阅读说明：本技术 一种七工位珍珠生产装置 (Seven station pearl apparatus for producing ) 是由 刘华 石乾清 于 2020-06-30 设计创作，主要内容包括：本发明公开一种七工位珍珠生产装置,属于粉圆机械化生产技术领域。所述七工位珍珠生产装置包括蒸汽加热工序、珍珠冷却工序、珍珠晾干工序、珍珠搅拌附粉工序和珍珠筛粉工序；所述蒸汽加热工序用于水煮粉圆；所述珍珠冷却工序用于冷却煮好的粉圆,使其成型；所述珍珠晾干工序用于晾干粉圆,去除表面的水煮；所述珍珠搅拌附粉工序对晾干后的粉圆进行表面附粉,防止其粘结；所述珍珠筛粉工序用于筛除粉圆表面多余的附粉,提高粉圆的口感。该七工位珍珠生产装置通过机械化实现珍珠粉圆蒸煮、冷却、晾干、附粉和筛粉一体化生产,提高生产效率的同时,自动化程序生产大大提高了珍珠粉圆的品质。(The invention discloses a seven-station pearl production device, and belongs to the technical field of mechanical production of pink balls. The seven-station pearl production device comprises a steam heating process, a pearl cooling process, a pearl airing process, a pearl stirring and powder attaching process and a pearl powder sieving process; the steam heating procedure is used for boiling rice dumplings in water; the pearl cooling procedure is used for cooling the cooked rice balls and forming the cooked rice balls; the pearl airing process is used for airing the powder balls, removing water on the surface and boiling; the pearl stirring and powder attaching process attaches powder to the surface of the dried powder balls to prevent the powder balls from being bonded; the pearl powder screening process is used for screening redundant attached powder on the surface of the flour ball and improving the taste of the flour ball. This seven station pearl apparatus for producing realizes pearl powder circle through mechanization that boiling, cooling, dry, attach powder and sieve powder integration production, when improving production efficiency, automatic procedure production has improved the quality of pearl powder circle greatly.)

1. A seven-station pearl production device is characterized by comprising a steam heating process (1), a pearl cooling process (2), a pearl airing process (3), a pearl stirring and powder attaching process (4) and a pearl powder sieving process (5);

the steam heating process (1), the pearl cooling process (2) and the pearl airing process (3) are fixedly connected to a frame in sequence;

the steam heating procedure (1) is used for boiling rice balls in water;

the pearl cooling procedure (2) is used for cooling the cooked rice dumplings and forming the cooked rice dumplings;

the pearl airing process (3) is used for airing the powder balls, removing water on the surface and boiling;

the pearl stirring and powder attaching process (4) is positioned at the tail end of the pearl airing process (3), and powder is attached to the surface of the aired flour balls to prevent the flour balls from being bonded;

the pearl powder sieving process (5) is positioned at the tail end of the pearl stirring and powder attaching process (4) and is used for sieving redundant attached powder on the surface of the flour ball and improving the taste of the flour ball.

2. The seven-station pearl production device according to claim 1, wherein the steam heating process (1) comprises a plurality of heating water tanks (11), a plurality of heating skip buckets (12), a plurality of heating telescopic cylinders (13) and a heating frame (14); a plurality of heating tipping buckets (12) are sequentially placed in the heating water tank (11) and are rotatably connected with the heating water tank (11) through rotating shafts; two ends of the heating telescopic cylinder (13) are respectively rotatably connected with the side edge of the heating tipping bucket (12) and the heating frame (14), and the heating tipping bucket (12) rotates around the rotating shaft in the heating water tank (11) under the action of the heating telescopic cylinder (13); a plurality of ventilation fans (6) are fixedly connected above the heating water tank (11).

3. The seven-station pearl production device according to claim 2, wherein a plurality of heating water tanks (11) are communicated with a heating water inlet pipe (15), a heating water outlet pipe (16) and a heating steam pipe (17); the heating water inlet pipe (15) is positioned at the top end of the side wall of the heating water tank (11) and is used for introducing water for boiling; the heating water outlet pipe (16) is positioned at the bottom of the heating water tank (11) and is used for discharging boiled wastewater; the heating steam pipe (17) is positioned at the bottom end of the side wall of the heating water tank (11), the other end of the heating steam pipe is communicated with a steam storage tank (19), and water in the heating water tank (11) is heated through steam; and a plurality of heating water tanks (11) are externally provided with heating temperature sensors (18) for monitoring the water temperature therein.

4. The seven-station pearl production device according to claim 3, wherein the heating tipping bucket (12) is composed of a heating bucket body (121), a heating arc bucket bottom (122) and a heating bucket shovel (123), and the heating bucket shovel (123) is fixedly connected to one side of the heating bucket body (121) close to the connection part of the heating water tank (11) in an inclined and upward manner; heating baffles (124) are arranged on two sides of the heating shovel (123), and the heating baffles (124) are inclined inwards; a plurality of through holes are uniformly distributed in the heating hopper body (121), and when the heating tipping bucket (12) rotates, water in the heating hopper body (121) is drained.

5. The seven-station pearl production device according to claim 1, wherein the pearl cooling process (2) comprises a plurality of cooling water tanks (21), a plurality of cooling tipping buckets (22), a plurality of cooling telescopic cylinders (23) and a cooling frame (24); a plurality of cooling tipping buckets (22) are sequentially placed in the cooling water tank (21) and are rotationally connected with the cooling water tank (21) through rotating shafts; two ends of the cooling telescopic cylinder (23) are respectively and rotatably connected with the side edge of the cooling tipping bucket (22) and the cooling frame (24); under the action of the cooling telescopic cylinder (23), the cooling tipping bucket (22) rotates around the rotating shaft in the cooling water tank (21).

6. A seven-station pearl production device as claimed in claim 5, wherein a plurality of cooling water tanks (21) are communicated with a cooling water inlet pipe (25) and a cooling water outlet pipe (26); the cooling water inlet pipe (25) is positioned at the top end of the side wall of the cooling water tank (21) and is used for introducing cooling water; the cooling water outlet pipe (26) is positioned at the bottom of the cooling water tank (21) and is used for discharging cooled waste water; a cooling temperature sensor (27) is arranged outside each of the cooling water tanks (21) and is used for monitoring the water temperature in the cooling water tanks; still fixedly connected with stirring support (28) and stirring roller (29) on cooling water tank (21), stirring roller (29) through a plurality of slider (291) with guide rail (281) sliding connection in stirring support (28), under the effect of pneumatic cylinder (7), stirring roller (29) are followed stirring support (28) round trip movement.

7. The seven-station pearl production device according to claim 5, wherein the cooling dump bucket (22) is composed of a cooling bucket body (221), a cooling arc bucket bottom (222) and a cooling bucket shovel (223), and the cooling bucket shovel (223) is fixedly connected to one side of the cooling bucket body (221) close to the connection position of the cooling water tank (21) in an inclined and upward manner; cooling baffles (224) are arranged on two sides of the cooling bucket shovel (223), and the cooling baffles (224) are inclined inwards; a plurality of through holes are uniformly distributed in the cooling bucket body (221), and when the cooling tipping bucket (22) rotates, water in the cooling bucket body (221) is drained.

8. The seven-station pearl production device according to claim 1, wherein the pearl drying process (3) comprises a drying box (31), a drying skip (32), a drying telescopic cylinder (33) and a drying frame (34), wherein the drying skip (32) is placed in the drying box (31) and is rotatably connected with the drying box (31) through a rotating shaft; two ends of the airing and lifting cylinder (33) are respectively and rotatably connected with the side edge of the airing skip bucket (32) and the airing frame (34); under the action of the airing lifting cylinder (33), the airing skip bucket (32) rotates around the rotating shaft in the airing box (31); the drying box (31) is communicated with a drying water inlet pipe (35) and a drying water outlet pipe (36), the drying water inlet pipe (35) is located at the top end of the side wall of the drying box (31) and used for introducing water for rinsing, and the drying water outlet pipe (36) is located at the bottom of the drying box (31) and used for discharging wastewater after rinsing; a drying temperature sensor (37) is arranged outside the drying box (31) and used for monitoring the water temperature in the drying box; the airing skip bucket (32) consists of an airing bucket body (321), an airing arc bucket bottom (322) and an airing shovel (323), and the airing shovel (323) is obliquely and upwards fixedly connected to one side, close to the joint of the airing bucket body (321) and the airing box (31); airing baffles (324) are arranged on two sides of the airing shovel (323), and the airing baffles (324) are inclined inwards; evenly distributed has a plurality of through-hole on the body of the hopper that dries (321) when drying tipping bucket (32) and rotating, the drippings dry water in the body of the hopper (321).

9. The seven-station pearl production device according to claim 1, wherein the pearl stirring and powder attaching process (4) comprises a stirring barrel (41), a feeding hole (42), a discharging hole (43), a gate valve (44) and a stirring power box (45); the feeding hole (42) and the discharging hole (43) are respectively positioned at the top end and the bottom end of the side wall of the stirring barrel (41) and are used for feeding and discharging; the gate valve (44) is fixedly connected to the side wall of the stirring barrel (41) and controls the discharging speed of the discharging port (43).

10. The seven-station pearl production device according to claim 9, wherein the stirring power box (45) is composed of a rotating shaft (451), a plurality of transverse stirring rods (452), a plurality of longitudinal stirring rods (453), a reducer (454) and a motor (455); the motor (455) is connected with the speed reducer (454) through a belt, and an output shaft of the speed reducer (454) is fixedly connected with the rotating shaft (451); a plurality of transverse stirring rods (452) and a plurality of longitudinal stirring rods (453) vertically penetrate through the rotating shaft (451); the plurality of transverse stirring rods (452) and the plurality of longitudinal stirring rods (453) are vertically arranged in a staggered mode.

Technical Field

The invention relates to the technical field of mechanical production of pink balls, in particular to a seven-station pearl production device.

Background

At present, the beverage on the market has various types, such as carbonated beverage, fruit juice, fruit tea, scented tea, coffee, milk tea and the like. The consumption main bodies of the milk tea are more young people. The pearl milk tea is a beverage originated in Taiwan province of China and mainly comprises two parts, namely pearl and milk tea. The pearl in the pearl milk tea is pearl ball, is leisure food with crystal and clear appearance and high internal nutritive value, has smooth and elastic mouthfeel, and is matched with the milk tea to have unique attractive appearance and mouthfeel.

At present, most of the pearl balls used in the market are manually cooked, cooled, dried, attached with powder and then packaged into bags for use, the efficiency of manually making the pearl balls is low, and the quality of the pearl balls cannot be guaranteed due to the fact that the whole process is operated by the experience of workers.

Disclosure of Invention

The invention aims to provide a seven-station pearl production device, which aims to solve the problems that the existing manual production of pink balls is low in efficiency, and the quality of the pink balls cannot be guaranteed due to the fact that the whole process is operated by the experience of workers.

In order to solve the technical problem, the invention provides a seven-station pearl production device which comprises a steam heating process, a pearl cooling process, a pearl airing process, a pearl stirring and powder attaching process and a pearl powder sieving process;

the steam heating process, the pearl cooling process and the pearl airing process are sequentially and fixedly connected to a frame;

the steam heating procedure is used for boiling rice dumplings in water;

the pearl cooling procedure is used for cooling the cooked rice balls and forming the cooked rice balls;

the pearl airing process is used for airing the powder balls, removing water on the surface and boiling;

the pearl stirring and powder attaching process is positioned at the tail end of the pearl airing process, and powder is attached to the surface of the aired flour balls to prevent the flour balls from being bonded;

the pearl powder sieving process is positioned at the tail end of the pearl stirring and powder attaching process, and is used for sieving redundant attached powder on the surface of the rice dumpling and improving the taste of the rice dumpling.

Optionally, the steam heating process includes a plurality of heating water tanks, a plurality of heating skip buckets, a plurality of heating telescopic cylinders and a heating frame; the plurality of heating tipping buckets are sequentially placed in the heating water tank and are rotationally connected with the heating water tank through a rotating shaft; two ends of the heating telescopic cylinder are respectively connected with the side edge of the heating tipping bucket and the heating frame in a rotating way, and the heating tipping bucket rotates around the rotating shaft in the heating water tank under the action of the heating telescopic cylinder; and a plurality of ventilation fans are fixedly connected above the heating water tank.

Optionally, the plurality of heating water tanks are communicated with a heating water inlet pipe, a heating water outlet pipe and a heating steam pipe; the heating water inlet pipe is positioned at the top end of the side wall of the heating water tank and is used for introducing water for boiling; the heating water outlet pipe is positioned at the bottom of the heating water tank and used for discharging the boiled wastewater; the heating steam pipe is positioned at the bottom end of the side wall of the heating water tank, the other end of the heating steam pipe is communicated with the steam storage tank, and water in the heating water tank is heated through steam; and a plurality of heating temperature sensors are arranged outside the heating water tanks and used for monitoring the water temperature therein.

Optionally, the heating tipping bucket comprises a heating bucket body, a heating arc bucket bottom and a heating bucket shovel, and the heating bucket shovel is obliquely and upwards fixedly connected to one side of the heating bucket body close to the connection position of the heating water tank; heating baffles are arranged on the two sides of the heating shovel, and the heating baffles are inclined inwards; a plurality of through holes are uniformly distributed in the heating bucket body, and when the heating tipping bucket rotates, water in the heating bucket body is drained.

Optionally, the pearl cooling process comprises a plurality of cooling water tanks, a plurality of cooling tipping buckets, a plurality of cooling telescopic cylinders and a cooling frame; the plurality of cooling tipping buckets are sequentially placed in the cooling water tank and are rotationally connected with the cooling water tank through a rotating shaft; two ends of the cooling telescopic cylinder are respectively in rotary connection with the side edge of the cooling tipping bucket and the cooling frame; and under the action of the cooling telescopic cylinder, the cooling tipping bucket rotates around the rotating shaft in the cooling water tank.

Optionally, a plurality of cooling water tanks are communicated with a cooling water inlet pipe and a cooling water outlet pipe; the cooling water inlet pipe is positioned at the top end of the side wall of the cooling water tank and is used for introducing cooling water; the cooling water outlet pipe is positioned at the bottom of the cooling water tank and used for discharging cooled waste water; a cooling temperature sensor is arranged outside each of the cooling water tanks and used for monitoring the water temperature in the cooling water tanks; the cooling water tank is also fixedly connected with a stirring support and a stirring roller, the stirring roller is connected with a guide rail in the stirring support in a sliding manner through a plurality of sliding blocks, and the stirring roller moves back and forth along the stirring support under the action of a hydraulic cylinder.

Optionally, the cooling tipping bucket comprises a cooling bucket body, a cooling arc bucket bottom and a cooling bucket shovel, and the cooling bucket shovel is obliquely and upwards fixedly connected to one side of the cooling bucket body close to the connection position of the cooling water tank; cooling baffles are arranged on the two sides of the cooling bucket shovel and are inclined inwards; a plurality of through holes are uniformly distributed in the cooling bucket body, and water in the cooling bucket body is drained when the cooling bucket rotates.

Optionally, the pearl drying process comprises a drying box, a drying skip bucket, a drying telescopic cylinder and a drying frame, wherein the drying skip bucket is placed in the drying box and is rotatably connected with the drying box through a rotating shaft; two ends of the airing telescopic cylinder are respectively rotatably connected with the side edge of the airing tipping bucket and the airing frame; under the action of the airing lifting cylinder, the airing skip bucket rotates around the rotating shaft in the airing box; the drying box is communicated with a drying water inlet pipe and a drying water outlet pipe, the drying water inlet pipe is positioned at the top end of the side wall of the drying box and used for introducing water for rinsing, and the drying water outlet pipe is positioned at the bottom of the drying box and used for discharging wastewater after rinsing; a drying temperature sensor is arranged outside the drying box and used for monitoring the water temperature in the drying box; the airing tipping bucket consists of an airing bucket body, an airing arc bucket bottom and an airing bucket shovel, and the airing bucket shovel is fixedly connected to one side, close to the joint of the airing box, of the airing bucket body in an inclined and upward manner; airing baffles are arranged on the two sides of the airing bucket shovel, and the airing baffles are inclined inwards; air and evenly distributed has a plurality of through-hole on the bucket body air dry when the tipping bucket rotates, the drippings air the water in the bucket body.

Optionally, the pearl stirring and powder attaching process comprises a stirring barrel, a feeding hole, a discharging hole, a gate valve and a stirring power box; the feeding hole and the discharging hole are respectively positioned at the top end and the bottom end of the side wall of the stirring barrel and are used for feeding and discharging; the gate valve is fixedly connected to the side wall of the stirring barrel and used for controlling the discharging speed of the discharging port.

Optionally, the stirring power box is composed of a rotating shaft, a plurality of transverse stirring rods, a plurality of longitudinal stirring rods, a speed reducer and a motor; the motor is connected with the speed reducer through a belt, and an output shaft of the speed reducer is fixedly connected with the rotating shaft; the plurality of transverse stirring rods and the plurality of longitudinal stirring rods vertically penetrate through the rotating shaft; the plurality of transverse stirring rods and the plurality of longitudinal stirring rods are vertically and alternately arranged.

The invention provides a seven-station pearl production device which comprises a steam heating process, a pearl cooling process, a pearl airing process, a pearl stirring and powder attaching process and a pearl powder sieving process; the steam heating process, the pearl cooling process and the pearl airing process are sequentially and fixedly connected to a frame; the steam heating procedure is used for boiling rice dumplings in water; the pearl cooling procedure is used for cooling the cooked rice balls and forming the cooked rice balls; the pearl airing process is used for airing the powder balls, removing water on the surface and boiling; the pearl stirring and powder attaching process is positioned at the tail end of the pearl airing process, and powder is attached to the surface of the aired flour balls to prevent the flour balls from being bonded; the pearl powder sieving process is positioned at the tail end of the pearl stirring and powder attaching process, and is used for sieving redundant attached powder on the surface of the rice dumpling and improving the taste of the rice dumpling. This seven station pearl apparatus for producing realizes pearl powder circle through mechanization that boiling, cooling, dry, attach powder and sieve powder integration production, when improving production efficiency, automatic procedure production has improved the quality of pearl powder circle greatly.

Drawings

FIG. 1 is a schematic view of the overall structure of a seven-station pearl production device according to the present invention;

FIG. 2 is an overall cross-sectional view of a seven-station pearl production apparatus provided in accordance with the present invention;

FIG. 3 is a schematic structural view of a steam heating process of a seven-station pearl production device according to the present invention;

FIG. 4 is a front view of a steam heating process of a seven-station pearl production apparatus according to the present invention;

FIG. 5 is a schematic structural diagram of a heating skip of a seven-station pearl production device provided by the invention;

FIG. 6 is a schematic structural view of a pearl cooling process in a seven-station pearl production apparatus according to the present invention;

FIG. 7 is a front view of a pearl cooling process in a seven-station pearl production apparatus according to the present invention;

FIG. 8 is a partial enlarged view of a pearl cooling process in a seven-station pearl production apparatus according to the present invention;

FIG. 9 is a schematic structural diagram of a seven-station pearl production device cooling skip provided by the invention;

FIG. 10 is a schematic structural view of a pearl drying process in a seven-station pearl production device according to the present invention;

FIG. 11 is a schematic structural diagram of a seven-station pearl production device airing skip bucket provided by the invention;

FIG. 12 is a schematic structural view of a pearl stirring and powder attaching process in a seven-station pearl production device according to the present invention;

fig. 13 is a schematic view of the internal structure of a stirring power box of a seven-station pearl production device provided by the invention.

Detailed Description

The invention provides a seven-station pearl production device which is further explained in detail by combining the attached drawings and the specific embodiment. Advantages and features of the present invention will become apparent from the following description and from the claims. It is to be noted that the drawings are in a very simplified form and are not to precise scale, which is merely for the purpose of facilitating and distinctly claiming the embodiments of the present invention.

The invention provides a seven-station pearl production device, which is shown in figures 1 and 2 and comprises a steam heating process 1, a pearl cooling process 2, a pearl airing process 3, a pearl stirring and powder attaching process 4 and a pearl powder sieving process 5; the steam heating process 1, the pearl cooling process 2 and the pearl airing process 3 are fixedly connected to a frame in sequence according to the sequence of the processes; the steam heating procedure 1 is used for boiling rice dumplings in water; the pearl cooling process 2 is used for cooling the cooked rice flour balls and forming the rice flour balls; the pearl airing process 3 is used for airing the powder balls, removing water on the surface and boiling; the pearl stirring and powder attaching process 4 is positioned at the tail end of the pearl airing process 3, and powder is attached to the surface of the aired flour balls to prevent the flour balls from being bonded; the pearl powder sieving process 5 is positioned at the tail end of the pearl stirring and powder attaching process 4, and is used for sieving redundant attached powder on the surface of the flour ball and improving the taste of the flour ball.

Specifically, as shown in fig. 3 and 4, the steam heating process 1 includes a plurality of heating water tanks 11, a plurality of heating skip buckets 12, a plurality of heating telescopic cylinders 13, and a heating frame 14; a plurality of the heating tipping buckets 12 are sequentially placed in the heating water tank 11 and are rotatably connected with the heating water tank 11 through a rotating shaft; two ends of the heating telescopic cylinder 13 are respectively rotatably connected with the side edge of the heating tipping bucket 12 and the heating frame 14, and the heating tipping bucket 12 rotates around the rotating shaft in the heating water tank 11 under the action of the heating telescopic cylinder 13; a plurality of ventilation fans 6 are fixedly connected above the heating water tank 11 and used for discharging steam generated by cooking; the heating water tanks 11 are communicated with a heating water inlet pipe 15, a heating water outlet pipe 16 and a heating steam pipe 17; the heating water inlet pipe 15 is positioned at the top end of the side wall of the heating water tank 11 and is used for introducing water for boiling; the heating water outlet pipe 16 is positioned at the bottom of the heating water tank 11 and is used for discharging the boiled wastewater; the heating steam pipe 17 is positioned at the bottom end of the side wall of the heating water tank 11, the other end of the heating steam pipe is communicated with a steam storage tank 19, and water in the heating water tank 11 is heated through steam; and a heating temperature sensor 18 is arranged outside each of the heating water tanks 11 and used for monitoring the temperature of water therein.

Specifically, as shown in fig. 5, the heating dump bucket 12 is composed of a heating bucket body 121, a heating arc bucket bottom 122 and a heating bucket blade 123, and the heating bucket blade 123 is fixedly connected to one side of the heating bucket body 121 close to the connection position of the heating water tank 11 in an inclined and upward manner; heating baffles 124 are arranged on two sides of the heating shovel 123, and the heating baffles 124 are inclined inwards; a plurality of through holes are uniformly distributed on the heating hopper body 121, and when the heating tipping bucket 12 rotates, water in the heating hopper body 121 is drained, and a non-water powder circle is guided into a subsequent tipping bucket.

Specifically, as shown in fig. 6 and 7, the pearl cooling process 2 includes a plurality of cooling water tanks 21, a plurality of cooling dumps 22, a plurality of cooling telescopic cylinders 23, and a cooling frame 24; the plurality of cooling tipping buckets 22 are sequentially placed in the cooling water tank 21 and are rotatably connected with the cooling water tank 21 through a rotating shaft; two ends of the cooling telescopic cylinder 23 are respectively connected with the side edge of the cooling tipping bucket 22 and the cooling frame 24 in a rotating way; under the action of the cooling telescopic cylinder 23, the cooling dump bucket 22 rotates around the rotating shaft in the cooling water tank 21; a cooling water inlet pipe 25 and a cooling water outlet pipe 26 are communicated with the plurality of cooling water tanks 21; the cooling water inlet pipe 25 is positioned at the top end of the side wall of the cooling water tank 21 and is used for introducing cooling water; the cooling water outlet pipe 26 is positioned at the bottom of the cooling water tank 21 and used for discharging cooled waste water; and a cooling temperature sensor 27 is arranged outside each of the cooling water tanks 21 and used for monitoring the temperature of water therein.

Specifically, as shown in fig. 8, a stirring bracket 28 and a stirring roller 29 are further fixedly connected to the cooling water tank 21, the stirring roller 29 is slidably connected to a guide rail 281 in the stirring bracket 28 through a plurality of sliders 291, and under the action of the hydraulic cylinder 7, the stirring roller 29 moves back and forth along the stirring bracket 28, so that indirect stirring of the stirring roller 29 is realized, and the powder balls are prevented from being bonded.

Specifically, as shown in fig. 9, the cooling dump bucket 22 is composed of a cooling bucket body 221, a cooling arc bucket bottom 222 and a cooling bucket 223, and the cooling bucket 223 is fixedly connected to one side of the cooling bucket body 221 close to the connection position of the cooling water tank 21 in an inclined and upward manner; cooling baffles 224 are arranged on two sides of the cooling bucket 223, and the cooling baffles 224 are inclined inwards; a plurality of through holes are uniformly distributed on the cooling bucket body 221, and when the cooling tipping bucket 22 rotates, water in the cooling bucket body 221 is drained, and a non-water powder circle is guided into a subsequent tipping bucket.

Specifically, as shown in fig. 10, the pearl drying process 3 includes a drying box 31, a drying skip 32, a drying telescopic cylinder 33 and a drying frame 34, wherein the drying skip 32 is placed in the drying box 31 and is rotatably connected to the drying box 31 through a rotating shaft; two ends of the airing telescopic cylinder 33 are respectively rotatably connected with the side edge of the airing skip 32 and the airing frame 34; under the action of the airing lifting cylinder 33, the airing skip 32 rotates around the rotating shaft in the airing box 31; the drying box 31 is communicated with a drying water inlet pipe 35 and a drying water outlet pipe 36, the drying water inlet pipe 35 is located at the top end of the side wall of the drying box 31 and used for introducing water for rinsing, and the drying water outlet pipe 36 is located at the bottom of the drying box 31 and used for discharging wastewater after rinsing; and a drying temperature sensor 37 is arranged outside the drying box 31 and used for monitoring the water temperature therein.

Specifically, as shown in fig. 11, the airing skip 32 is composed of an airing bucket body 321, an airing arc bucket bottom 322 and an airing bucket shovel 323, and the airing bucket shovel 323 is fixedly connected to one side of the airing bucket body 321 close to the joint of the airing box 31 in an inclined upward direction; airing baffles 324 are arranged on two sides of the airing scoop 323, and the airing baffles 324 are inclined inwards; air a plurality of through-hole that evenly distributed is gone up to the bucket body 321 when drying tipping bucket 32 and rotating, the drippings air the water in the bucket body 321, will not contain during the leading-in later stage tipping bucket of water powder circle.

Specifically, as shown in fig. 12, the pearl stirring and powder attaching process 4 includes a stirring barrel 41, a feed inlet 42, a discharge outlet 43, a gate valve 44 and a stirring power box 45; the feed inlet 42 and the discharge outlet 43 are respectively positioned at the top end and the bottom end of the side wall of the stirring barrel 41 and are used for feeding and discharging; the gate valve 44 is fixedly connected to the side wall of the stirring barrel 41, and controls the discharging speed of the discharging port 43.

Specifically, as shown in fig. 13, the stirring power box 45 is composed of a rotating shaft 451, a plurality of transverse stirring rods 452, a plurality of longitudinal stirring rods 453, a speed reducer 454 and a motor 455; the motor 455 is connected to the speed reducer 454 through a belt, and an output shaft of the speed reducer 454 is fixedly connected to the rotating shaft 451; the plurality of transverse stirring rods 452 and the plurality of longitudinal stirring rods 453 vertically penetrate through the rotating shaft 451; the plurality of transverse stirring rods 452 and the plurality of longitudinal stirring rods 453 are vertically staggered.

The above description is only for the purpose of describing the preferred embodiments of the present invention, and is not intended to limit the scope of the present invention, and any variations and modifications made by those skilled in the art based on the above disclosure are within the scope of the appended claims.