CN113117790B

CN113117790B - Fine super-grinding equipment for solid beverage

Info

Publication number: CN113117790B
Application number: CN202110368611.1A
Authority: CN
Inventors: 龙辉
Original assignee: Jiangxi Nuotai Biotechnology Co ltd
Current assignee: Jiangxi Nuotai Biotechnology Co ltd
Priority date: 2021-04-06
Filing date: 2021-04-06
Publication date: 2022-07-12
Anticipated expiration: 2041-04-06
Also published as: CN113117790A

Abstract

The invention relates to fine super-grinding equipment, in particular to solid beverage fine super-grinding equipment. The invention provides solid beverage fine super-grinding equipment which can be used for preliminarily grinding and finely grinding solid hard chat powder and is convenient to collect. The invention provides a solid beverage fine ultra-grinding device, which comprises: the base is provided with a first support frame; the first support frame is provided with a first fixed shell, and the bottom of the first fixed shell is provided with a discharge hole; the motor base is arranged on one side of the first fixed shell; and the motor base is provided with a servo motor. Blocky solid beverage is poured into the second fixing shell through the feeding mechanism, then the solid beverage of a larger block is primarily crushed through the up-and-down movement of the extruding mechanism, the solid beverage drops onto the grinding cone, and the grinding cone rotates to grind the solid beverage.

Description

Fine super-grinding equipment for solid beverage

Technical Field

The invention relates to fine super-grinding equipment, in particular to solid beverage fine super-grinding equipment.

Background

The solid beverage is prepared by removing water from liquid beverage, and is a solid product with water content of not more than 5 g per 100 g of finished product, which is prepared from sugar, milk and dairy products, eggs or egg products, fruit juice or edible plant extracts and the like as main raw materials and proper amount of auxiliary materials or food additives, and is in the form of powder, granules or blocks.

Generally, solid beverage which is formed by liquid in a block shape needs to be finely ground into powder and then packaged, and small grinding facilities are not fine enough in grinding, so that the product quality is affected, workers need to continuously feed materials, and the workload of the workers is increased.

Therefore, it is highly desirable to design a solid beverage fine ultra-milling apparatus capable of performing preliminary grinding, fine milling, and convenient collection of solid chatty powder, so as to solve the above problems.

Disclosure of Invention

In order to overcome the defects that the grinding of a small grinding facility is not fine enough, the product quality is influenced, workers need to continuously feed materials, and the workload of the workers is increased, the invention has the technical problems that: the solid beverage fine super-grinding equipment is capable of conducting preliminary grinding and fine grinding and is convenient to collect solid chatting powder.

A solid beverage fine micronizing device comprising: the device comprises a base, a first support frame and a second support frame, wherein the first support frame is arranged on the base; the first support frame is provided with a first fixed shell, and the bottom of the first fixed shell is provided with a discharge hole; the motor base is arranged on one side of the first fixed shell; the servo motor is arranged on the motor base; the first rotating shaft is rotatably arranged on one side of the first fixed shell; the first belt pulley assembly is arranged between the output shaft of the servo motor and one end of the first rotating shaft and consists of two belt pulleys and a flat belt, one belt pulley is arranged on the output shaft of the servo motor, the other belt pulley is arranged at one end of the first rotating shaft, and the flat belt is arranged between the two belt pulleys; the first fixing frame is arranged in the first fixing shell; the second rotating shaft is rotatably arranged on one side of the first fixing frame; the first bevel gear component is arranged between the bottom end of the second rotating shaft and the other end of the first rotating shaft, the first bevel gear component consists of two bevel gears, one bevel gear is arranged at the bottom end of the second rotating shaft, the other bevel gear is arranged at the other end of the first rotating shaft, and the two bevel gears are meshed with each other; the top end of the second rotating shaft is provided with a first circular gear; the second circular gear is rotatably arranged at the top of the first fixing frame, and the first circular gear is meshed with the second circular gear; the grinding cone is arranged at the top of the second circular gear; the top of the first fixed shell is provided with a first fixed shell, and the grinding cone is positioned in the first fixed shell; the first support frame is provided with an extrusion mechanism; and the feeding mechanism is arranged on one side of the first fixed shell.

Further described, the pressing mechanism includes: the first support frame is provided with a first support frame; the top of the second support frame is provided with a positioning frame; the bottom of one side of the positioning frame is rotatably provided with a third rotating shaft; a second belt pulley component is arranged between one end of the third rotating shaft and the output shaft of the servo motor and consists of two belt pulleys and a flat belt, one belt pulley is arranged at one end of the third rotating shaft, the other belt pulley is arranged on the output shaft of the servo motor, and the flat belt is arranged between the two belt pulleys; the other end of the third rotating shaft is provided with a first rotating disc; the fourth rotating shaft is rotatably arranged on one side of the top of the positioning frame; a second bevel gear assembly is arranged between the bottom end of the fourth rotating shaft and the third rotating shaft and consists of two bevel gears, one bevel gear is arranged at the bottom end of the fourth rotating shaft, the other bevel gear is arranged on the third rotating shaft, and the two bevel gears are meshed with each other; the other side of the upper part of the positioning frame is rotatably provided with a fifth rotating shaft; a third belt pulley assembly is arranged between the top end of the fifth rotating shaft and the top end of the fourth rotating shaft, the third belt pulley assembly consists of two belt pulleys and a flat belt, one belt pulley is arranged at the top end of the fifth rotating shaft, the other belt pulley is arranged at the top end of the fourth rotating shaft, and the flat belt is arranged between the two belt pulleys; the other side of the bottom of the positioning frame is rotatably provided with a sixth rotating shaft; a third bevel gear assembly is arranged between one end of the sixth rotating shaft and the bottom end of the fifth rotating shaft and consists of two bevel gears, one bevel gear is arranged at one end of the sixth rotating shaft, the other bevel gear is arranged at the bottom end of the fifth rotating shaft, and the two bevel gears are meshed with each other; the other end of the sixth rotating shaft is provided with a second rotating disc; the fixing rod is arranged between the lower parts of the first rotating disc and the second rotating disc; the fixed rod is provided with an extrusion rod, the bottom end of the extrusion rod is uniformly provided with a circle of small holes at intervals, and the extrusion rod is positioned in the second fixed shell.

Further illustratively, the feed mechanism includes: a third support frame is arranged on one side of the first fixed shell; the third support frame is provided with a feed hopper; the bottom end of the feed hopper is provided with a feed pipe, and the other end of the feed pipe is connected with the second fixed shell; the limiting frame is arranged on the feeding pipe; the stop plate is arranged in the limiting frame in a sliding manner; the first elastic pieces are arranged between the two sides of the upper part of the striker plate and the two sides of the lower part of the limiting frame; the feeding pipe is provided with a first limiting block; the first limiting block is provided with a clamping block in a sliding mode, and the clamping block is matched with the material baffle plate; the second elastic piece is symmetrically arranged between one side of the fixture block and one side of the first limiting block; the clamping column is arranged on one side of the first limiting block in a sliding mode and matched with the clamping block.

Further illustratively, the blocking mechanism includes: one side of the third supporting frame is symmetrically provided with a second fixing frame; the second limiting blocks are arranged on opposite sides of the two second fixing frames in a sliding manner, and the bottoms of the two second limiting blocks are connected with the top of the material baffle plate; a seventh rotating shaft is rotatably arranged between the two second limiting blocks; the seventh rotating shaft is symmetrically provided with first fixed blocks, and the two first fixed blocks are matched with the two second limiting blocks; the seventh rotating shaft is provided with a third circular gear; racks are arranged on one sides of the two second fixing frames in a sliding mode, and the racks are meshed with the third circular gear; the second fixing block is arranged on one side of the upper part of the extrusion rod; the connecting band, second fixed block bottom is provided with the connecting band, and the connecting band bottom is connected with the rack.

Further illustratively, the via mechanism includes: the top of the second fixed shell is provided with a fixed cover; the bottom of the fixed cover is provided with a fixed seat; and the bottom of the fixed seat is uniformly provided with a circle of ejector rods at intervals, and the ejector rods are matched with the small holes in the extrusion rod.

Further illustratively, the rolling mechanism includes: the eighth rotating shaft is rotatably arranged on one side of the base; the eighth rotating shaft is provided with a first roller; a row of ninth rotating shafts are uniformly and rotatably arranged on the base at intervals; the ninth rotating shafts in the row are provided with second rollers; the ejection block is symmetrically and slidably arranged on one side of the base; and the third elastic pieces are arranged between one side of the two ejector blocks back to the base.

Further explaining, the limiting mechanism comprises: the two sides of the second fixing frames, back to the first fixing frame, are symmetrically provided with limiting shells; wedge blocks are arranged in the four limiting shells in a sliding mode, and the four wedge blocks are matched with the two second fixing frames; and fourth elastic pieces are arranged between one side of each wedge block, which faces away from the wedge block, and one side of each limit shell, which faces towards the wedge block.

Further, a protrusion is arranged on the inner wall of the second fixing shell.

The invention has the beneficial effects that: 1. blocky solid beverage is poured into the second fixing shell through the feeding mechanism, then the solid beverage of a larger block is primarily crushed through the up-and-down movement of the extruding mechanism, the solid beverage drops onto the grinding cone, and the grinding cone rotates to grind the solid beverage.

2. The pressing rod moves downwards to grind the solid beverage initially, and the feeding pipe can be blocked and is not discharged.

3. The ejector pin penetrates the small hole on the extrusion stem, can avoid the small hole to block up the influence and roll the effect.

4. The first roller and the second roller rotate, so that friction force is reduced when workers place and replace the collecting frame, and labor is saved.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a partial perspective sectional structural schematic view of the present invention.

Fig. 3 is a schematic perspective view of the pressing mechanism of the present invention.

Fig. 4 is a schematic perspective view of the feeding mechanism of the present invention.

Fig. 5 is a partial perspective sectional structural schematic view of the feeding mechanism of the present invention.

Fig. 6 is a schematic perspective view of the blocking mechanism of the present invention.

Fig. 7 is a schematic partial perspective view of the blocking mechanism of the present invention.

Fig. 8 is a schematic perspective sectional structural view of the through hole mechanism of the present invention.

Fig. 9 is a schematic perspective view of the rolling mechanism of the present invention.

Fig. 10 is a schematic perspective view of the limiting mechanism of the present invention.

Reference numbers in the drawings: 1: base, 2: first support frame, 3: first stationary case, 4: motor cabinet, 5: servo motor, 6: first rotating shaft, 7: first pulley assembly, 8: first mount, 9: second rotation shaft, 10: first bevel gear assembly, 11: first circular gear, 12: second circular gear, 13: grinding cone, 14: second stationary case, 15: extrusion mechanism, 1501: second support, 1502: a positioning frame, 1503: third axis of rotation, 1504: second pulley assembly, 1505: first carousel, 1506: fourth rotation shaft, 1507: a second bevel gear assembly, 1508: fifth rotation shaft, 1509: third pulley assembly, 1510: sixth rotation shaft, 1511: third bevel gear assembly, 1512: second carousel, 1513: fixing rod, 1514: extrusion stem, 16: feed mechanism, 1601: third support, 1602: feed hopper, 1603: feed tube, 1604: limit frame, 1605: striker plate, 1606: first elastic member, 1607: first stopper, 1608: a latch, 1609: second elastic member, 1610: a catch column, 17: blocking mechanism, 1701: second mount, 1702: second stopper, 1703: seventh shaft, 1704: first fixing block, 1705: third circular gear, 1706: rack, 1707: second fixed block, 1708: connecting band, 18: through hole mechanism, 1801: fixed cover, 1802: fixing base, 1803: ejector rod, 19: rolling mechanism, 1901: eighth rotation shaft, 1902: first drum, 1903: ninth rotation shaft, 1904: second roller, 1905: top block, 1906: third elastic member, 20: stop gear, 2001: spacing shell, 2002: wedge block, 2003: and a fourth elastic member.

Detailed Description

The present invention will be further described with reference to specific examples, which are illustrative of the invention and are not to be construed as limiting the invention.

Example 1

As shown in fig. 1 and fig. 2, a solid beverage fine super-grinding device comprises a base 1, a first support frame 2, a first fixed casing 3, a motor base 4, a servo motor 5, a first rotating shaft 6, a first belt pulley assembly 7, a first fixed frame 8, a second rotating shaft 9, a first bevel gear assembly 10, a first circular gear 11, a second circular gear 12, a grinding cone 13, a second fixed casing 14, an extruding mechanism 15 and a feeding mechanism 16, wherein the base 1 is provided with the first support frame 2, the first support frame 2 is provided with the first fixed casing 3, the bottom of the first fixed casing 3 is provided with a discharge hole, the front side of the first fixed casing 3 is provided with the motor base 4, the motor base 4 is provided with the servo motor 5, the front side of the first fixed casing 3 is rotatably provided with the first rotating shaft 6, a first belt 7 is arranged between an output shaft of the servo motor 5 and the front end of the first rotating shaft 6, the first belt pulley assembly 7 is composed of two belt pulleys and a flat belt, a belt pulley is arranged on an output shaft of the servo motor 5, another belt pulley is arranged at the front end of the first rotating shaft 6, the flat belt is arranged between the two belt pulleys, a first fixing frame 8 is arranged in the first fixing shell 3, a second rotating shaft 9 is rotatably arranged at the front side of the first fixing frame 8, a first bevel gear assembly 10 is arranged between the bottom end of the second rotating shaft 9 and the rear end of the first rotating shaft 6, the first bevel gear assembly 10 is composed of two bevel gears, a bevel gear is arranged at the bottom end of the second rotating shaft 9, another bevel gear is arranged at the rear end of the first rotating shaft 6, the two bevel gears are mutually meshed, a first circular gear 11 is arranged at the top end of the second rotating shaft 9, a second circular gear 12 is rotatably arranged at the top of the first fixing frame 8, and the first circular gear 11 is mutually meshed with the second circular gear 12, the top of the second circular gear 12 is provided with a grinding cone 13, the top of the first fixed shell 3 is provided with a second fixed shell 14, the grinding cone 13 is positioned in the second fixed shell 14, the first support frame 2 is provided with an extrusion mechanism 15, and the left side of the first fixed shell 3 is provided with a feeding mechanism 16.

When solid beverage needs to be finely ground, a worker pours the solid beverage crystallized from liquid into a feeding mechanism 16, the solid beverage falls into a second fixed shell 14 through the feeding mechanism 16, then the worker starts a servo motor 5, the servo motor 5 rotates to drive an extrusion mechanism 15 to move up and down to preliminarily grind the larger solid beverage, the broken solid beverage falls onto a grinding cone 13, the servo motor 5 rotates to drive a first rotating shaft 6 to rotate through a first belt pulley component 7, the first rotating shaft 6 rotates to drive a first bevel gear component 10 to be meshed, the first bevel gear component 10 rotates to drive a second rotating shaft 9 to rotate, the second rotating shaft 9 rotates to drive a first circular gear 11 to rotate to be meshed with a second circular gear 12, the second circular gear 12 rotates to drive a grinding cone 13 to rotate to finely grind the solid beverage, and the solid beverage powder falls through a discharge hole of the first fixed shell 3 after grinding is completed, the staff will collect the frame and place and concentrate the collection to solid drink powder in discharge gate bottom, treat that the whole back that grinds of solid drink is accomplished, the staff closes servo motor 5, servo motor 5 stall drives extrusion mechanism 15 stop motion, servo motor 5 stall drives first pivot 6 stall through first pulley subassembly 7, first pivot 6 stall drives first bevel gear subassembly 10 stop-engagement, first bevel gear subassembly 10 stall drives second pivot 9 stall, second pivot 9 stall drives first round gear 11 stall and second round gear 12 stop-engagement, second round gear 12 stall drives grinding cone 13 stop-rotation, this device simple structure, and the operation of being convenient for.

Example 2

As shown in fig. 3, 4 and 5, in embodiment 1, the pressing mechanism 15 includes a second support frame 1501, a positioning frame 1502, a third rotating shaft 1503, a second pulley assembly 1504, a first rotating disc 1505, a fourth rotating shaft 1506, a second bevel gear assembly 1507, a fifth rotating shaft 1508, a third pulley assembly 1509, a sixth rotating shaft 1510, a third bevel gear assembly 1511, a second rotating disc 1512, a fixing rod 1513 and a pressing rod 1514, the first support frame 2 is provided with the second support frame 1501, the second support frame 1501 is provided with the positioning frame 1502 at the top, the third rotating shaft 1503 is rotatably provided at the bottom of the front side of the positioning frame 1502, the second pulley assembly 1504 is provided between the front end of the third rotating shaft 1503 and the output shaft of the servo motor 5, the second pulley assembly 1504 is composed of two pulleys and a flat belt, the front end of the third rotating shaft 1503 is provided with one pulley, the output shaft of the servo motor 5 is provided with another pulley, a flat belt is arranged between the two belt pulleys, a first rotating disc 1505 is arranged at the rear end of the third rotating shaft 1503, a fourth rotating shaft 1506 is arranged at the front side of the top of the positioning frame 1502 in a rotating manner, a second bevel gear assembly 1507 is arranged between the bottom end of the fourth rotating shaft 1506 and the third rotating shaft 1503, the second bevel gear assembly 1507 consists of two bevel gears, a bevel gear is arranged at the bottom end of the fourth rotating shaft 1506, another bevel gear is arranged on the third rotating shaft 1503 and is meshed with the two bevel gears, a fifth rotating shaft 1508 is arranged at the rear side of the upper part of the positioning frame 1502 in a rotating manner, a third belt pulley assembly 1509 is arranged between the top end of the fifth rotating shaft 1508 and the top end of the fourth rotating shaft 1506, the third belt pulley assembly 1509 consists of two belt pulleys and a flat belt, a belt is arranged at the top end of the fifth rotating shaft 1508, another belt pulley is arranged at the top end of the fourth rotating shaft 1506, and a flat belt is arranged between the two belt pulleys, a sixth rotating shaft 1510 is rotatably arranged at the rear side of the bottom of the positioning frame 1502, a third bevel gear assembly 1511 is arranged between the rear end of the sixth rotating shaft 1510 and the bottom end of a fifth rotating shaft 1508, the third bevel gear assembly 1511 is composed of two bevel gears, one bevel gear is arranged at the rear end of the sixth rotating shaft 1510, the bottom end of the fifth rotating shaft 1508 is provided with another bevel gear, the two bevel gears are meshed with each other, a second rotating disc 1512 is arranged at the front end of the sixth rotating shaft 1510, a fixing rod 1513 is arranged between the lower parts of the first rotating disc 1505 and the second rotating disc 1512, an extruding rod 1514 is arranged on the fixing rod 1513, a circle of small holes are uniformly arranged at the bottom end of the extruding rod 1514 at intervals, and the extruding rod 1514 is positioned in the second fixing shell 14.

The servo motor 5 rotates to drive the third rotating shaft 1503 to rotate through the second belt pulley component 1504, the third rotating shaft 1503 rotates to drive the second bevel gear component 1507 to mesh, the second bevel gear component 1507 rotates to drive the fourth rotating shaft 1506 to rotate, the fourth rotating shaft 1506 rotates to drive the fifth rotating shaft 1508 to rotate through the third belt pulley component 1509, the fifth rotating shaft 1508 rotates to drive the third bevel gear component 1511 to mesh, the third bevel gear component 1511 rotates to drive the sixth rotating shaft 1510 to rotate, the sixth rotating shaft 1510 and the third rotating shaft 1503 rotate to drive the second rotating disc 1512 and the first rotating disc 1505 to rotate, the first rotating disc 1505 and the second rotating disc 1512 rotate to drive the fixing rod 1513 to rotate, the fixing rod 1513 rotates to drive the extrusion rod 1514 to slide up and down, the extrusion rod 1514 slides down on the second fixed shell 14, thereby realizing preliminary grinding of the massive solid beverage in the second fixed shell 14, and after the solid beverage is completely ground, the worker turns off the servo motor 5, the servo motor 5 stops rotating to drive the third rotating shaft 1503 to stop rotating through the second belt pulley component 1504, the third rotating shaft 1503 stops rotating to drive the second bevel gear component 1507 to stop meshing, the second bevel gear component 1507 stops rotating to drive the fourth rotating shaft 1506 to stop rotating, the fourth rotating shaft 1506 stops rotating to drive the fifth rotating shaft 1508 to stop rotating through the third belt pulley component 1509, the fifth rotating shaft 1508 stops rotating to drive the third bevel gear component 1511 to stop meshing, the third bevel gear component 1511 stops rotating to drive the sixth rotating shaft 1510 to stop rotating, the sixth rotating shaft 1510 and the third rotating shaft 1503 stop rotating to drive the second rotating disc 1512 and the first rotating disc 1505 to stop rotating, the first rotating disc 1505 and the second rotating disc 1512 stop rotating to drive the fixing rod 1513 to stop rotating, the fixing rod 1513 stops rotating to drive the extrusion rod 1514 to stop sliding, and the device is simple in structure, and the extrusion rod 1514 slides up and down to primarily crush massive solid beverages in the second fixing shell 14.

The feeding mechanism 16 comprises a third support frame 1601, a feeding hopper 1602, a feeding pipe 1603, a limit frame 1604, a material blocking plate 1605, a first elastic member 1606, a first limit block 1607, a clamping block 1608, a second elastic member 1609 and a clamping column 1610, wherein the third support frame 1601 is arranged on the left side of the first fixed shell 3, the feeding hopper 1602 is arranged on the third support frame 1601, the feeding pipe 1603 is arranged at the bottom end of the feeding hopper 1602, the right end of the feeding pipe 1603 is connected with the second fixed shell 14, the limit frame 1604 is arranged on the feeding pipe 1603, the material blocking plate 1605 is arranged in the limit frame 1604 in a sliding manner, first elastic members 1606 are arranged between the front and back sides of the upper portion of the material blocking plate 1605 and the front and back sides of the lower portion of the limit frame 1604, a first limit block 1607 is arranged on the feeding pipe 1603, a clamping block 1608 is arranged on the first limit block 1607 in a sliding manner, the clamping block 1608 is matched with the material blocking plate 1605, and a second elastic member 1609 is symmetrically arranged between one side of the clamping block 1608 and one side of the first limit block 1607, a clamping post 1610 is slidably disposed on the left side of the first limit block 1607, and the clamping post 1610 is engaged with the clamping block 1608.

When solid beverage needs to be finely ground, a worker presses the striker plate 1605 to slide downwards on the limiting frame 1604 to block the feed pipe 1603, the first elastic member 1606 is compressed, the striker plate 1605 moves downwards to avoid extruding the fixture block 1608, the second elastic member 1609 is reset to drive the fixture block 1608 to slide rightwards on the first limiting block 1607 to block the striker plate 1605, then the massive solid beverage of the worker is poured into the feed hopper 1602, after the massive solid beverage is poured into the feed hopper 1602, the worker moves upwards by pulling the blocking column 1610 to drive the fixture block 1608 to slide leftwards on the first limiting block 1607 to avoid blocking the striker plate 1605, the first elastic member 1606 is reset to drive the striker plate 1605 to slide upwards on the limiting frame 1604 to avoid blocking the feed pipe 1603, the solid beverage in the feed hopper 1602 falls into the second fixed shell 14 through the feed pipe 1603, and moves upwards and downwards through the extrusion rod 1601514 to grind, the device has a simple structure, and can block the feeding pipe 1603 during feeding.

Example 3

As shown in fig. 6, 7, 8, 9 and 10, based on embodiment 2, the blocking mechanism 17 includes a second fixing frame 1701, a second stop block 1702, a seventh rotating shaft 1703, a first fixed block 1704, a third circular gear 1705, a rack 1706, a second fixed block 1707 and a connecting band 1708, the second fixing frame 1701 is symmetrically disposed on the right side of the third supporting frame 1601, second stop blocks 1702 are slidably disposed on opposite sides of the two second fixing frames 1701, bottoms of the two second stop blocks 1702 are connected to the top of the striker 1605, a seventh rotating shaft 1703 is rotatably disposed between the two second stop blocks 1702, the first fixed block 1704 is symmetrically disposed on the seventh rotating shaft 1703, the two first stop blocks 1704 are engaged with the two second stop blocks 1702, a third circular gear 1705 is disposed on the seventh rotating shaft 1703, a rack 1706 is slidably disposed on the right side of the two second fixing frames 1701, the rack 1706 and the third round gear 1705 are meshed with each other, the left side of the upper portion of the extrusion rod 1514 is provided with a second fixing block 1707, the bottom end of the second fixing block 1707 is provided with a connecting band 1708, and the bottom end of the connecting band 1708 is connected with the rack 1706.

The pressing rod 1514 moves downwards to drive the second fixing block 1707 to move downwards, the connecting band 1708 is loosened, the second fixing block 1707 moves downwards to contact with the rack 1706, the rack 1706 moves downwards on the second fixing frame 1701 along with the rack 1706, the rack 1706 moves downwards through the third round gear 1705 to drive the second limit block 1702 to move downwards, the second limit block 1702 moves downwards to drive the stop plate 1605 to slide downwards on the limit frame 1604 to stop the feeding pipe 1603 due to the larger friction force of the third round gear 1705, the first elastic element 1606 is compressed, then the rack 1706 moves downwards to be meshed with the third round gear 1705, the third round gear 1705 rotates to drive the seventh rotating shaft 1703 to rotate, the seventh rotating shaft 1703 rotates to drive the first fixing block 1704 to rotate leftwards to stop the second limit block 1702, the stop block 1608 is no longer pressed by the downward movement of the stop plate 1605, the second elastic element 1609 resets to drive the stop block 1608 to slide rightwards on the first limit block 1607 to stop the stop plate 1605, the device has the advantages that the feeding pipe 1603 can be blocked and no longer fed when the extrusion rod 1514 moves downwards to primarily crush the solid beverage, when the extrusion rod 1514 moves upwards to drive the second fixing block 1707 to move upwards, the connecting band 1708 is tightened, the second fixing block 1707 moves upwards to pass through the connecting band 1708, the rack 1706 is further driven to move upwards to be meshed with the third circular gear 1705, the third circular gear 1705 rotates to drive the seventh rotating shaft 1703 to rotate, the seventh rotating shaft 1703 rotates to drive the first fixing block 1704 to rotate rightwards for ninety degrees and no longer clamp the second limiting block 1702, then a worker drives the clamping block 1608 to move upwards to slide leftwards on the first limiting block 1607 without clamping the striker plate 1605, the second elastic piece 1609 is compressed, the first elastic piece 1606 resets to drive the striker plate 1605 to slide upwards on the limiting frame 1604 without blocking the feeding pipe 1603, the device is simple in structure, the extrusion rod 1514 can move downwards to primarily crush the solid beverage, and the feeding pipe 1603 can be stopped And no blanking is performed.

The through hole mechanism 18 comprises a fixing cover 1801, a fixing seat 1802 and a top rod 1803, the fixing cover 1801 is arranged at the top of the second fixing shell 14, the fixing seat 1802 is arranged at the bottom of the fixing cover 1801, a circle of top rods 1803 are uniformly arranged at the bottom of the fixing seat 1802 at intervals, and the top rods 1803 are matched with small holes in the extrusion rod 1514.

When the extrusion rod 1514 moves upwards, the extrusion rod 1514 moves upwards to contact with the top rod 1803, and the top rod 1803 penetrates through small holes in the extrusion rod 1514, so that the rolling effect can be prevented from being influenced by the blockage of the small holes.

Rolling mechanism 19 is including eighth pivot 1901, first cylinder 1902, ninth pivot 1903, second cylinder 1904, kicking block 1905 and third elastic component 1906, base 1 rear side rotation type is provided with eighth pivot 1901, be provided with first cylinder 1902 on the eighth pivot 1901, even interval rotary type is provided with one row of ninth pivot 1903 on the base 1, one row all be provided with second cylinder 1904 on the ninth pivot 1903, base 1 rear side symmetry slidingtype is provided with kicking block 1905, two kicking block 1905 all is provided with third elastic component 1906 between one side dorsad and the base 1.

Before the solid beverage is finely ground, a worker places the collection frame on the base 1, the worker drives the first roller 1902 to rotate on the eighth rotating shaft 1901 by pushing the collection frame, the second roller 1904 rotates on the ninth rotating shaft 1903, the two sides of the collection frame extrude the top block 1905 to slide backwards on the base 1, the third elastic piece 1906 is compressed, when the collection frame moves to the discharge port of the first fixing shell 3 and does not extrude the top block 1905, the third elastic piece 1906 resets to drive the top block 1905 to slide backwards on the base 1 to reset, when the solid beverage powder in the collection frame reaches a certain amount, the worker drives the top block 1905 to slide backwards on the base 1 by pushing the top block 1905, the third elastic piece 1906 is compressed, then the worker pulls out the collection frame, and after the collection frame is pulled out, the third elastic piece 1906 resets to drive the top block 1905 to slide upwards on the base 1 to reset. This device simple structure can make the staff place and change when collecting the frame, reduces frictional force, comparatively laborsaving.

The limiting mechanism 20 comprises limiting shells 2001, wedge blocks 2002 and fourth elastic pieces 2003, the limiting shells 2001 are symmetrically arranged on the two sides, back to the two second fixing frames 1701, the wedge blocks 2002 are arranged in the four limiting shells 2001 in a sliding mode, the four wedge blocks 2002 are matched with the two second fixing frames 1701, and the fourth elastic pieces 2003 are arranged between the side, back to the four wedge blocks 2002, of the four wedge blocks and the opposite side of the four limiting shells 2001.

The second stopper 1702 moves downwards to press the wedge 2002 to slide backwards in the stopper casing 2001, the fourth elastic member 2003 is compressed, when the second stopper 1702 moves downwards to no longer press the wedge 2002, the fourth elastic member 2003 resets to drive the wedge 2002 to slide backwards in the stopper casing 2001 to block the second stopper 1702, when the rack 1706 moves upwards to engage with the third circular gear 1705, the third circular gear 1705 rotates to drive the seventh rotating shaft 1703 to rotate, the seventh rotating shaft 1703 rotates to drive the first fixing block 1704 to rotate rightwards by ninety degrees to no longer block the second stopper 1702, then the worker moves upwards by pulling the blocking column 1610 to drive the blocking block 1608 to slide leftwards on the first stopper 1607 to no longer block the striker 1605, the second elastic member 1609 is compressed, the rack 1706 moves upwards through the third circular gear 1705 to drive the second stopper 1702 to move upwards, because the second stopper 1702 moves upwards greatly, the second limiting block 1702 moves upwards to press the wedge block 2002 to slide backwards in the limiting shell 2001, the fourth elastic piece 2003 is compressed, the wedge block 2002 slides backwards to be free from blocking the second limiting block 1702, the second limiting block 1702 moves upwards to drive the baffle plate 1605 to slide upwards on the limiting frame 1604 to reset and stop the feeding pipe 1603, the first elastic piece 1606 resets along with the second limiting block 1702, and when the second limiting block 1702 moves upwards to stop pressing the wedge block 2002 again, the fourth elastic piece 2003 resets to drive the wedge block 2002 to slide inwards in the limiting shell 2001 to reset. The device has simple structure, and can prevent blocky solid beverage from falling onto the extrusion rod 1514 to cause the extrusion rod 1514 to be clamped when the extrusion rod 1514 is not completely lifted and reset.

The inner wall of the second fixing shell 14 is provided with a protrusion which can be matched with the grinding cone 13, so that the block-shaped solid beverage is ground more finely.

The above description is only an example of the present invention and is not intended to limit the present invention. All equivalents which come within the spirit of the invention are intended to be embraced therein. Details not described herein are well within the skill of those in the art.

Claims

1. A fine super-grinding device for solid beverage is characterized by comprising:

the device comprises a base (1), wherein a first support frame (2) is arranged on the base (1);

the first fixing shell (3) is arranged on the first support frame (2), and a discharge hole is formed in the bottom of the first fixing shell (3);

the motor base (4) is arranged on one side of the first fixed shell (3);

the servo motor (5) is arranged on the motor base (4);

the first rotating shaft (6) is rotatably arranged on one side of the first fixed shell (3);

the belt wheel device comprises a first belt pulley assembly (7), wherein the first belt pulley assembly (7) is arranged between an output shaft of the servo motor (5) and one end of a first rotating shaft (6), the first belt pulley assembly (7) consists of two belt pulleys and a flat belt, the output shaft of the servo motor (5) is provided with one belt pulley, one end of the first rotating shaft (6) is provided with the other belt pulley, and the flat belt is arranged between the two belt pulleys;

the first fixing frame (8), the first fixing shell (3) is internally provided with the first fixing frame (8);

a second rotating shaft (9), wherein one side of the first fixing frame (8) is rotatably provided with the second rotating shaft (9);

the first bevel gear component (10) is arranged between the bottom end of the second rotating shaft (9) and the other end of the first rotating shaft (6), the first bevel gear component (10) is composed of two bevel gears, one bevel gear is arranged at the bottom end of the second rotating shaft (9), the other bevel gear is arranged at the other end of the first rotating shaft (6), and the two bevel gears are meshed with each other;

the top end of the second rotating shaft (9) is provided with a first circular gear (11);

the top of the first fixing frame (8) is rotatably provided with a second circular gear (12), and the first circular gear (11) is meshed with the second circular gear (12);

the grinding cone (13) is arranged at the top of the second circular gear (12);

the top of the first fixed shell (3) is provided with a second fixed shell (14), and the grinding cone (13) is positioned in the second fixed shell (14);

the first support frame (2) is provided with an extrusion mechanism (15);

the feeding mechanism (16) is arranged on one side of the first fixed shell (3);

the pressing mechanism (15) includes:

the first support frame (2) is provided with a first support frame (1501);

the positioning frame (1502) is arranged at the top of the second supporting frame (1501);

the bottom of one side of the positioning frame (1502) is rotatably provided with a third rotating shaft (1503);

the second belt pulley component (1504) is arranged between one end of the third rotating shaft (1503) and the output shaft of the servo motor (5), the second belt pulley component (1504) consists of two belt pulleys and a flat belt, one end of the third rotating shaft (1503) is provided with one belt pulley, the output shaft of the servo motor (5) is provided with another belt pulley, and the flat belt is arranged between the two belt pulleys;

a first rotating disc (1505), wherein the other end of the third rotating shaft (1503) is provided with the first rotating disc (1505);

a fourth rotating shaft (1506), wherein the fourth rotating shaft (1506) is rotatably arranged on one side of the top of the positioning frame (1502);

the second bevel gear assembly (1507) is arranged between the bottom end of the fourth rotating shaft (1506) and the third rotating shaft (1503), the second bevel gear assembly (1507) consists of two bevel gears, one bevel gear is arranged at the bottom end of the fourth rotating shaft (1506), the other bevel gear is arranged on the third rotating shaft (1503), and the two bevel gears are meshed with each other;

a fifth rotating shaft (1508), wherein the other side of the upper part of the positioning frame (1502) is rotatably provided with the fifth rotating shaft (1508);

a third belt pulley assembly (1509), wherein the third belt pulley assembly (1509) is arranged between the top end of the fifth rotating shaft (1508) and the top end of the fourth rotating shaft (1506), the third belt pulley assembly (1509) consists of two belt pulleys and a flat belt, the top end of the fifth rotating shaft (1508) is provided with one belt pulley, the top end of the fourth rotating shaft (1506) is provided with another belt pulley, and the flat belt is arranged between the two belt pulleys; the other side of the bottom of the positioning frame (1502) is rotatably provided with a sixth rotating shaft (1510);

a third bevel gear assembly (1511) is arranged between one end of the sixth rotating shaft (1510) and the bottom end of the fifth rotating shaft (1508), the third bevel gear assembly (1511) consists of two bevel gears, one bevel gear is arranged at one end of the sixth rotating shaft (1510), another bevel gear is arranged at the bottom end of the fifth rotating shaft (1508), and the two bevel gears are meshed with each other;

the other end of the sixth rotating shaft (1510) is provided with a second rotating disc (1512);

a fixing rod (1513), wherein a fixing rod (1513) is arranged between the lower parts of the first rotating disc (1505) and the second rotating disc (1512);

the fixed rod (1513) is provided with an extrusion rod (1514), a circle of small holes are uniformly formed in the bottom end of the extrusion rod (1514) at intervals, and the extrusion rod (1514) is located in the second fixed shell (14);

the feed mechanism (16) includes:

a third supporting frame (1601), wherein the third supporting frame (1601) is arranged on one side of the first fixed shell (3);

the feeding hopper (1602), the third supporting frame (1601) is provided with the feeding hopper (1602);

the feeding hopper (1602) is provided with a feeding pipe (1603) at the bottom end, and the other end of the feeding pipe (1603) is connected with the second fixed shell (14);

the limiting frame (1604), wherein the feeding pipe (1603) is provided with the limiting frame (1604);

the material baffle plate (1605) is arranged in the limiting frame (1604) in a sliding mode;

the first elastic piece (1606) is arranged between two sides of the upper part of the striker plate (1605) and two sides of the lower part of the limiting frame (1604);

the feeding pipe (1603) is provided with a first limiting block (1607);

the clamping block (1608) is arranged on the first limiting block (1607) in a sliding mode, and the clamping block (1608) is matched with the material blocking plate (1605);

a second elastic piece (1609), a second elastic piece (1609) is symmetrically arranged between one side of the fixture block (1608) and one side of the first limit block (1607);

the clamping post (1610) is arranged on one side of the first limiting block (1607) in a sliding mode, and the clamping post (1610) is matched with the clamping block (1608);

the blocking mechanism (17) comprises:

the second fixing frame (1701), the second fixing frame (1701) is set symmetrically on one side of the third supporting frame (1601);

the opposite sides of the two second fixing frames (1701) are both provided with a second limiting block (1702) in a sliding mode, and the bottoms of the two second limiting blocks (1702) are connected with the top of the material baffle plate (1605); a seventh rotating shaft (1703), wherein the seventh rotating shaft (1703) is rotatably arranged between the two second limiting blocks (1702);

the seventh rotating shaft (1703) is symmetrically provided with first fixed blocks (1704), and the two first fixed blocks (1704) are matched with the two second limiting blocks (1702);

a third circular gear (1705), wherein the seventh rotating shaft (1703) is provided with the third circular gear (1705);

the racks (1706) are arranged on one side of the two second fixing frames (1701) in a sliding mode, and the racks (1706) are meshed with the third circular gear (1705);

a second fixed block (1707), wherein the second fixed block (1707) is arranged on one side of the upper part of the extrusion rod (1514);

the bottom end of the second fixing block (1707) is provided with a connecting belt (1708), and the bottom end of the connecting belt (1708) is connected with the rack (1706);

the through-hole mechanism (18) includes:

the top of the second fixing shell (14) is provided with a fixing cover (1801);

the bottom of the fixed cover (1801) is provided with a fixed seat (1802);

the bottom of the fixed seat (1802) is uniformly provided with a circle of ejector rods (1803) at intervals, and the ejector rods (1803) are matched with small holes in the extrusion rod (1514);

the rolling mechanism (19) includes:

an eighth rotating shaft (1901), wherein the eighth rotating shaft (1901) is rotatably arranged on one side of the base (1);

the first roller (1902), the eighth rotating shaft (1901) is provided with the first roller (1902);

a row of ninth rotating shafts (1903) are rotatably arranged on the base (1) at uniform intervals;

the second rollers (1904) are arranged on the ninth rotating shafts (1903) in one row;

the ejection block (1905), one side of the base (1) is symmetrically and slidably provided with the ejection block (1905);

the third elastic piece (1906) is arranged between one side, back to the base (1), of each of the two top blocks (1905);

the stopper mechanism (20) includes:

the two second fixing frames (1701) are symmetrically provided with limiting shells (2001) on the sides opposite to each other;

the four limiting shells (2001) are internally provided with wedge blocks (2002) in a sliding manner, and the four wedge blocks (2002) are matched with the two second fixing frames (1701); and fourth elastic pieces (2003) are arranged between one side of each of the four wedge blocks (2002) facing away from the corresponding side of the four limiting shells (2001).

2. A fine micromilling device for solid beverages, as in claim 1, characterized in that the inner wall of said second stationary shell (14) is provided with projections.