A device for cleaning kelp threads

By designing a kelp washing device, and utilizing high-pressure bubble impact and automated pushing and collecting technology, the problems of high labor intensity and low efficiency in the kelp washing process have been solved, achieving efficient and stable automated washing results.

CN224461066UActive Publication Date: 2026-07-07SHANXI LIUWEIZHAI HOLDING GROUP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANXI LIUWEIZHAI HOLDING GROUP CO LTD
Filing Date
2025-06-21
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

The current kelp processing and cleaning process is labor-intensive and inefficient, and the cleaning effect is greatly affected by human factors. Existing equipment cannot meet the requirements of high efficiency, stability and easy maintenance.

Method used

Design a kelp shred cleaning device that uses an air pump and air supply pipeline to form high-pressure bubble impact cleaning, and combines a swing arm assembly and a discharge device to achieve automated cleaning and collection. The device includes the design of a cleaning zone, a sedimentation zone and a discharge zone. The air pump supplies air to form high-pressure bubble impact cleaning, the swing arm assembly pushes the kelp shreds, and the discharge zone achieves automated drainage and collection.

Benefits of technology

It achieves all-round bubble impact cleaning of kelp strands, improving cleaning efficiency and cleanliness, reducing manual operation, realizing automated production, and reducing labor intensity and maintenance costs.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224461066U_ABST
    Figure CN224461066U_ABST
Patent Text Reader

Abstract

The utility model belongs to food processing equipment technical field, concretely relates to a kelp silk cleaning device, including overall frame, cleaning device, conveying device, discharge device and electric cabinet, wherein: overall frame is used for bearing cleaning device, conveying device and discharge device, cleaning device includes cleaning storehouse, is equipped with air pump on the outer wall of cleaning storehouse, is divided and is configured as cleaning area and sedimentation area in the inside of cleaning storehouse, is equipped with a plurality of exhaust pipes in the cleaning area, exhaust pipe is on the basis of intercommunication and is communicated with gas pipeline, and gas pipeline is communicated with air pump, conveying device includes swing arm subassembly and power component, discharge device is located in the output end of cleaning storehouse one side, and discharge device includes discharge storehouse, and the first cylinder and second cylinder of mutual cooperation are equipped above discharge storehouse, the utility model provides a kelp silk cleaning device, utilizes simple and easy device equipment to can complete to large quantities of kelp silk high -efficient automation's cleaning and collection.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model belongs to the technical field of food processing equipment, and specifically relates to a kelp washing device. Background Technology

[0002] Kelp is a major cultivated seaweed in my country, ranking first in the world in terms of production. Kelp strips, processed from kelp, are widely popular due to their rich nutrition and versatility in cooking. In the large-scale production of kelp strips, the cleaning process is the core step to ensure product quality, requiring the thorough removal of mucus, attached mud, and impurities from the surface of the kelp strips.

[0003] However, the existing processing flow has prominent problems: high dependence on manual operation: traditional cleaning processes require manual labor to repeatedly stir, wash and drain kelp strips in water tanks, which is labor-intensive and dense, resulting in low production efficiency. Moreover, the cleaning effect is greatly affected by human factors, making it difficult to guarantee the stability of product quality. Existing cleaning equipment has obvious defects: some cleaning machines use mesh bags or belt conveyors, which have problems such as complex cleaning processes, dead corners that cannot be thoroughly cleaned, and high maintenance costs. They cannot meet the needs of large-scale production for high efficiency, stability and easy maintenance.

[0004] The "low efficiency and low quality" of manual cleaning, coupled with the "high cost and low adaptability" of existing equipment, constitutes a technical bottleneck in the kelp shred processing and cleaning process. There is an urgent need for a kelp shred cleaning device that is simple in structure, low in cost, easy to maintain and clean, capable of large-scale processing, and can improve the cleaning effect and automation level, in order to solve problems such as labor intensity, low efficiency and unstable quality. Utility Model Content

[0005] In view of this, the present invention provides a kelp washing device, which can complete the efficient and automated washing and collection process of large quantities of kelp using simple equipment, and can effectively solve the above-mentioned technical problems.

[0006] The technical solution provided by this utility model is as follows:

[0007] A kelp shred cleaning device includes: an overall frame, a cleaning device, a conveying device, a discharging device, and an electrical control box, wherein:

[0008] The overall frame is used to support the cleaning device, conveying device and discharging device, and the cleaning device, conveying device and discharging device are arranged in sequence.

[0009] A cleaning device includes a rectangular cleaning chamber with a long side and a short side. One short side is configured as an input end, and the other short side as an output end. A water inlet pipe is provided on the side wall of the input end for adding cleaning fluid to the cleaning chamber. Two air pumps are provided on the outer wall of one long side of the cleaning chamber, each connected to an air supply pipe that penetrates the side wall of the cleaning chamber and extends into its interior. Furthermore, the interior space of the cleaning chamber is divided into two sections along the extension direction of the long side. The system includes a washing zone and a sedimentation zone, with the two washing zones located on opposite sides of the sedimentation zone. Each washing zone contains several equally spaced and uniformly arranged exhaust pipes, which are interconnected and connected to the gas supply pipeline. Each exhaust pipe has several equally spaced and uniformly arranged air outlets. In addition, the washing chamber is equipped with a water filter plate, and the inner wall of the washing chamber is provided with a support boss. The water filter plate is positioned above the exhaust pipes via the support boss, and the water filter plate has several water filter holes.

[0010] The conveying device includes a swing arm assembly disposed on top of the cleaning chamber and a power assembly disposed on one side of the cleaning chamber, wherein:

[0011] The swing arm assembly includes several rotating shafts that are parallel to each other and evenly arranged on the top of the cleaning chamber. The extension direction of the rotating shafts is the same as the extension direction of the short side of the cleaning chamber. Each rotating shaft is connected to a fork pushing mechanism. The fork pushing mechanism includes a set of actuating plates fixed on the rotating shaft. A locking interface is provided on the side of the set of actuating plates away from the rotating shaft. The opening direction of the locking interface is the same as the extension direction of the long side of the cleaning chamber and faces the output end of the cleaning chamber. On this basis, a connecting plate is rotatably connected to each actuating plate above the locking interface. A fork is fixedly connected to the end of the connecting plate. The position of the fork corresponds to the locking interface. In addition, the swing arm assembly also includes a swing tube fixed on each rotating shaft. Several swing tubes are simultaneously rotatably connected to a crossbeam.

[0012] The power assembly includes a geared motor and a crank-rocker mechanism. The crank-rocker mechanism includes an eccentric wheel, a first connecting rod, and a second connecting rod. The center of the eccentric wheel is fixedly connected to the output end of the geared motor. An eccentric shaft is provided on the eccentric wheel. The eccentric shaft is rotatably connected to the end of the first connecting rod. The other end of the first connecting rod is connected to one end of the second connecting rod. The other end of the second connecting rod is fixedly connected to any one of the rotating shafts.

[0013] The discharge device is located on one side of the output end of the cleaning chamber. The discharge device includes a discharge chamber with a sloping bottom. The bottom of the discharge chamber is flush with the filter plate in the cleaning chamber. A loading platform is provided at the top of the discharge chamber. The loading platform is horizontally arranged. The discharge device also includes a first cylinder parallel to the bottom of the discharge chamber. The first cylinder is a magnetic couple rodless cylinder, including a cylinder seat. A piston rod is provided on the cylinder seat. A movable slider is sleeved on the piston rod. Several support rods are fixedly connected to the movable slider. The support rods extend vertically upward. The tops of the support rods are connected to a second cylinder. The second cylinder is perpendicular to the cleaning chamber. A first crossbar is connected to the piston end of the second cylinder. Several drain claws are provided on the first crossbar in a vertically downward direction.

[0014] An electrical control box is located on one side of the discharge device. The electrical control box is electrically connected to the air pump, the geared motor, the first cylinder, and the second cylinder. In addition, the electrical control box is also equipped with a touch control screen for controlling the operation of the air pump, the geared motor, the first cylinder, and the second cylinder.

[0015] Preferably, in the cleaning device, the inlet pipe is also equipped with a control valve to control the amount of cleaning liquid added to the cleaning chamber. Correspondingly, the cleaning chamber is also provided with an overflow port near the output end to collect the overflowing cleaning liquid.

[0016] Preferably, the cleaning chamber is also provided with a drain outlet at the location of the sedimentation zone.

[0017] Preferably, on the exhaust pipe, a plurality of air outlets are located at the top of the exhaust pipe for discharging the air supplied by the air pump toward the water filter plate.

[0018] Preferably, in the swing arm assembly, both ends of each rotating shaft are rotatably mounted on the side wall of the cleaning chamber via a bearing assembly. The bearing assembly includes a bearing seat fixedly mounted on the side wall of the cleaning chamber, and a rolling bearing is provided inside the bearing seat, with the rolling bearing sleeved on the end of the rotating shaft.

[0019] Preferably, in the fork pushing mechanism, the fork includes a second crossbar, the length of which is equal to the length of the short side of the cleaning chamber, and several actuating claws are fixedly provided below the second crossbar, with a gap always existing between the bottom end of the actuating claws and the bottom plate of the cleaning chamber.

[0020] Preferably, in the discharge device, a scraper is provided at the bottom of the movable slider, and a plurality of scraping holes are provided on the scraper. The plurality of scraping holes are matched one-to-one with a plurality of draining claws, and the scraping holes are always fitted on the outside of the draining claws during the entire process of the piston of the second cylinder moving vertically up and down.

[0021] Preferably, the electrical control box is also equipped with an emergency brake switch for emergency braking when the kelp washing device malfunctions.

[0022] The beneficial effects of this utility model are as follows:

[0023] This invention utilizes the cooperation of an air pump, an air supply pipe, and an exhaust pipe. Under the premise of air supply from the air pump, high-pressure gas is blown into the cleaning chamber through the air outlet to form high-pressure bubbles. This causes the cleaning liquid inside to rise and form an impact water flow, creating an all-round bubble impact cleaning of the kelp strands, thereby improving the cleanliness of the kelp strands.

[0024] Based on this, the present invention also provides a swing arm assembly at the top of the cleaning chamber. With the power assembly providing reciprocating swing power to the actuating plate, the actuating plate intermittently pushes the feed fork toward the output end of the cleaning chamber through the card interface. At this time, the feed fork will intermittently insert and push the kelp strips in the swing direction of the feed fork. During the swing and pushing process of the feed fork, on the one hand, the cleaning liquid is agitated, so that the cleaning liquid cleans the kelp strips more thoroughly, and on the other hand, the kelp strips are transported forward, realizing the automation of kelp strip cleaning.

[0025] In addition, this utility model also sets a discharge device at the output end of the cleaning chamber. When the conveying device gradually pushes the kelp strips to the output end of the cleaning chamber, the kelp strips are pushed upward along the inclined discharge chamber and drained by the cooperation of the first cylinder, the second cylinder and the draining claw, thus achieving the effect of automated cleaning of kelp strips and improving the cleaning efficiency of kelp strips. Attached Figure Description

[0026] 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.

[0027] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0028] Figure 2 This is a schematic diagram of the structure of the air pump connected to the exhaust pipe and the air delivery pipeline in this utility model;

[0029] Figure 3 This is a bottom view of the installation configuration of the exhaust pipe and the filter plate in this utility model.

[0030] Figure 4 This is a schematic diagram of the specific structure of the swing arm assembly in this utility model;

[0031] Figure 5 This is a schematic diagram of the specific structure of the power component in this utility model;

[0032] Figure 6 This is a schematic diagram of the operating state of the swing arm assembly in this utility model;

[0033] Figure 7 This is a schematic diagram of another operating state of the swing arm assembly in this utility model;

[0034] Figure 8 This is a partial structural diagram of the discharge device in this utility model. Detailed Implementation

[0035] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0036] In the description of this utility model, it should be noted that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," etc., indicating the orientation or positional relationship, are based on the orientation or positional relationship shown in the accompanying drawings and are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model; the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance. In addition, unless otherwise explicitly specified and limited, the terms "installed," "connected," and "linked" should be interpreted broadly. For example, it can be a fixed connection, a detachable connection, or an integral connection; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be a connection within two components. For those skilled in the art, the specific meaning of the above terms in this utility model can be understood according to the specific circumstances.

[0037] In this technical solution, such as Figure 1As shown, a kelp washing device includes: an overall frame 1, a washing device 2, a conveying device 3, a discharging device 4, and an electrical control box 5. The overall frame 1 supports the washing device 2, the conveying device 3, and the discharging device 4. The washing device 2, the conveying device 3, and the discharging device 4 are arranged in sequence.

[0038] like Figure 1 As shown, the cleaning device 2 includes a rectangular cleaning chamber 201. The cleaning chamber 201 includes a long side and a short side. One short side of the cleaning chamber 201 is configured as an input end 202 and the other short side is configured as an output end 203. A water inlet pipe 204 is provided on the side wall of the input end 202 for adding cleaning fluid into the cleaning chamber 201. A control valve 205 is also provided on the water inlet pipe 204 for controlling the amount of cleaning fluid added into the cleaning chamber 201. Correspondingly, the cleaning chamber 201 also has an overflow port 209 on the long side near the output end 203 for collecting the overflowing cleaning fluid.

[0039] In addition, the cleaning chamber 201 has two air pumps 6 on the outer wall of one long side. Each air pump 6 is connected to an air supply pipe 601, which penetrates the side wall of the cleaning chamber 201 and extends into the interior of the cleaning chamber 201. Figure 1-3 As shown, the overall space inside the cleaning chamber 201 is divided into two cleaning zones 7 and one sedimentation zone 8 along the extension direction of the long side. The two cleaning zones 7 are located on both sides of the sedimentation zone 8. Each cleaning zone 7 is provided with several vent pipes 602 that are evenly spaced and arranged in a uniform manner. The vent pipes 602 are interconnected and connected to the air supply pipe 601. Each vent pipe 602 is provided with several air outlets 603 that are evenly spaced and arranged in a uniform manner. The air outlets 603 are located at the top of the vent pipes 602. In addition, the cleaning chamber 201 is also provided with a water filter plate 206. The inner wall of the cleaning chamber 201 is also provided with a support boss 207. The water filter plate 206 is positioned above the vent pipes 602 through the support boss 207. The water filter plate 206 is provided with several water filter holes 210.

[0040] In this embodiment, kelp strips are placed into the cleaning chamber 201 by the worker at the input end 202 and discharged from the cleaning chamber 201 at the output end 203. The kelp strips are cleaned during the process from the input end 202 to the output end 203. Specifically, based on the cooperation of the air pump 6, the air supply pipe 601, and the exhaust pipe 602, with the air pump 6 supplying air, high-pressure gas is discharged towards the water filter plate 206 through the air outlet 603, and then blown into the cleaning chamber 201 through the water filter holes 210 to form high-pressure bubbles, thus cleaning the interior of the cleaning chamber 201. The liquid churns upwards, forming an impact water flow. Due to the design of the filter plate 206, on the one hand, the high-pressure gas ejected from the air outlet 603 can be diverted to the filter hole 210 and then sprayed onto the top of the filter plate 206. On the other hand, it prevents kelp strands from entering the gaps between the exhaust pipes 602 and creating cleaning dead corners. The filter plate 206 is installed by the support boss 207, which facilitates the replacement and cleaning of the filter plate 206. Based on the above structure, the cleaning chamber can ultimately perform all-round bubble impact cleaning of the kelp strands, improving the rinsing cleanliness of the kelp strands.

[0041] In addition, the setting of the cleaning zone 7 and the sedimentation zone 8 allows the kelp shreds to be cleaned by bubble impact in the cleaning zone 7, removing the mud and other impurities on the kelp shreds. At this time, the mud and other impurities will also be turbulent with the bubbles. Therefore, this application also sets up a sedimentation zone 8. When the kelp shreds along with the mud and other impurities move to the sedimentation zone 8, the cleaning liquid will tend to calm down, and the mud and other impurities will settle to the sedimentation zone 8. On this basis, this application also sets up a drain outlet 208 on the cleaning chamber 201 at the location of the sedimentation zone 8, which is used to discharge the mud and other impurities along with the cleaning liquid. At the same time, the drain outlet 208 is also used to collect and discharge the water in the cleaning chamber 201.

[0042] During the convenient cleaning process of kelp shreds in the aforementioned cleaning chamber 201, the movement of the kelp shreds from the input end 202 to the output end 203 is provided by the conveying device 3, such as... Figure 1 , Figure 4-7 As shown, the conveying device 3 includes a swing arm assembly 9 disposed on the top of the cleaning chamber 201 and a power assembly 10 disposed on one side of the cleaning chamber 201, wherein:

[0043] like Figure 1 , Figure 4-5 As shown, the swing arm assembly 9 includes several rotating shafts 901 that are parallel to each other and evenly arranged on the top of the cleaning chamber 201. The extension direction of the rotating shafts 901 is the same as the extension direction of the short side of the cleaning chamber 201. Both ends of each rotating shaft 901 are rotatably mounted on the side wall of the cleaning chamber 201 through a bearing assembly. The bearing assembly includes a bearing seat 907 fixedly mounted on the side wall of the cleaning chamber 201. The bearing seat 907 is provided with a rolling bearing inside, and the rolling bearing is sleeved on the end of the rotating shaft 901.

[0044] Each rotating shaft 901 is connected to a forklift pushing mechanism 902. The forklift pushing mechanism 902 includes a set of actuating plates 903 fixedly mounted on the rotating shaft 901. Each set of actuating plates 903 has a locking interface 904 on the side away from the rotating shaft 901. The opening direction of the locking interface 904 is the same as the extension direction of the long side of the cleaning chamber 201 and faces the output end of the cleaning chamber 201. Furthermore, each actuating plate 903 is rotatably connected to a connecting plate 905 above the locking interface 904. The end of the connecting plate 905 is fixedly connected to… The fork 906 is connected to the card interface 904. The fork 906 includes a second crossbar 910. The length of the second crossbar 910 is equal to the length of the short side of the cleaning chamber 201. Several actuating claws 911 are fixedly provided below the second crossbar 910. There is always a gap between the bottom end of the actuating claw 911 and the bottom plate of the cleaning chamber 201. In addition, the swing arm assembly 9 also includes a swing tube 908 fixedly provided on each rotating shaft 901. Several swing tubes 908 are simultaneously rotatably connected to a crossbeam 909.

[0045] like Figure 1 , Figure 5 As shown, the power assembly 10 includes a geared motor 1001 and a crank-rocker mechanism 1002. The crank-rocker mechanism 1002 includes an eccentric wheel 1003, a first connecting rod 1004, and a second connecting rod 1005. The center of the eccentric wheel 1003 is fixedly connected to the output end of the geared motor 1001. An eccentric shaft 1006 is provided on the eccentric wheel 1003. The eccentric shaft 1006 is rotatably connected to the end of the first connecting rod 1004. The other end of the first connecting rod 1004 is connected to one end of the second connecting rod 1005. The other end of the second connecting rod 1005 is fixedly connected to any rotating shaft 901.

[0046] Based on the above structure, the crank-rocker mechanism 1002 is a commonly used transmission form in the prior art. Specifically, in this application, when the geared motor 1001 starts and provides rotational power, the eccentric wheel 1003 rotates around its center. At this time, the eccentric wheel 1003 is the driving crank in the existing crank-rocker mechanism, and the first connecting rod 1004 and the second connecting rod 1005 are the driven connecting rods in the existing crank-rocker mechanism. That is, when the eccentric wheel 1003 rotates, the second connecting rod 1005 is caused to reciprocate around the shaft 901 through the transmission action of the first connecting rod 1004. The shaft 901, which is fixedly connected to the second connecting rod 1005, is configured as... The active rotating shaft 901 performs a reciprocating rotational motion with a semi-circular trajectory. Since several rotating shafts 901 are fixedly connected to swing tubes 908, and several swing tubes 908 are simultaneously rotatably connected to a crossbeam 909, when the active rotating shaft actively performs a reciprocating rotational motion with a semi-circular trajectory, the swing tubes 908 on the active rotating shaft swing around the active rotating shaft as an axis. The swing tubes 908 on the active rotating shaft drive the crossbeam 909 to perform a reciprocating motion along the long side of the cleaning chamber 201. In turn, the crossbeam 909 drives all rotating shafts 901 to achieve a reciprocating rotational motion with a semi-circular trajectory.

[0047] Based on this, when several rotating shafts 901 operate simultaneously, each rotating shaft 901 drives a toggle plate 903 fixedly connected to it to swing around the shaft. Figure 4 Taking the orientation shown as an example, when the rotating shaft 901 drives the actuating plate 903 to the left side of the rotating shaft 901, the connecting plate 905 and the fork 906 are in a vertical state due to their own gravity. The specific structure is as follows: Figure 4 As shown; when the rotating shaft 901 drives the actuating plate 903 to run directly below the rotating shaft 901, the fork 906 engages with the locking interface 904 on the actuating plate 903. At this time, the rotating shaft 901, the actuating plate 903, and the fork 906 are on the same vertical line, as shown in the specific structure. Figure 6 As shown, when the actuating plate 903 swings and rotates from the left side of the rotating shaft 901 to below the rotating shaft 901, the connecting plate 905 and the fork 906 connected to the actuating plate 903 will have a vertically downward displacement component. The existence of this displacement component causes the fork 906 to insert the kelp strands located at that position in the cleaning chamber 201. When the rotating shaft 901 drives the actuating plate 903 to the right side of the rotating shaft 901, the connecting plate 905 and the fork 906 cooperate with the card interface 904, and the fork 906 swings to the right following the actuating plate 903. At this time, the fork 906 pushes the inserted kelp strands to the right. The specific structure is as follows. Figure 7 As shown; at this point, based on the simultaneous reciprocating swing of several feed forks 906, the effect of pushing the kelp shreds to the output end 203 of the cleaning chamber 201 will be achieved.

[0048] Based on the above embodiments, during the oscillating and pushing process of the feed fork 906, on the one hand, the cleaning fluid is agitated to make the cleaning fluid more thorough on the kelp shreds, and on the other hand, the kelp shreds are transported to the output end 203 to realize the automation of the cleaning of the kelp shreds. The gap that always exists between the bottom end of the agitator 911 and the bottom plate of the cleaning chamber 201 can prevent the agitator 911 from interfering with the cleaning chamber 201, and facilitates the partial settling of sludge and other impurities in the area of ​​the filter plate 206 where the filter holes 210 are not provided, which is convenient for the centralized cleaning of sludge and other impurities.

[0049] In this invention, when the kelp shreds washed in the washing chamber 201 are pushed to a position near the output end 203, they are collected by the discharge device 4. Figure 1 As shown, the discharge device 4 is located on one side of the output end 203 of the cleaning chamber 201. The discharge device 4 includes a discharge chamber 401. The bottom surface of the discharge chamber 401 is sloping, and the bottom of the slope of the discharge chamber 401 is flush with the filter plate 206 in the cleaning chamber 201. A loading platform is also provided at the top of the slope of the discharge chamber 401. The loading platform is horizontally set and is not shown in the figure.

[0050] like Figure 1 , Figure 8 As shown, the discharge device 4 also includes a first cylinder 402 parallel to the bottom surface of the discharge bin 401. The first cylinder 402 is a magnetic couple rodless cylinder, including a cylinder seat 403. A piston rod 404 is provided on the cylinder seat 403. A movable slider 405 is sleeved on the piston rod 404. Several support rods 406 are fixedly connected to the movable slider 405. The several support rods 406 extend vertically upward, and the top ends of the several support rods 406 are connected to a second cylinder 407. The second cylinder 407 is perpendicular to the cleaning bin 201. A first crossbar 408 is connected to the piston end of the second cylinder 407. Several drain claws 409 are provided on the first crossbar 408 in a vertically downward direction.

[0051] Based on the above structure, when the kelp strips washed in the washing chamber 201 are pushed to a position near the output end 203, the second cylinder 407 is controlled to operate. At this time, the first crossbar 408 moves vertically downward and uses several draining claws 409 to pick up the kelp strips at this position. Then, the first cylinder 403 is controlled to operate, and the sliding block 405 drives the second cylinder 407, the draining claws 409, and the kelp strips picked up by the draining claws 409 to slide from the bottom to the top of the slope of the discharge chamber 401 until they reach the position of the loading platform. Then, the second cylinder 407 operates to drive the draining claws 409 to retract upward, leaving the kelp strips on the loading platform for collection by the staff. At this time, the sliding block 405 is moved back to the initial state, and the first cylinder 403 and the second cylinder 407 are ready to perform the next kelp strip extraction. This process realizes the automated extraction of washed kelp strips, making the entire process from washing to collection of washed kelp strips automated, greatly improving work efficiency.

[0052] Furthermore, in this technical solution, such as Figure 8 As shown, a scraper 410 is provided at the bottom of the movable slider 405. The scraper 410 has several scraping holes 411. The scraping holes 411 correspond one-to-one with several drain claws 409. During the entire process of the piston of the second cylinder 407 moving vertically up and down, the scraping holes 411 are always fitted on the outside of the drain claws 409. When the second cylinder 407 moves and drives the drain claws 409 to retract upwards, the scraper 410 follows the movable slider 405 to a stationary state. Then, the seaweed strands wrapped on the drain claws 409 will be scraped off by the scraping holes 411, saving the time of manual cleaning by the staff.

[0053] Based on the above technical solutions, such as Figure 1 As shown, this utility model also has an electrical control box 5 on one side of the discharge device 4. The electrical control box 5 is electrically connected to the air pump 6, the geared motor 1001, the first cylinder 403 and the second cylinder 407 respectively. In addition, the electrical control box 5 is also equipped with a touch control screen 501, which is used to realize the electrification of the air pump 6, the geared motor 1001, the first cylinder 403 and the second cylinder 408. On this basis, the electrical control box 5 is also equipped with an emergency brake switch 502, which is used to brake in case of abnormal operation of the kelp washing device, so as to ensure the safety of the staff.

[0054] In general, the materials used in the various devices and equipment in this technical solution are all ordinary pipes, rods and plates, which are inexpensive and simple in structure. More specifically, this utility model utilizes the cooperation of air pump 6 with air supply pipe 601 and exhaust pipe 602. Under the premise of air supply from air pump 6, high-pressure gas is blown into the cleaning chamber 201 through air outlet 603 to form high-pressure bubbles, which in turn cause the cleaning liquid inside to rise and form an impact water flow, forming an all-round bubble impact cleaning of kelp shreds, thereby improving the rinsing cleanliness of kelp shreds.

[0055] Based on this, the present invention also provides a swing arm assembly 9 at the top of the cleaning chamber 201. With the power assembly 10 providing reciprocating swing power to the actuating plate 903, the actuating plate 903 intermittently pushes the feed fork 906 to swing towards the output end 203 of the cleaning chamber 201 through the card interface 904. At this time, the feed fork 906 will intermittently insert and pick up kelp strips and push the kelp strips in the swing direction of the feed fork 906. During the swing pushing process of the feed fork 906, on the one hand, the cleaning liquid is agitated, so that the cleaning liquid cleans the kelp strips more thoroughly, and on the other hand, the kelp strips are transported forward to realize the automation of kelp strip cleaning.

[0056] In addition, this utility model also provides a discharge device 4 at the output end 203 of the cleaning chamber 201. When the conveying device 3 gradually pushes the kelp strips to the output end 203 of the cleaning chamber 201, the kelp strips are pushed upward along the inclined discharge chamber 401 and drained by the cooperation of the first cylinder 402, the second cylinder 407, and the draining claw 409, thus achieving the effect of automated cleaning of kelp strips and improving the cleaning efficiency of kelp strips.

[0057] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A kelp washing device, characterized in that, include: The overall frame, cleaning device, conveying device, discharge device, and electrical control box include: The overall frame is used to support the cleaning device, conveying device and discharging device, and the cleaning device, conveying device and discharging device are arranged in sequence. A cleaning device includes a rectangular cleaning chamber with a long side and a short side. One short side is configured as an input end, and the other short side as an output end. A water inlet pipe is provided on the side wall of the input end for adding cleaning fluid to the cleaning chamber. Two air pumps are provided on the outer wall of one long side of the cleaning chamber, each connected to an air supply pipe that penetrates the side wall of the cleaning chamber and extends into its interior. Furthermore, the interior space of the cleaning chamber is divided into two sections along the extension direction of the long side. The system includes a washing zone and a sedimentation zone, with the two washing zones located on opposite sides of the sedimentation zone. Each washing zone contains several equally spaced and uniformly arranged exhaust pipes, which are interconnected and connected to the gas supply pipeline. Each exhaust pipe has several equally spaced and uniformly arranged air outlets. In addition, the washing chamber is equipped with a water filter plate, and the inner wall of the washing chamber is provided with a support boss. The water filter plate is positioned above the exhaust pipes via the support boss, and the water filter plate has several water filter holes. The conveying device includes a swing arm assembly disposed on top of the cleaning chamber and a power assembly disposed on one side of the cleaning chamber, wherein: The swing arm assembly includes several rotating shafts that are parallel to each other and evenly arranged on the top of the cleaning chamber. The extension direction of the rotating shafts is the same as the extension direction of the short side of the cleaning chamber. Each rotating shaft is connected to a fork pushing mechanism. The fork pushing mechanism includes a set of actuating plates fixed on the rotating shaft. A locking interface is provided on the side of the set of actuating plates away from the rotating shaft. The opening direction of the locking interface is the same as the extension direction of the long side of the cleaning chamber and faces the output end of the cleaning chamber. On this basis, a connecting plate is rotatably connected to each actuating plate above the locking interface. A fork is fixedly connected to the end of the connecting plate. The position of the fork corresponds to the locking interface. In addition, the swing arm assembly also includes a swing tube fixed on each rotating shaft. Several swing tubes are simultaneously rotatably connected to a crossbeam. The power assembly includes a geared motor and a crank-rocker mechanism. The crank-rocker mechanism includes an eccentric wheel, a first connecting rod, and a second connecting rod. The center of the eccentric wheel is fixedly connected to the output end of the geared motor. An eccentric shaft is provided on the eccentric wheel. The eccentric shaft is rotatably connected to the end of the first connecting rod. The other end of the first connecting rod is connected to one end of the second connecting rod. The other end of the second connecting rod is fixedly connected to any one of the rotating shafts. The discharge device is located on one side of the output end of the cleaning chamber. The discharge device includes a discharge chamber with a sloping bottom. The bottom of the discharge chamber is flush with the filter plate in the cleaning chamber. A loading platform is provided at the top of the discharge chamber. The loading platform is horizontally arranged. The discharge device also includes a first cylinder parallel to the bottom of the discharge chamber. The first cylinder is a magnetic couple rodless cylinder, including a cylinder seat. A piston rod is provided on the cylinder seat. A movable slider is sleeved on the piston rod. Several support rods are fixedly connected to the movable slider. The support rods extend vertically upward. The tops of the support rods are connected to a second cylinder. The second cylinder is perpendicular to the cleaning chamber. A first crossbar is connected to the piston end of the second cylinder. Several drain claws are provided on the first crossbar in a vertically downward direction. An electrical control box is located on one side of the discharge device. The electrical control box is electrically connected to the air pump, the geared motor, the first cylinder, and the second cylinder. In addition, the electrical control box is also equipped with a touch control screen for controlling the operation of the air pump, the geared motor, the first cylinder, and the second cylinder.

2. The kelp washing device according to claim 1, characterized in that: In the cleaning device, the water inlet pipe is also equipped with a control valve to control the amount of cleaning liquid added to the cleaning chamber. Correspondingly, the cleaning chamber is also provided with an overflow port on the long side near the output end to collect the overflowing cleaning liquid.

3. The kelp washing device according to claim 2, characterized in that: The cleaning chamber also has a drain outlet at the location of the sedimentation zone.

4. The kelp washing device according to claim 3, characterized in that: On the exhaust pipe, a plurality of air outlets are located at the top of the exhaust pipe for discharging the air supplied by the air pump toward the water filter plate.

5. The kelp washing device according to claim 4, characterized in that: In the swing arm assembly, both ends of each rotating shaft are rotatably mounted on the side wall of the cleaning chamber via a bearing assembly. The bearing assembly includes a bearing seat fixedly mounted on the side wall of the cleaning chamber, and a rolling bearing is provided inside the bearing seat, which is sleeved on the end of the rotating shaft.

6. The kelp washing device according to claim 5, characterized in that: In the fork pushing mechanism, the fork includes a second crossbar, the length of which is equal to the length of the short side of the cleaning chamber. Several actuating claws are fixedly provided below the second crossbar, and there is always a gap between the bottom end of the actuating claws and the bottom plate of the cleaning chamber.

7. The kelp washing device according to claim 6, characterized in that: In the discharge device, a scraper is provided at the bottom of the movable slider. The scraper has several scraping holes, which correspond one-to-one with several drain claws. During the entire process of the piston of the second cylinder moving vertically up and down, the scraping holes are always fitted outside the drain claws.

8. The kelp washing device according to claim 7, characterized in that: The electrical control box is also equipped with an emergency brake switch, which is used for emergency braking when the kelp washing device malfunctions.