Probiotic powder bagging apparatus
By combining the feeding unit with the dual stirring blades and the screw rod, and the guide wheel with the heat sealing/cutting unit, the problem of powder agglomeration and clogging in the probiotic powder bagging equipment is solved, achieving uniform powder feeding and reliable sealing of the packaging bags, reducing equipment maintenance frequency and production costs.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU LVKEE BIOTECHNOLOGY CO LTD
- Filing Date
- 2025-08-23
- Publication Date
- 2026-07-14
Smart Images

Figure CN224491598U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of probiotic powder production technology, specifically to a probiotic powder bagging equipment. Background Technology
[0002] In the fields of fish farming and ornamental fish breeding, probiotic powder is an important feed additive. It significantly improves the health of fish by improving the aquatic environment, enhancing their digestive function and immunity. To realize the commercial distribution of probiotic powder, it needs to be quantitatively packaged by special bagging equipment after production to ensure the convenience of transportation, storage and use.
[0003] Currently, the bagging process for probiotic powder typically uses conventional powder loading equipment, such as screw conveyors or gravity feeding devices. However, in practical applications, the following technical drawbacks exist:
[0004] 1. Because probiotic powder contains active microbial components, it is easily affected by factors such as humidity and static electricity during transportation, forming clumps and causing blockage at the discharge port;
[0005] 2. When powder flows in the conveying pipeline or silo, it leaves residue due to its small particle size and easy adsorption to the inner wall of the equipment.
[0006] The above-mentioned problems collectively lead to the deterioration of powder flowability, requiring frequent shutdowns for maintenance and increasing production costs. Utility Model Content
[0007] To address the shortcomings of existing technologies, this utility model provides a probiotic powder bagging device, which solves the problems mentioned in the background art.
[0008] To achieve the above objectives, this utility model provides the following technical solution:
[0009] A probiotic powder bagging device includes: a shell, a guide component fixedly installed on the top of the front of the shell, a heat sealing unit assembled on the shell below the guide component, a guide unit assembled on the shell below the heat sealing unit, a cutting unit assembled on the shell below the guide unit, a second mounting frame fixedly installed on the top of the shell, a mounting cover fixedly installed on the second mounting frame, a material bucket fixedly installed together with the mounting cover and the guide component, and a feeding unit assembled inside the material bucket;
[0010] The guiding unit includes a second motor, a first shaft, a second rotating shaft, and a guide wheel. The first shaft and the second rotating shaft, which extend into the interior, are rotatably mounted on the front of the housing. The outer ends of the first shaft and the second rotating shaft are fixedly mounted with guide wheels, and the inner ends are fixedly mounted with meshing ring gear sets. The second motor is fixedly mounted inside the housing, and the output end of the second motor is equipped with a pulley that is connected to the first shaft for transmission.
[0011] The feeding unit includes a rotating shaft three, a stirring blade one, a screw rod, and a stirring blade two. A mounting sleeve is fixedly installed on the top of the material barrel. A rotating sleeve extending into the mounting sleeve is rotatably installed inside the material barrel. Stirring blade one and stirring blade two are fixedly installed on the bottom of the rotating sleeve respectively. A rotating shaft three extending into the material barrel is rotatably installed inside the mounting sleeve. A screw rod is fixedly installed on the bottom of the rotating shaft three.
[0012] Furthermore, a base is fixedly installed at the bottom of the housing, and guide plates are fixedly installed at the four corners of the bottom of the base. A guide plate is fixedly installed on the front of the housing, and the guide plate is located below the cutting unit.
[0013] Furthermore, the cutting unit includes a mounting bracket 1, a sliding rod 1, a connector 1, a cutting blade, a spring, a guide plate 1, and a cylinder 2. Two sets of mounting brackets 1 are fixedly installed on the front of the housing. Two sets of sliding rods 1 are fixedly installed between the mounting brackets 1. Guide plates 2 and 3 are installed on the sliding rods 1. Guide plates 1 are mounted on the mounting brackets 1 outside the guide plates 2. A spring connected to the guide plates 2 is fixedly connected to the guide plates 1. A push rod penetrating the guide plates 2 is fixedly connected to the guide plates 1. A connector 2 is fixedly installed on the inner side of the guide plates 2, and a cutting blade is fixedly installed at the end of the push rod, with the cutting blade located inside the connector 2. A connector 1 is fixedly installed on the inner side of the guide plates 3. A cylinder 2 is fixedly installed between the mounting bracket 1 and the guide plates 1 and 3.
[0014] Furthermore, the heat sealing unit includes a mounting plate 1, a heat sealing block 1, a heat sealing block 2, a cylinder 1, and a mounting base. Two sets of mounting bases are fixedly installed on the top of the front side of the housing. Two sets of sliding rods 2 are connected and installed between the mounting bases. Two sets of mounting plates 1 are fitted on the sliding rods 2. Heat sealing blocks 1 and 2 are fixedly installed on the corresponding surfaces of the mounting plates 1. A cylinder 1 is fixedly installed on the outside of the mounting base. The output end of the cylinder 1 passes through the mounting base and is installed and connected to the mounting plate 1.
[0015] Furthermore, the guiding component includes a support frame, a support frame is fixedly installed on the front of the housing, a second mounting plate is fixedly installed on the front of the support frame, a rubber guide roller and a drive roller are rotatably installed between the second mounting plates, a motor is installed on one side of the second mounting plate, a bevel gear set is assembled at the output end of the motor and is connected to the shaft end of the drive roller, a guide rod is fixedly installed at the bottom of the second mounting plate, a raw material rack is fixedly installed at the top of the support frame, and a guide nozzle is fixedly installed on the inner side of the support frame through a fixing frame.
[0016] Furthermore, both sides of the top of the material barrel are fixedly installed with a connecting inlet 1 and an inlet 2. The top of the mounting cover is fixedly connected with a motor 3 and a motor 4 respectively. The output end of the motor 3 is connected to a rotating shaft 4 that is rotatably connected to the material barrel. The rotating shaft 4 is equipped with a pulley 2 that is rotatably connected to the rotating sleeve. The mounting sleeve, the rotating shaft 3, and the rotating sleeve are all rotatably connected through bearing components.
[0017] This invention provides a probiotic powder bagging device. Compared with the prior art, it has the following advantages:
[0018] 1. The feeding unit enables the equipment to achieve the synergistic effect of double mixing blades and screw rod. The first mixing blade and the second mixing blade adopt a differentiated design to ensure that the powder in the material bucket is mixed without dead corners and avoids clumping or stratification.
[0019] The screw is driven independently and is separate from the mixing mechanism. The speed can be adjusted to adapt to the flowability of different powders, ensuring uniform feeding and no clogging.
[0020] 2. The guide wheels in the guide unit work in conjunction with the heat sealing / cutting unit to ensure the alignment and sealing reliability of the packaging bag. Attached Figure Description
[0021] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0022] Figure 1 A schematic diagram of the overall structure of this utility model is shown;
[0023] Figure 2 A schematic diagram of the guiding component structure of this utility model is shown;
[0024] Figure 3 A schematic diagram of the external structure of the material bucket of this utility model is shown;
[0025] Figure 4 A schematic diagram of the housing and heat-sealing unit structure of this utility model is shown;
[0026] Figure 5 A schematic diagram of the cutting unit structure of this utility model is shown;
[0027] Figure 6 A schematic diagram of the housing and guide unit structure of this utility model is shown;
[0028] Figure 7 This diagram shows a first structural schematic of the feeding unit of this utility model;
[0029] Figure 8 A schematic diagram of the second structure of the feeding unit of this utility model is shown;
[0030] As shown in the figure: 100, housing; 101, guide plate; 102, base;
[0031] 200. Cutting unit; 201. Mounting bracket one; 202. Slide rod one; 203. Connector one; 204. Cutting blade; 205. Spring component; 206. Guide plate one; 207. Cylinder two; 208. Push rod; 209. Guide plate two; 210. Connector two; 211. Guide plate three;
[0032] 300. Heat sealing unit; 301. Mounting plate one; 302. Heat sealing block one; 303. Heat sealing block two; 304. Cylinder one; 305. Mounting base; 306. Slide rod two;
[0033] 400. Guiding component; 401. Support frame; 402. Rubber guide roller; 403. Raw material rack; 404. Fixing frame; 405. Guide nozzle; 406. Motor 1; 407. Bevel gear set; 408. Mounting plate 2; 409. Guide rod; 410. Drive roller;
[0034] 500. Material bucket; 501. Mounting bracket two; 502. Mounting cover; 503. Injection port one; 504. Injection port two;
[0035] 600. Guiding unit; 601. Motor II; 602. Shaft I; 603. Ring gear set; 604. Rotating shaft II; 605. Guide wheel; 606. Belt pulley I;
[0036] 700. Feeding unit; 701. Rotating shaft three; 702. Stirring blade one; 703. Spiral rod; 704. Stirring blade two; 705. Rotating sleeve; 706. Belt pulley two; 707. Rotating shaft four; 708. Motor three; 709. Motor four; 710. Mounting sleeve; 711. Bearing components. Detailed Implementation
[0037] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions in the embodiments of this utility model are described clearly and completely. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of this utility model.
[0038] Example
[0039] To address the technical problems in the background section, the following probiotic powder bagging equipment is provided:
[0040] Combination Figures 1-8As shown, the present invention provides a probiotic powder bagging device, comprising: a housing 100, a guide component 400 fixedly installed on the top of the front side of the housing 100, a heat sealing unit 300 mounted on the housing 100 below the guide component 400, a guide unit 600 mounted on the housing 100 below the heat sealing unit 300, a cutting unit 200 mounted on the housing 100 below the guide unit 600, a mounting bracket 501 fixedly installed on the top of the housing 100, a mounting cover 502 fixedly installed on the mounting bracket 501, a material hopper 500 fixedly installed together with the guide component 400, and a feeding unit 700 assembled inside the material hopper 500; the guide unit 600 includes a motor 601, a shaft 602, a rotating shaft 604, and a guide wheel 605, and shafts 602 extending into the front side of the housing 100 are rotatably mounted on the front side of the housing 100. The second rotating shaft 604, the first shaft 602, and the outer ends of the second rotating shaft 604 are all fixedly installed with guide wheels 605, and the inner ends are fixedly installed with meshing ring gear sets 603. The second motor 601 is fixedly installed inside the housing 100. The output end of the second motor 601 is equipped with a pulley 606 that is connected to the first shaft 602 for transmission. The feeding unit 700 includes a third rotating shaft 701, a first stirring blade 702, a screw rod 703, and a second stirring blade 704. The top of the material tank 500 is fixedly installed with a mounting sleeve 710. The inside of the material tank 500 is rotatably installed with a rotating sleeve 705 that extends into the mounting sleeve 710. The bottom of the rotating sleeve 705 is fixedly installed with the first stirring blade 702 and the second stirring blade 704. The inside of the mounting sleeve 710 is rotatably installed with the third rotating shaft 701 that extends into the material tank 500. The bottom of the third rotating shaft 701 is fixedly installed with a screw rod 703.
[0041] Housing 100: The front is sequentially equipped with guide component 400, heat sealing unit 300, guide unit 600, and cutting unit 200; the top is fixed with mounting bracket 2 501 and mounting cover 502, which together with guide component 400 support material bucket 500;
[0042] Guide unit 600: Motor 2 601 drives shaft 1 602 to rotate through pulley 1 606. Shaft 1 602 and rotating shaft 2 604 are meshed through ring gear set 603 to achieve synchronous reverse rotation, which drives guide wheel 605 to clamp the edge of packaging bag for alignment and downward feeding;
[0043] Feeding unit 700: Rotary shaft 3 701 drives the screw rod 703 to rotate and convey powder; Rotary sleeve 705 is driven by motor 3 708 through belt pulley 2 706, which drives stirring blade 1 702 and stirring blade 2 704 to mix powder and clean the inner wall.
[0044] In this embodiment, a base 102 is fixedly installed at the bottom of the housing 100, and guide plates 101 are fixedly installed at the four corners of the bottom of the base 102. A guide plate 101 is fixedly installed on the front of the housing 100, and the guide plate 101 is located below the cutting unit 200.
[0045] Base 102: Guide plates 101 are provided at the four corners of the bottom to receive the cut packaging bags and guide them to the collection area;
[0046] Front guide plate 101: Located below the cutting unit 200, it ensures that the bag slides to the designated position after being cut; its function is to prevent the packaging bag from scattering and to achieve automated collection.
[0047] In this embodiment, the cutting unit 200 includes a mounting bracket 201, a sliding rod 202, a connector 203, a cutting blade 204, a spring 205, a guide plate 206, and a cylinder 207. Two sets of mounting brackets 201 are fixedly mounted on the front of the housing 100. Two sets of sliding rods 202 are fixedly mounted between the mounting brackets 201. Guide plates 209 and 311 are mounted on the sliding rods 202. Guide plates 206 are fitted onto the mounting brackets 201 outside the guide plates 209. A spring 205 connected to a guide plate 209 is fixedly connected to a guide plate 1 206. A push rod 208 passing through the guide plate 209 is fixedly connected to a guide plate 1 206. A connector 210 is fixedly installed on the inner side of the guide plate 209. A cutting blade 204 is fixedly installed at the end of the push rod 208 and is located inside the connector 210. A connector 1 203 is fixedly installed on the inner side of the guide plate 3 211. A cylinder 207 is fixedly installed between the mounting bracket 1 201 and the guide plates 1 206 and 3 211.
[0048] Cylinder 207 pushes guide plate 1 206 and guide plate 3 211 to move towards each other, and guide plate 209 buffers the pressure through spring 205;
[0049] Push rod 208 pushes cutting blade 204 through connector 210, and cooperates with connector 1 203 to complete the cutting;
[0050] Working process: After heat sealing, the packaging bag descends between the first connector 203 and the second connector 210. The second cylinder 207 is activated, and the spring 205 is compressed, causing the cutting blade 204 to cut the bag body at a uniform speed.
[0051] In this embodiment, the heat sealing unit 300 includes a mounting plate 301, a heat sealing block 302, a heat sealing block 303, a cylinder 304, and a mounting base 305. Two sets of mounting bases 305 are fixedly installed on the top of the front of the housing 100. Two sets of sliding rods 306 are connected between the mounting bases 305. Two sets of mounting plates 301 are fitted on the sliding rods 306. Heat sealing blocks 302 and 303 are fixedly installed on the corresponding surfaces of the mounting plates 301. A cylinder 304 is fixedly installed on the outer side of the mounting base 305. The output end of the cylinder 304 passes through the mounting base 305 and is installed and connected to the mounting plate 301.
[0052] Structural composition: Cylinder 304 pushes mounting plate 301 to move along slide bar 306, so that heat sealing block 302 and heat sealing block 303 are closed;
[0053] Heat sealing process: After the packaging bag is filled with powder through the feed nozzle 405, the cylinder 304 drives the heat sealing block to heat seal the bottom and sides of the bag; after the filling is completed, the top is heat sealed again to form a three-sided seal.
[0054] In this embodiment, the guide component 400 includes a support frame 401. The support frame 401 is fixedly installed on the front of the housing 100. A second mounting plate 408 is fixedly installed on the front of the support frame 401. A rubber guide roller 402 and a drive roller 410 are rotatably installed between the second mounting plates 408. A first motor 406 is installed on one side of the second mounting plate 408. The output end of the first motor 406 is equipped with a bevel gear set 407 that is connected to the shaft end of the drive roller 410. A guide rod 409 is fixedly installed at the bottom of the second mounting plate 408. A raw material rack 403 is fixedly installed at the top of the support frame 401. A guide nozzle 405 is fixedly installed on the inner side of the support frame 401 through a fixing frame 404.
[0055] Structural composition: Motor 406 drives drive roller 410 through bevel gear set 407, which cooperates with rubber guide roller 402 to pull packaging belt;
[0056] Guide rod 409 ensures the packaging tape is aligned, and feed nozzle 405 guides the powder injection;
[0057] Work process: The packaging tape is drawn out from the raw material rack 403, pulled down to the heat sealing position by the drive roller 410, and the guide nozzle 405 is inserted into the bag opening to supply material.
[0058] In this embodiment, two inlet ports 503 and 504 are fixedly installed on both sides of the top of the material barrel 500. The top of the mounting cover 502 is fixedly connected to the motor 708 and the motor 709 respectively. The output end of the motor 708 is connected to the rotating shaft 707 which is rotatably connected to the material barrel 500. The rotating shaft 707 is equipped with the pulley 706 which is pulsatorically connected to the rotating sleeve 705. The mounting sleeve 710 is rotatably connected to the rotating shaft 701 and the rotating sleeve 705 through the bearing 711.
[0059] Dual injection ports: Injection port 1 (503) and injection port 2 (504) can simultaneously inject different powders, which are then mixed by stirring blades 1 (702) and 2 (704).
[0060] Drive structure: Motor 3 708 drives the rotating sleeve 705 to stir via pulley 2 706; Motor 4 709 independently drives the rotating shaft 3 701 to drive the screw rod 703 to feed material;
[0061] Bearing component 711: Ensures the rotational stability of the rotating shaft 701 and the mounting sleeve 710, and the mounting sleeve 710 and the rotating sleeve 705.
[0062] Working principle and usage process of this utility model:
[0063] When in use, the packaging bag principle roller is set on 412. Initially, personnel need to pull the raw material bag between the guide rod 409, the drive roller 410, 411 and the guide nozzle 405. During the continuous operation of the packaging equipment, personnel then inject the feed into the feed tank 500 through the feed inlet 1 503 and the feed inlet 2 504. The advantage of the dual feed inlets is that it can increase the amount of feed injected and simultaneously inject two sets of feed that need to be mixed.
[0064] The second step is to start motor 3 708 if mixing is required. The output of motor 3 708 drives the rotating sleeve 705 to rotate through the pulley 2 706 on the rotating shaft 4 707. The rotating sleeve 705 rotates in the mounting sleeve 710, thereby driving the stirring blade 1 702 and stirring blade 2 704 to rotate, so as to stir and mix the powder in the material barrel 500. After the operation is completed, the rotation of stirring blade 1 702 and stirring blade 2 704 can be used again to clean the residual powder on the inner wall of the material barrel 500.
[0065] The third step, during bagging, starts motor 406, which drives drive roller 410 via bevel gear set 407. Drive roller 410 and guide rod 409 work together to guide the packaging tape downwards. The packaging tape wraps around the guide nozzle 405. Then, cylinder 304 is started. The output end of cylinder 304 pushes mounting plate 301, causing heat sealing blocks 302 and 303 between mounting plates 301 to mate and close. Then, heat sealing blocks 302 and 303 are electrically heated to heat and connect the folded packaging tape. In this way, the bottom and inner edge of the packaging tape are pressed and heat-sealed. Then, motor 709 is started to drive shaft 701 to rotate. Shaft 701 drives screw rod 703 to transport the powder in the material barrel 500 to the guide nozzle 405 and flow into the packaging bag in the heat-sealing section for filling.
[0066] Fourth step: After the filling is completed, start motor 601 drives shaft 602 to rotate through pulley 606. The inner end of shaft 602 uses ring gear set 603 to synchronously drive shaft 604, causing shaft 604 and shaft 602 to rotate synchronously in opposite directions. At that time, guide wheel 605 can clamp and guide the edge of the packaging bag. This can ensure that the packaging tape after filling and heat sealing is guided downward and can also limit and align the edge of the packaging tape.
[0067] After the packaging tape is filled and heat-sealed again, it descends. Then, cylinder 304 and heat-sealing block 302 are activated again to seal the top of the packaging tape, thus forming a three-sided heat seal. Finally, it continues to descend to between connector 210 and guide plate 311. Cylinder 207 is activated to drive guide plate 206 and guide plate 311. At that time, guide plate 206 pushes guide plate 209 and cutting blade 204 at the connecting end through push rod 208 and spring 205 until connector 210 and connector 203 are connected. Since the spring 205 between guide plate 209 and guide plate 206 is compressed, push rod 208 continues to push the cutting blade 204 at the end, causing the cutting blade 204 to cut the filled packaging bag to form an independent packaging bag, which falls into the guide plate 101 for discharge after cutting.
[0068] It is worth noting that the electrical components in this application, such as motors and cylinders, are existing and widely used in the field. Furthermore, the conveying, heat-sealing, and cutting processes in this application also exist, and for details, please refer to the JS-320C packaging machine. These are not within the scope of technical protection of this application.
[0069] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.
[0070] The above embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit it. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of this utility model.
Claims
1. A probiotic powder bagging device, characterized in that, Includes: a housing, a guide component fixedly installed on the top of the front of the housing, a heat sealing unit mounted on the housing below the guide component, a guide unit mounted on the housing below the heat sealing unit, a cutting unit mounted on the housing below the guide unit, a second mounting bracket fixedly installed on the top of the housing, a mounting cover fixedly installed on the second mounting bracket, a material bucket fixedly installed together with the mounting cover and the guide component, and a feeding unit assembled inside the material bucket; The guiding unit includes a second motor, a first shaft, a second rotating shaft, and a guide wheel. The first shaft and the second rotating shaft, which extend into the interior, are rotatably mounted on the front of the housing. The outer ends of the first shaft and the second rotating shaft are fixedly mounted with guide wheels, and the inner ends are fixedly mounted with meshing ring gear sets. The second motor is fixedly mounted inside the housing, and the output end of the second motor is equipped with a pulley that is connected to the first shaft for transmission. The feeding unit includes a rotating shaft three, a stirring blade one, a screw rod, and a stirring blade two. A mounting sleeve is fixedly installed on the top of the material barrel. A rotating sleeve extending into the mounting sleeve is rotatably installed inside the material barrel. Stirring blade one and stirring blade two are fixedly installed on the bottom of the rotating sleeve respectively. A rotating shaft three extending into the material barrel is rotatably installed inside the mounting sleeve. A screw rod is fixedly installed on the bottom of the rotating shaft three.
2. The probiotic powder bagging equipment according to claim 1, characterized in that: A base is fixedly installed at the bottom of the housing, and guide plates are fixedly installed at the four corners of the bottom of the base. A guide plate is fixedly installed on the front of the housing, and the guide plate is located below the cutting unit.
3. The probiotic powder bagging equipment according to claim 1, characterized in that: The cutting unit includes a mounting bracket 1, a sliding rod 1, a connector 1, a cutting blade, a spring, a guide plate 1, and a cylinder 2. Two sets of mounting brackets 1 are fixedly installed on the front of the housing. Two sets of sliding rods 1 are fixedly installed between the mounting brackets 1. Guide plates 2 and 3 are installed on the sliding rods 1. Guide plates 1 are mounted on the mounting brackets 1 outside the guide plates 2. A spring connected to the guide plates 2 is fixedly connected to the guide plates 1. A push rod passing through the guide plates 2 is fixedly connected to the guide plates 1. A connector 2 is fixedly installed on the inner side of the guide plates 2, and a cutting blade is fixedly installed at the end of the push rod, with the cutting blade located inside the connector 2. A connector 1 is fixedly installed on the inner side of the guide plates 3. A cylinder 2 is fixedly installed between the mounting bracket 1 and the guide plates 1 and 3.
4. The probiotic powder bagging equipment according to claim 3, characterized in that: The heat sealing unit includes a mounting plate 1, a heat sealing block 1, a heat sealing block 2, a cylinder 1, and a mounting base. Two sets of mounting bases are fixedly installed on the top of the front of the housing. Two sets of sliding rods 2 are connected and installed between the mounting bases. Two sets of mounting plates 1 are fitted on the sliding rods 2. Heat sealing blocks 1 and 2 are fixedly installed on the corresponding surfaces of the mounting plates 1. A cylinder 1 is fixedly installed on the outside of the mounting base. The output end of the cylinder 1 passes through the mounting base and is installed and connected to the mounting plate 1.
5. The probiotic powder bagging equipment according to claim 4, characterized in that: The guiding component includes a support frame. The support frame is fixedly installed on the front of the housing. Mounting plate two is fixedly installed on the front of the support frame. A rubber guide roller and a drive roller are rotatably installed between mounting plates two. Motor one is fixedly installed on one side of mounting plate two. A bevel gear set that is connected to the shaft end of the drive roller is assembled at the output end of motor one. A guide rod is fixedly installed at the bottom of mounting plate two. A raw material rack is fixedly installed at the top of the support frame. A guide nozzle is fixedly installed on the inner side of the support frame through a fixing frame.
6. The probiotic powder bagging equipment according to claim 1, characterized in that: Both sides of the top of the material barrel are fixedly installed with a connecting inlet 1 and an inlet 2. The top of the mounting cover is fixedly connected with a motor 3 and a motor 4. The output end of the motor 3 is connected to a rotating shaft 4 that is rotatably connected to the material barrel. The rotating shaft 4 is equipped with a pulley 2 that is rotatably connected to the rotating sleeve. The mounting sleeve, the rotating shaft 3, and the rotating sleeve are all rotatably connected through bearing components.