CN217395030U - Multi-channel connected rotary freeze-drying slicing device - Google Patents

Abstract

The utility model belongs to the technical field of the section device technique and specifically relates to a formula freeze-drying section device that rotates that multichannel is connected, including the frame, feed mechanism is installed to the inboard one end of frame, and supporting mechanism is installed to feed mechanism's exit end, and supporting mechanism's bottom fixed mounting has the guide swash plate, and section mechanism is installed to supporting mechanism's top, and section mechanism includes second motor, cam, mount pad, pinch roller, slide bar, answer spring, mounting panel and cutter unit spare. The utility model discloses an adjustment of blade section thickness, this requirement that just can satisfy actual different section thickness.

Description

Multi-channel connected rotary freeze-drying slicing device

Technical Field

The utility model relates to a rotation formula freeze-drying section device technical field that the multichannel is connected especially relates to a rotation formula freeze-drying section device that multichannel is connected.

Background

In real life, some medicinal materials need to be sliced after freeze-drying, but the traditional medicinal material slicing is generally manually sliced, so that the efficiency is low, a large amount of labor waste is caused, and the slicing efficiency and effect are seriously reduced;

to this end, chinese patent publication No. CN201920264085.2 discloses that "a tricholoma matsutake slicing apparatus based on tricholoma matsutake freeze-drying production includes: a box body; the transmission structure is fixed at the bottom of the inner wall of the box body and comprises a support frame, and the top of the support frame is fixedly connected with a movable groove; the two sides of the moving plate are respectively fixed on the front surface and the back surface of the inner wall of the movable groove; the bottom of the first motor is fixed to the bottom of the inner wall of the box body and is positioned on one side of the supporting frame, and a first belt pulley is fixedly connected to the outer surface of an output shaft of the first motor;

in the patent, a cam is driven to rotate by a second motor, and a blade moves by the cooperation of the cam and an extrusion spring; although this method realizes automatic slicing, it cannot realize adjustment of slice thickness, and thus cannot meet the requirements of slices with different thicknesses.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the shortcoming that the adjustment to slice thickness can't be realized to exist among the prior art, and the rotation formula freeze-drying section device that a multichannel is connected that proposes.

In order to realize the purpose, the utility model adopts the following technical scheme:

the design is a multichannel-connected rotary freeze-drying slicing device which comprises a rack, wherein a feeding mechanism is installed at one end of the inner side of the rack, a supporting mechanism is installed at the outlet end of the feeding mechanism, a material guide inclined plate is fixedly installed at the bottom of the supporting mechanism, a slicing mechanism is installed above the supporting mechanism, and the slicing mechanism comprises a second motor, a cam, an installation seat, a pressing wheel, a sliding rod, a return spring, an installation plate and a cutter assembly;

second motor fixed mounting is at the top of frame, cam fixed mounting is on the output shaft of second motor, the slide bar run through the roof of frame, and with frame sliding connection, mount pad fixed mounting is on the top of slide bar, the pinch roller rotate install the mount pad inboard, and with cam intermittent type nature contact, the answer spring housing is established on the slide bar, mounting panel fixed mounting is in the bottom of slide bar, cutter unit installs the bottom at the mounting panel.

Preferably, the feeding mechanism comprises a feeding barrel, a feeding pipe, a discharging pipe, a spiral conveying shaft and a first motor; the feeding barrel is fixedly installed on the inner side of the rack, the discharging pipe is fixedly installed at one end of the top of the feeding barrel, the discharging pipe is fixedly installed at the outlet end of the feeding barrel, the spiral conveying shaft is rotatably installed on the inner side of the feeding barrel, the first motor is fixedly installed on the outer side of the feeding barrel, and the output shaft is fixedly connected with the spiral conveying shaft.

Preferably, the supporting mechanism comprises a supporting platform, two guard plates and a baffle plate; the supporting table is fixedly installed on the inner side of the rack, the two guard plates are fixedly installed on two sides of the supporting table in parallel, and the baffle is rotatably connected with the end portion of the supporting table through a pin shaft and is perpendicular to the supporting table.

Preferably, the two ends of the baffle are coaxially and fixedly provided with gears, the two ends of the baffle pin shaft are sleeved with coil springs, one ends of the two coil springs are fixedly connected with the two gears respectively, and the other ends of the two coil springs are fixedly connected with the pin shaft of the baffle.

Preferably, mounting panel bottom fixed mounting has two connecting rods that are parallel to each other, two the equal fixed mounting in bottom of connecting rod has the rack, two the rack meshes with two gear intermittence respectively.

Preferably, the cutter assembly comprises a mounting frame, a screw rod, a movable block, a guide rod, a blade, a first bevel gear, a third motor and a second bevel gear; mounting bracket fixed mounting is in the bottom of mounting panel, the lead screw rotates to be installed at the mounting bracket inboardly, the top thread of movable block is installed on the lead screw, guide bar fixed mounting is inboard at the mounting bracket, the guide bar run through the movable block, and with movable block sliding connection, blade fixed mounting is in the bottom of movable block, first bevel gear fixed mounting is at the tip of lead screw, third motor fixed mounting is at the mounting panel top, second bevel gear fixed mounting on the output shaft of third motor, and with first bevel gear meshing.

The utility model provides a pair of formula freeze-drying section device is rotated in multichannel connection, beneficial effect lies in: before the work, make second bevel gear rotate through starting the third motor to make first bevel gear drive the lead screw and rotate, this just makes the movable block drive the blade and removes along the guide bar, and then changes the skew distance of blade and baffle, has just also realized the adjustment of blade section thickness, and this requirement that just can satisfy actual different section thickness.

Drawings

Fig. 1 is a schematic structural diagram of a multi-channel connected rotary freeze-drying slicing device according to the present invention;

fig. 2 is a schematic structural diagram of a feeding mechanism of a multi-channel connected rotary freeze-drying slicing device according to the present invention;

fig. 3 is a schematic structural diagram of a supporting mechanism of a multi-channel connected rotary type freeze-drying slicing device provided by the present invention;

fig. 4 is a schematic structural diagram of a slicing mechanism of a multi-channel connected rotary freeze-drying slicing device according to the present invention;

fig. 5 is the utility model provides a structural schematic diagram of the cutter subassembly of the rotatory freeze-drying section device of multichannel connection.

In the figure: the device comprises a frame 1, a feeding mechanism 2, a feeding barrel 21, a feeding pipe 22, a discharging pipe 23, a spiral conveying shaft 24, a first motor 25, a supporting mechanism 3, a supporting table 31, a protective plate 32, a baffle 33, a gear 34, a coil spring 35, a material guide inclined plate 4, a slicing mechanism 5, a second motor 51, a cam 52, a mounting seat 53, a pressing wheel 54, a sliding rod 55, a return spring 56, a mounting plate 57, a connecting rod 58, a rack 59, a cutter assembly 50, a mounting frame 501, a screw rod 502, a movable block 503, a guide rod 504, a blade 505, a first bevel gear 506, a third motor 507 and a second bevel gear 508.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Example 1:

referring to fig. 1-4, a multi-channel connected rotary freeze-drying slicing device comprises a frame 1, wherein a feeding mechanism 2 is installed at one end of the inner side of the frame 1, a supporting mechanism 3 is installed at the outlet end of the feeding mechanism 2, a material guide inclined plate 4 is fixedly installed at the bottom of the supporting mechanism 3, a slicing mechanism 5 is installed above the supporting mechanism 3, and the slicing mechanism 5 comprises a second motor 51, a cam 52, a mounting seat 53, a pressing wheel 54, a sliding rod 55, a return spring 56, a mounting plate 57 and a cutter assembly 50; the second motor 51 is fixedly installed at the top of the rack 1, the cam 52 is fixedly installed on an output shaft of the second motor 51, the sliding rod 55 penetrates through the top wall of the rack 1 and is in sliding connection with the rack 1, the installation seat 53 is fixedly installed at the top end of the sliding rod 55, the pressing wheel 54 is rotatably installed on the inner side of the installation seat 53 and is in intermittent contact with the cam 52, the return spring 56 is sleeved on the sliding rod 55, the installation plate 57 is fixedly installed at the bottom end of the sliding rod 55, and the cutter assembly 50 is installed at the bottom of the installation plate 57. The return spring 56 not only provides a cushioning effect, but also allows the puck 54 to return to its original state after it has been disengaged from the cam 52.

The feeding mechanism 2 comprises a feeding barrel 21, a feeding pipe 22, a discharging pipe 23, a spiral conveying shaft 24 and a first motor 25; feeding barrel 21 is fixed mounting in the inboard of frame 1, discharging pipe 23 fixed mounting is in the one end at feeding barrel 21's top, and discharging pipe 23 fixed mounting is in feeding barrel 21's exit end, and auger delivery axle 24 rotates and installs in feeding barrel 21 inboard, and first motor 25 fixed mounting is in feeding barrel 21's the outside, and output shaft and auger delivery axle 24 fixed connection.

The supporting mechanism 3 comprises a supporting platform 31, two guard plates 32 and a baffle 33; the support table 31 is fixedly arranged on the inner side of the frame 1, the two guard plates 32 are fixedly arranged on two sides of the support table 31 in parallel, and the baffle 33 is rotatably connected with the end part of the support table 31 through a pin shaft and is arranged perpendicular to the support table 31; gears 34 are coaxially and fixedly installed at two ends of the baffle 33, coil springs 35 are sleeved at two ends of a pin shaft of the baffle 33, one ends of the two coil springs 35 are fixedly connected with the two gears 34 respectively, and the other ends of the two coil springs 35 are fixedly connected with the pin shaft of the baffle 33; two parallel connecting rods 58 are fixedly mounted at the bottom of the mounting plate 57, racks 59 are fixedly mounted at the bottom ends of the two connecting rods 58, and the two racks 59 are intermittently meshed with the two gears 34 respectively.

The working principle is as follows: firstly, introducing materials into the feeding barrel 21 through the feeding pipe 22, then starting the first motor 25 to enable the spiral conveying shaft 24 to rotate, so that the materials are conveyed into the discharging pipe 23, and then the materials are conveyed onto the supporting platform 31 through the discharging pipe 23 to be in contact with the baffle 33;

meanwhile, the second motor 51 is started to enable the cam 52 to rotate, when the cam 52 is in contact with the pressing wheel 54, the pressing wheel 54 is stressed to drive the sliding rod 55 to move downwards, and meanwhile, the return spring 56 is stressed to compress to continue elastic potential energy, so that the mounting plate 57 drives the cutter assembly 50 to move downwards to slice materials; when cam 52 disengages from puck 54, return springs 56 release potential energy causing puck 54 to move upward; the above circulation is performed, so that the cutter assembly 50 can perform intermittent slicing on the material;

in the downward movement process of the mounting plate 57, the two racks 59 move downward to be meshed with the two gears 34, so that the gears 34 drive the baffle 33 to rotate, and the sliced materials can be guided into and out of the material guide inclined plate 4; when the rack 59 moves upwards to be separated from the gear 34, the baffle 33 is restored to the initial state under the action of the coil spring 35; the whole process is completely automated, and the labor intensity of workers is greatly reduced.

Example 2:

referring to fig. 1 to 5, as another preferred embodiment of the present invention, there is a difference from embodiment 1 in that the cutter assembly 50 includes a mounting bracket 501, a screw 502, a movable block 503, a guide bar 504, a blade 505, a first bevel gear 506, a third motor 507, and a second bevel gear 508; the mounting frame 501 is fixedly mounted at the bottom of the mounting frame 57, the screw rod 502 is rotatably mounted on the inner side of the mounting frame 501, the top end of the movable block 503 is mounted on the screw rod 502 in a threaded manner, the guide rod 504 is fixedly mounted on the inner side of the mounting frame 501, the guide rod 504 penetrates through the movable block 503 and is in sliding connection with the movable block 503, the blade 505 is fixedly mounted at the bottom of the movable block 503, the first bevel gear 506 is fixedly mounted at the end of the screw rod 502, the third motor 507 is fixedly mounted at the top of the mounting frame 57, and the second bevel gear 508 is fixedly mounted on an output shaft of the third motor 507 and is meshed with the first bevel gear 506.

Before the operation, the third motor 507 is started to enable the second bevel gear 508 to rotate, so that the first bevel gear 506 drives the screw rod 502 to rotate, the movable block 503 drives the blade 505 to move along the guide rod 504, the offset distance between the blade 505 and the baffle 33 is further changed, the slicing thickness of the blade 505 is adjusted, and the requirements of different actual slicing thicknesses can be met.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. A multi-channel connected rotary freeze-drying slicing device comprises a rack (1) and is characterized in that a feeding mechanism (2) is installed at one end of the inner side of the rack (1), a supporting mechanism (3) is installed at the outlet end of the feeding mechanism (2), a material guide inclined plate (4) is fixedly installed at the bottom of the supporting mechanism (3), a slicing mechanism (5) is installed above the supporting mechanism (3), and the slicing mechanism (5) comprises a second motor (51), a cam (52), a mounting seat (53), a pressing wheel (54), a sliding rod (55), a return spring (56), a mounting plate (57) and a cutter assembly (50);

second motor (51) fixed mounting is at the top of frame (1), cam (52) fixed mounting is on the output shaft of second motor (51), top wall that frame (1) was run through in slide bar (55) and with frame (1) sliding connection, mount pad (53) fixed mounting is on the top of slide bar (55), pinch roller (54) rotate install mount pad (53) inboard and with cam (52) intermittent type nature contact, answer spring (56) cover is established on slide bar (55), mounting panel (57) fixed mounting is in the bottom of slide bar (55), the bottom at mounting panel (57) is installed in cutter subassembly (50).

2. The multi-channel connected rotary freeze-drying slicing device according to claim 1, wherein the feeding mechanism (2) comprises a feeding barrel (21), a feeding pipe (22), a discharging pipe (23), a spiral conveying shaft (24) and a first motor (25); the feeding barrel (21) is fixedly installed on the inner side of the rack (1), the discharging pipe (23) is fixedly installed at one end of the top of the feeding barrel (21), the discharging pipe (23) is fixedly installed at the outlet end of the feeding barrel (21), the spiral conveying shaft (24) is rotatably installed on the inner side of the feeding barrel (21), the first motor (25) is fixedly installed on the outer side of the feeding barrel (21), and the output shaft is fixedly connected with the spiral conveying shaft (24).

3. A multi-channel linked rotary lyophilization slicing apparatus according to claim 2, wherein the support mechanism (3) comprises a support table (31), two guards (32) and a baffle (33); support table (31) fixed mounting is in the inboard of frame (1), two backplate (32) parallel fixed mounting is in the both sides of support table (31), baffle (33) rotate through the round pin axle with the tip of support table (31) be connected, and with the perpendicular setting of support table (31).

4. The multi-channel connected rotary freeze-drying slicing device according to claim 3, wherein gears (34) are coaxially and fixedly mounted at both ends of the baffle plate (33), coil springs (35) are sleeved at both ends of a pin shaft of the baffle plate (33), one ends of the two coil springs (35) are respectively and fixedly connected with the two gears (34), and the other ends of the two coil springs (35) are respectively and fixedly connected with the pin shaft of the baffle plate (33).

5. The multichannel-connected rotary freeze-drying slicing device according to claim 4, wherein two parallel connecting rods (58) are fixedly mounted at the bottom of the mounting plate (57), racks (59) are fixedly mounted at the bottom ends of the two connecting rods (58), and the two racks (59) are intermittently meshed with the two gears (34) respectively.

6. The multi-channel connected rotary freeze-drying slicing device according to claim 5, wherein the cutter assembly (50) comprises a mounting frame (501), a screw rod (502), a movable block (503), a guide rod (504), a blade (505), a first bevel gear (506), a third motor (507) and a second bevel gear (508); mounting bracket (501) fixed mounting is in the bottom of mounting panel (57), lead screw (502) are rotated and are installed at mounting bracket (501) inboard, the top thread of movable block (503) is installed on lead screw (502), guide bar (504) fixed mounting is inboard in mounting bracket (501), guide bar (504) run through movable block (503) and with movable block (503) sliding connection, blade (505) fixed mounting is in the bottom of movable block (503), first bevel gear (506) fixed mounting is at the tip of lead screw (502), third motor (507) fixed mounting is at mounting panel (57) top, second bevel gear (508) fixed mounting is on the output shaft of third motor (507) and meshes with first bevel gear (506).

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