CN220292921U - High-efficient combined type osteoclast - Google Patents

Abstract

The utility model discloses a high-efficiency composite type bone crusher, which belongs to the field of food processing, and comprises a machine shell, wherein the machine shell is provided with a cavity, and a mounting seat is arranged in the cavity; the mount pad is U type and installs on it and be equipped with a set of broken bone mechanism, broken bone mechanism includes two regulation spouts of seting up respectively in the mount pad both sides, all radial slip is equipped with a slider in two regulation spouts, rotates through cooperation bearing spare and pivot between two sliders and is equipped with first compression roller. The high-efficiency combined type bone crusher has the advantages of freely adjusting the bone crushing distance between the compression rollers, crushing bones with different specifications and sizes, being efficient and wide in application range, and the first rotating shaft can radially slide in the adjusting chute through mutual motion coordination of a plurality of parts in the arranged bone crushing mechanism, so that the adjustment of the bone crushing distance between the first compression roller and the second compression roller is completed, and finally, the quick and accurate variable-pitch bone crushing according to the different bone crushing size requirements is realized.

Description

High-efficient combined type osteoclast

Technical Field

The utility model belongs to the field of food processing, and particularly relates to a high-efficiency composite type bone crusher.

Background

The pet food mainly provides basic nutrition substances required by life guarantee, growth and development and health for various pets, has the advantages of comprehensive nutrition, high digestibility, scientific formula, quality standard, convenient feeding and use, capability of preventing certain diseases and the like, and is usually required to be used for processing bones.

When the bone crusher is used, bones are usually placed in the bone crusher manually, the bones are extruded and crushed through the two compression rollers which rotate oppositely in the bone crusher, after crushing is finished, crushed bones are collected manually, the extrusion space between the compression rollers of the existing bone crusher cannot be adjusted according to requirements, and the compression rollers with different circle diameter specifications are required to be installed in an adapting mode according to the size of the broken bones when the bones are crushed due to different size requirements of the broken bones, and then the circle number of the compression rollers is changed to meet the requirement of crushing the broken bones with different sizes.

Disclosure of Invention

Aiming at one or more of the defects or improvement demands of the prior art, the utility model provides a high-efficiency compound type bone crusher, which has the advantages of freely adjusting the bone crushing distance between compression rollers, crushing broken bones with different specifications and sizes, high efficiency and wide application range.

In order to achieve the above-mentioned purpose, the present utility model provides a high-efficiency composite osteoclast, which comprises a casing, wherein the casing has a cavity and a mounting seat is installed in the cavity;

the installation seat is U-shaped, a group of bone breaking mechanisms are arranged on the installation seat, each bone breaking mechanism comprises two adjusting sliding grooves which are respectively arranged on two sides of the installation seat, a sliding block is radially arranged in each adjusting sliding groove in a sliding manner, and a first compression roller is arranged between each sliding block and the corresponding rotating shaft in a rotating manner through a matched bearing piece;

the bone breaking mechanism further comprises a second compression roller which can rotate in the mounting seat, and the first compression roller and the second compression roller are arranged in parallel;

the upper end face of the shell is provided with a feed hopper in a penetrating way, and one side of the shell is provided with an opening and a collecting box in a sliding way.

As a further improvement of the utility model, the bone breaking mechanism further comprises two reciprocating motors which are respectively fixed on one side of the adjusting chute, the two reciprocating motors are both fixed on the mounting seat through the motor seat and are arranged on the same side, the output ends of the two reciprocating motors are both connected with a small threaded screw rod, and one ends of the two small threaded screw rods extend into the adjusting chute through the mounting seat and are in threaded engagement with the sliding block.

As a further improvement of the utility model, a first rotating shaft is arranged between the two sliding blocks, two ends of the first rotating shaft are propped against the adjacent sliding blocks and rotate between the two sliding blocks through bearing pieces, the first roller is sleeved on the outer circumferential surface of the first rotating shaft, and two ends of the first rotating shaft penetrate through the side of the mounting seat to the outside and are fixedly connected with a first gear.

As a further improvement of the utility model, the bone breaking mechanism further comprises a second rotating shaft, two ends of the second rotating shaft rotate on the inner wall of the mounting seat through bearing pieces, two ends of the second rotating shaft extend to the outside through the side of the mounting seat and are fixedly connected with a driving gear, one side of one driving gear is provided with a driving motor, the driving motor is fixed on the inner wall of the casing through a motor seat, the output end of the driving motor is connected with one end part of the second rotating shaft, and the first gear is meshed with the driving gear.

As a further improvement of the utility model, the bone breaking mechanism further comprises a third rotating shaft, two ends of the third rotating shaft rotate on the inner wall of the mounting seat through bearing pieces, and two ends of the third rotating shaft extend to the outside through the mounting seat and are fixedly connected with a linkage gear, and the linkage gear is meshed with the driving gear.

As a further improvement of the utility model, the bone breaking mechanism further comprises a fourth rotating shaft, two ends of the fourth rotating shaft rotate on the inner wall of the mounting seat through bearing pieces, two ends of the fourth rotating shaft penetrate through the mounting seat to the outside and are fixedly connected with a second gear, and the second gear is meshed with the linkage gear.

In general, the above technical solutions conceived by the present utility model have the beneficial effects compared with the prior art including:

according to the high-efficiency combined type bone breaking machine, through mutual movement coordination of a plurality of components in the arranged bone breaking mechanism, the arranged first rotating shaft can radially slide in the adjusting chute, so that the adjustment of the bone breaking distance between the first pressing roller and the second pressing roller is finished, through changing the distance between the first pressing roller and the second pressing roller and through mutual transmission among a plurality of groups of gears which are cooperatively arranged, the rapid and accurate variable-pitch bone breaking according to different bone breaking size requirements is finally realized, compared with the traditional mode that the circle diameter of the pressing roller is changed, the adjustment of the bone breaking distance is realized through changing the position of the sliding block, the efficiency is higher, the operation is concise, the distance control is more accurate, the combined type bone breaking work of the machine is realized through the variable-pitch type bone breaking work between the two pressing rollers, the bone breaking efficiency is greatly improved, and meanwhile, the application range is wider.

Drawings

FIG. 1 is a schematic view of the overall installation structure of the present utility model;

FIG. 2 is a schematic view of the mounting structure of the housing, hopper and collection box of the present utility model;

FIG. 3 is a schematic view of the overall mounting structure of the present utility model with an osteoclast mechanism on a mounting base;

FIG. 4 is a schematic view of the intermeshing structure between the first gear, the second gear, the drive gear and the linking gear of the present utility model;

fig. 5 is a schematic view of an installation structure of a first rotating shaft on a sliding block according to the present utility model.

Like reference numerals denote like technical features throughout the drawings, in particular: 1. a housing; 2. a feed hopper; 31. a mounting base; 3. a bone-breaking mechanism; 32. adjusting the chute; 33. a slide block; 34. a reciprocating motor; 35. a small thread screw rod; 36. a first rotating shaft; 361. a first press roller; 37. a first gear; 38. a second rotating shaft; 39. a drive gear; 391. a driving motor; 392. a third rotating shaft; 393. a linkage gear; 394. a fourth rotating shaft; 395. a second gear; 396. a second press roller; 4. and (5) collecting a box.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples

1-5, a high-efficiency composite osteoclast comprises a casing 1, wherein the casing 1 is provided with a cavity, and a mounting seat 31 is arranged in the cavity;

the mounting seat 31 is U-shaped, a group of bone breaking mechanisms 3 are arranged on the mounting seat, the bone breaking mechanisms 3 comprise two adjusting sliding grooves 32 which are respectively arranged on two sides of the mounting seat 31, a sliding block 33 is radially arranged in each of the two adjusting sliding grooves 32 in a sliding manner, and a first compression roller 361 is arranged between the two sliding blocks 33 and the rotating shaft in a rotating manner through a matched bearing piece;

the bone breaking mechanism 3 further comprises a second compression roller 396 rotatable in the mounting seat 31, and the first compression roller 361 and the second compression roller 396 are arranged in parallel;

the upper end face of the machine shell 1 is provided with a feed hopper 2 in a penetrating way, one side of the machine shell 1 is provided with an opening, and a collecting box 4 is arranged in a sliding way.

In this embodiment, through the cooperation of the mutual motion of a plurality of parts in the broken bone mechanism 3 that sets up, make the first pivot 36 that sets up radially slide in adjusting chute 32, and then accomplish the broken bone interval adjustment between first compression roller 361 and the second compression roller 396, through the mutual transmission between the multiunit gear that changes the interval of first compression roller 361 and second compression roller 396 and set up through the cooperation, it can carry out quick and accurate variable-pitch broken bone to have finally realized according to the broken bone size demand of difference, compare in traditional mode through changing the compression roller circle footpath, adjust broken bone interval through changing the position of slider 33, not only efficiency is higher and the operation is succinct, distance control is more accurate, through the broken bone work of variable-pitch between two compression rollers, the compound broken bone work of this machine has been realized, broken bone efficiency has been greatly improved, different broken bone demands have been realized simultaneously, application scope is wider.

Specifically, referring to fig. 1 to 3 and 5, the bone breaking mechanism 3 further includes two reciprocating motors 34 respectively fixed on one side of the adjusting chute 32, the two reciprocating motors 34 are both fixed on the mounting seat 31 through the motor seat and are arranged on the same side, the output ends of the two reciprocating motors 34 are both connected with a small threaded screw rod 35, and one ends of the two small threaded screw rods 35 extend into the adjusting chute 32 through the mounting seat 31 and are in threaded engagement with the sliding block 33.

In this embodiment, the two reciprocating motors 34 are connected to an external power source and a motor co-frequency device, and the output ends of the two reciprocating motors 34 are controlled to rotate synchronously, so that the small threaded screw rod 35 connected with the two reciprocating motors rotates, and when the small threaded screw rod 35 rotates, the two sliding blocks 33 can slide radially in the adjusting sliding groove 32.

Specifically, referring to fig. 1 to 5, a first rotating shaft 36 is disposed between two sliding blocks 33, two ends of the first rotating shaft 36 are abutted against adjacent sliding blocks 33 and rotate between the two sliding blocks 33 through bearing members, a first pressing roller 361 is sleeved on the outer circumferential surface of the first rotating shaft 36, and two ends of the first rotating shaft 36 penetrate through the side of the mounting seat 31 to the outside and are fixedly connected with a first gear 37.

In this embodiment, when the small threaded screw rod 35 rotates, the two sliding blocks 33 can slide radially in the adjusting chute 32, and the first pressing roller 361 can slide radially through the connection of the first rotating shaft 36 on the sliding blocks 33, so that the osteoclast gap between the first pressing roller 361 and the second pressing roller 396 is completed, and a user can accurately adjust the gap according to different osteoclast requirements.

Specifically, referring to fig. 1 to 5, the bone-breaking mechanism 3 further includes a second rotating shaft 38, two ends of the second rotating shaft 38 rotate on an inner wall of the mounting seat 31 through bearing members, two ends of the second rotating shaft 38 extend to the outside through an edge of the mounting seat 31 and are fixedly connected with a driving gear 39, one side of one driving gear 39 is provided with a driving motor 391, the driving motor 391 is fixed on the inner wall of the casing 1 through the motor seat, an output end of the driving motor 391 is connected with one end of the second rotating shaft 38, and the first gear 37 is meshed with the driving gear 39.

In this embodiment, the driving motor 391 is powered on, so that the output end of the driving motor 391 drives and rotates the second rotating shaft 38, and when the second rotating shaft 38 rotates, the driving gear 39 fixed to the second rotating shaft 38 can rotate along with the second rotating shaft, and the driving gear 39 can drive the first gear 37 to rotate through the driving gear 39 by virtue of the engagement between the first gear 37 and the driving gear 39, so that the first rotating shaft 36 and the first pressing roller 361 rotate.

Specifically, referring to fig. 1 to 5, the bone-breaking mechanism 3 further includes a third rotating shaft 392, two ends of the third rotating shaft 392 are rotated on the inner wall of the mounting seat 31 through bearing members, two ends of the third rotating shaft 392 extend to the outside through the mounting seat 31 and are fixedly connected with a linkage gear 393, and the linkage gear 393 is meshed with the driving gear 39.

In the present embodiment, the third rotating shaft 392 can rotate through the engagement of the driving gear 39 and the linkage gear 393.

Specifically, referring to fig. 1 to 5, the bone-breaking mechanism 3 further includes a fourth rotating shaft 394, two ends of the fourth rotating shaft 394 are rotated on the inner wall of the mounting seat 31 through bearing members, two ends of the fourth rotating shaft 394 penetrate through the mounting seat 31 to the outside and are fixedly connected with a second gear 395, and the second gear 395 is meshed with the linkage gear 393.

In this embodiment, through the engagement between the set linkage gear 393 and the second gear 395, the second press roller 396 can rotate synchronously under the transmission of the fourth rotating shaft 394, and through the mutual transmission among the plurality of gears, the opposite synchronous rotation of the second press roller 396 and the first press roller 361 is finally realized.

The utility model relates to a high-efficiency compound bone-breaking machine:

the first step: when a user uses the bone breaker, firstly, the bone breaking mechanism 3 is adjusted according to different bone breaking size requirements, during adjustment, the two reciprocating motors 34 are connected with an external power supply and a motor co-frequency device, the output ends of the two reciprocating motors 34 are controlled to synchronously rotate, so that a small threaded screw rod 35 connected with the two reciprocating motors rotates, when the small threaded screw rod 35 rotates, the two sliding blocks 33 can slide radially in the adjusting sliding groove 32, the first pressing roller 361 can slide radially through the connection of the first rotating shaft 36 on the sliding blocks 33, at the moment, the bone breaking distance between the first pressing roller 361 and the second pressing roller 396 is completed, and the user can accurately adjust the distance according to different bone breaking requirements;

and a second step of: when the adjustment of the osteoclast interval between the first compression roller 361 and the second compression roller 396 is completed, the driving motor 391 is powered on, so that the output end of the driving motor 391 drives and rotates the second rotating shaft 38, when the second rotating shaft 38 rotates, the driving gear 39 fixed with the second rotating shaft 38 can rotate along with the second rotating shaft 38, the third rotating shaft 392 can rotate through the meshing of the driving gear 39 and the linkage gear 393, the first rotating shaft 36 can rotate along with the first rotating shaft through the meshing of the driving gear 39 and the first gear 37, the first compression roller 361 can rotate, the linkage gear 393 is meshed with the second gear 395, the second compression roller 396 can rotate synchronously under the transmission of the fourth rotating shaft 394, the second compression roller 396 and the first compression roller 361 can rotate synchronously in opposite directions through the mutual transmission among the gears, the bone fragments can be collected through the collecting box 4 after the bone fragments are broken between the second compression roller 396 and the first compression roller 361.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The high-efficiency combined type bone crusher is characterized by comprising a machine shell (1), wherein the machine shell (1) is provided with a cavity, and a mounting seat (31) is arranged in the cavity;

the mounting seat (31) is U-shaped, a group of bone breaking mechanisms (3) are arranged on the mounting seat, the bone breaking mechanisms (3) comprise two adjusting sliding grooves (32) which are respectively arranged on two sides of the mounting seat (31), a sliding block (33) is radially arranged in each adjusting sliding groove (32) in a sliding manner, and a first compression roller (361) is arranged between the two sliding blocks (33) in a rotating manner through a matched bearing piece and a rotating shaft;

the bone breaking mechanism (3) further comprises a second compression roller (396) which can rotate in the mounting seat (31), and the first compression roller (361) and the second compression roller (396) are arranged in parallel;

the upper end face of the shell (1) is communicated with a feed hopper (2), and one side of the shell (1) is provided with an opening and is provided with a collecting box (4) in a sliding manner.

2. The efficient composite bone breaker according to claim 1, wherein the bone breaking mechanism (3) further comprises two reciprocating motors (34) fixed on one side of the adjusting chute (32), the two reciprocating motors (34) are fixed on the mounting seat (31) through motor seats and are arranged on the same side, the output ends of the two reciprocating motors (34) are connected with a small threaded screw rod (35), and one ends of the two small threaded screw rods (35) penetrate through the mounting seat (31) to extend into the adjusting chute (32) and are in threaded engagement with the sliding block (33).

3. The efficient composite bone crusher according to claim 2, wherein a first rotating shaft (36) is arranged between two sliding blocks (33), two ends of the first rotating shaft (36) are propped against adjacent sliding blocks (33) and rotate between the two sliding blocks (33) through bearing pieces, the first pressing roller (361) is sleeved on the outer circumferential surface of the first rotating shaft (36), and two ends of the first rotating shaft (36) penetrate through the side of the mounting seat (31) to the outside and are fixedly connected with a first gear (37).

4. A high-efficiency composite type bone breaker according to claim 3, wherein the bone breaking mechanism (3) further comprises a second rotating shaft (38), two ends of the second rotating shaft (38) rotate on the inner wall of the mounting seat (31) through bearing parts, two ends of the second rotating shaft (38) extend to the outside through the side of the mounting seat (31) and are fixedly connected with a driving gear (39), one side of the driving gear (39) is provided with a driving motor (391), the driving motor (391) is fixed on the inner wall of the casing (1) through a motor seat, the output end of the driving motor (391) is connected with one end of the second rotating shaft (38), and the first gear (37) is meshed with the driving gear (39).

5. The efficient composite osteoclast machine according to claim 4, wherein the osteoclast mechanism (3) further comprises a third rotating shaft (392), two ends of the third rotating shaft (392) are rotated on the inner wall of the mounting seat (31) through bearing members, two ends of the third rotating shaft (392) extend to the outside through the mounting seat (31) and are fixedly connected with a linkage gear (393), and the linkage gear (393) is meshed with the driving gear (39).

6. The efficient composite osteoclast of claim 5, wherein the osteoclast mechanism (3) further comprises a fourth shaft (394), two ends of the fourth shaft (394) are rotated on the inner wall of the mounting seat (31) through bearing members, two ends of the fourth shaft (394) penetrate through the mounting seat (31) to the outside and are fixedly connected with a second gear (395), and the second gear (395) is meshed with the linkage gear (393).