423). The symmetrical lifting connecting frames (423) are respectively connected to the smoothing mechanism (5) and the adsorption mechanism (6), which work synchronously and do not contact each other. The outer surface of the lifting connecting frame (423) is fixedly connected to a side mounting seat (44). The top surface of the side mounting seat (44) is slidably connected to an adapting slide rod (441). The bottom surface of the adapting slide rod (441) is fixedly connected to a compression spring (442). The bottom surface of the compression spring (442) is fixedly connected to a contact ball head rod (443), which is used to contact the limiting guide groove (321) to achieve lifting.
5. The apparatus for preparing freeze-dried powder of anti-fatigue deer placenta composition according to claim 4, characterized in that: The smoothing mechanism (5) includes a side connecting column (51), which is fixedly connected to the outer surface of the lifting connecting frame (423). A serrated wall (52) is fixedly connected to the bottom surface of the side connecting column (51), and a flat wall (53) is fixedly connected to the bottom surface of the side connecting column (51).
6. The apparatus for preparing an anti-fatigue deer placenta composition freeze-dried powder according to claim 5, characterized in that: The adsorption mechanism (6) includes an actuation chamber (61), which is fixedly connected to a lifting connecting frame (423). A drive chamber (611) is fixedly connected to the outer surface of the actuation chamber (61). A motor bracket (612) is fixedly connected to the top surface of the drive chamber (611). A drive motor (62) is slidably connected to the inner surface of the motor bracket (612). A lifting connecting shaft (621) is fixedly connected to the bottom surface of the drive motor (62). A return spring (622) is sleeved on the outer surface of the lifting connecting shaft (621). A rotating output seat (63) is rotatably connected to the inner surface of the drive chamber (611). A connecting crank (64) is fixedly connected to the bottom surface of the rotating output seat (63). A sliding block (641) is slidably connected to the bottom surface of the connecting crank (64). A piston rod (65) is slidably connected to the inner surface of the drive chamber (611). One end of the piston rod (65) is fixedly connected to a piston head (651). When the rotating output seat (63) rotates, it drives the connecting crank (64) to make the sliding block (641) reciprocate. The inner surface of the execution cavity (61) is fixedly connected to symmetrically distributed inner flap supports (66). The outer surface of the inner flap supports (66) is provided with a notch groove (661). The outer surface of the inner flap supports (66) is fixedly connected to an elastic fixed flap (663). The inner surface of the inner flap supports (66) is fixedly connected to a flap spring (662). The other end of the flap spring (662) is fixedly connected to an elastic movable flap (664). The upper and lower distributed elastic movable flaps (664) alternately open and close according to the direction of movement of the piston head (651) to generate an adsorption effect. The top surface of the execution cavity (61) is fixedly connected to an output pipe (67), and the bottom surface of the execution cavity (61) is fixedly connected to an input pipe (671).
7. The apparatus for preparing an anti-fatigue deer placenta composition freeze-dried powder according to claim 6, characterized in that: The collection chamber (7) includes a buffer shell (71), which is fixedly connected to the outer surface of the execution chamber (61). A bottom shell (72) is fixedly connected to the bottom surface of the buffer shell (71). A bottom slide (73) is slidably connected to the inner surface of the bottom shell (72). An output groove (731) is opened on the outer surface of the bottom slide (73). A slide spring (732) is fixedly connected to the outer surface of the bottom slide (73).
8. A method of using an apparatus for preparing an anti-fatigue deer placenta composition lyophilized powder, comprising using the apparatus for preparing an anti-fatigue deer placenta composition lyophilized powder as described in claim 7, characterized in that... The following steps are included: S1, the two proportioning partitions (2) inside the raw material warehouse (1) divide the warehouse into three compartments, which store different deer placenta composition raw material powders respectively. The proportioning partitions (2) can be rotated to adjust the bottom area and volume of each compartment, thereby changing the time of the adsorption mechanism (6) through a single compartment. Since the compartment volume is proportional to the single adsorption amount, the total amount of each raw material changes synchronously with the consumption rate, ensuring that the powder in the three compartments can be consumed at the same time, thus achieving powder proportioning. S2. The servo motor (41) drives the adsorption mechanism (6) and the smoothing mechanism (5) to rotate at a constant speed through the descending drive shaft (4). They pass through three raw material compartments in sequence. The adsorption mechanism (6) generates periodic suction by reciprocating piston motion. Through the opening and closing control of the elastic movable flap (664), the powder is sucked from the input pipe (671) into the execution chamber (61) for temporary storage. The lifting outer shaft (42) is connected to the adjustable slide rail (3) through the shaft connecting seat (35). It can descend synchronously with the height of the powder surface, so that the adsorption port always keeps close to the powder and ensures stable adsorption effect. S3. When the piston moves in the reverse direction, it pushes the temporarily stored powder into the output pipe (67) and enters the buffer shell (71) for temporary storage. At the same time, the smoothing mechanism (5) immediately processes the powder surface after adsorption. The serrated wall (52) first changes the deep depression formed by adsorption into multiple shallow grooves, and the flat wall (53) then smooths the shallow grooves to prevent the depression from affecting the adsorption effect next time. The adsorption mechanism (6) and the smoothing mechanism (5) work synchronously through the symmetrically distributed lifting connecting frame (423) to achieve adsorption and smoothing at the same time. S4. When the collection bin (7) rotates above the mixing bin (11) with the adsorption mechanism (6), the bottom slide (73) contacts the outer protrusion (341) on the fixed guide groove (34) and produces a sliding displacement, so that the output groove (731) is aligned with the mixing bin (11). The powder is automatically released to complete the feeding. After it leaves the outer protrusion (341), the slide spring (732) drives the bottom slide (73) to reset and re-close the buffer shell (71). The entire device adapts to the spacing change after the partition rotates through the folding and telescopic structure of the adjustable slide rail (3) to achieve continuous automated operation.