CN112120061B - Meat block particle air cooling mechanism and meat block particle air cooling processing technology - Google Patents

Abstract

The invention discloses a meat piece particle air cooling mechanism and a meat piece particle air cooling processing technology. Meat piece particle forced air cooling mechanism includes: a meat block mincing device and a meat particle air cooling device; the meat block mincing device is used for mincing meat blocks into meat particles; the meat grain air cooling device is used for carrying out air-blowing type cooling on the meat grains. The air cooling processing technology for the meat block particles comprises the following steps: step one, mincing the meat blocks into meat particles by the meat block mincing device; and step two, conveying the meat particles through the meat particle air cooling device and simultaneously realizing air-blowing type cooling. According to the meat piece particle air cooling mechanism and the meat piece particle air cooling processing technology, meat pieces with high temperature are quickly and effectively cooled to the indoor environment temperature, so that the production efficiency is improved, and meatballs with high quality are obtained.

Description

Meat block particle air cooling mechanism and meat block particle air cooling processing technology

Technical Field

The invention relates to the technical field of food processing, in particular to a meat piece particle air cooling mechanism and a meat piece particle air cooling processing technology.

Background

The meatballs are delicious food which is well pursued by the great food lovers. The process flow of the meat balls is approximately as follows: taking fresh beef or pork which is just slaughtered, beating the fresh beef or pork to obtain meat pulp, kneading the meat pulp into a dough shape, putting the dough-shaped meat pulp into a boiling soup pot, and boiling the dough-shaped meat pulp in the soup pot for a certain time to obtain the edible meat ball finished product.

However, whether the finished meat ball is tough or not is greatly related to the preparation process, and the excellent degree of the preparation process is related to the quality of the meat ball.

In the process of making the meatballs, fresh beef or pork which is just killed needs to be taken, the temperature of the fresh beef or pork which is just killed is higher than the indoor environment temperature, and the fresh beef or pork is not suitable for being directly beaten, and if meat blocks with higher temperature are directly beaten, the finally obtained meatballs are not chewy and tasty.

Therefore, the meat pieces with higher temperature need to be cooled down to the indoor environment temperature. For large-scale food processing enterprises, how to quickly and effectively reduce meat blocks with higher temperature to indoor environment temperature so as to improve production efficiency and obtain meatballs with superior quality is a technical problem to be overcome.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide a meat piece particle air cooling mechanism and a meat piece particle air cooling processing technology, which can quickly and effectively reduce the temperature of meat pieces with higher temperature to the indoor environment temperature, thereby improving the production efficiency and obtaining meat balls with superior quality.

The purpose of the invention is realized by the following technical scheme:

a meat piece crumb air cooling mechanism comprising: a meat block mincing device and a meat particle air cooling device; the meat block mincing device is used for mincing meat blocks into meat particles; the meat grain air cooling device is used for carrying out air-blowing type cooling on the meat grains.

The meat piece mincing device comprises: a meat block mincing bin, a meat block mincing cutter and a cutter driving part; the meat piece mincing bin is provided with a feeding port and a discharging port, the meat piece mincing cutter is arranged in the bin body of the meat piece mincing bin and is positioned between the feeding port and the discharging port, and the cutter driving part is in driving connection with the meat piece mincing cutter.

The meat grain air cooling device comprises: the meat particle conveying device comprises a meat particle conveying base, a meat particle conveying belt, a belt driving part and an air supply cooling machine; meat grain transmission belt connects end to end and encircles and locates on the meat grain transmission base, belt drive portion with meat grain transmission belt drive is connected, the air supply cooler is located meat grain transmission belt's top.

The meat particle air cooling device also comprises a meat particle discharging scraper bucket, and the meat particle discharging scraper bucket is arranged on the meat particle transmission base and is positioned at one end of the meat particle transmission belt; meat grain unloading scraper bucket has a unloading inclined plane, the both ends on unloading inclined plane form respectively and scrape material end and discharge end, scrape the material end press hold in on the area body of meat grain transmission belt.

In one embodiment, the meat granule blanking scraper bucket is also provided with anti-overflow side baffles, and the anti-overflow side baffles are arranged on two sides of the blanking inclined plane.

In one embodiment, the meat particle discharging scraper is rotatably arranged on the meat particle transmission base.

In one embodiment, the blast cooler is an electric fan structure.

In one embodiment, the tool driving part is a motor driving structure.

In one embodiment, a plurality of air holes are formed in the belt body of the meat particle conveying belt, and the air holes are distributed in a rectangular array along the conveying direction of the meat particle conveying belt.

In one embodiment, the meat mincing tool comprises a driving mincing rotating shaft and a driven mincing rotating shaft, and the tool driving part is in driving connection with the driving mincing rotating shaft; a driving gear is arranged at the end part of the driving rubbing rotating shaft, a driven gear is arranged at the end part of the driven rubbing rotating shaft, and the driving gear is meshed with the driven gear;

a plurality of active mincing knives are arranged on the shaft body of the active mincing rotating shaft and are sequentially arranged at intervals along the axial direction of the active mincing rotating shaft; a plurality of driven mincing knives are arranged on the shaft body of the driven mincing rotating shaft and are sequentially arranged at intervals along the axial direction of the driven mincing rotating shaft; the plurality of driving mincing knives and the plurality of driven mincing knives are arranged in a staggered way.

A meat piece particle air-cooling processing technology comprises the following steps:

step one, mincing the meat blocks into meat particles by the meat block mincing device.

And step two, conveying the meat particles through the meat particle air cooling device and simultaneously realizing air-blowing type cooling.

According to the meat piece particle air cooling mechanism and the meat piece particle air cooling processing technology, meat pieces with high temperature are quickly and effectively cooled to the indoor environment temperature, so that the production efficiency is improved, and meatballs with high quality are obtained.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic structural view of a meat piece crumb air-cooling mechanism according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of the meat mincing device shown in FIG. 1;

FIG. 3 is a schematic view of the meat trim mincing tool of the meat trim mincing device shown in FIG. 2;

FIG. 4 is a schematic view of the meat particle air-cooling apparatus shown in FIG. 1;

FIG. 5 is a schematic view of the meat particle discharging scraper shown in FIG. 4;

FIG. 6 is a schematic view showing the structure of the meat granule hammering device shown in FIG. 1;

fig. 7 is an exploded view of the meat granule hammering device shown in fig. 6.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

It is first noted that the master worker uses a knife to cut meat pieces from freshly slaughtered cattle or pigs, which are usually larger pieces, on average around 250g per piece. The meat piece at this moment is in the state of high temperature, because the meat piece is great and thick, the heat is difficult to in time effectually distribute away, if let rely on the heat constantly to pile up, the quality of meat piece can descend to influence the off-the-shelf quality of meat ball. More importantly, for a large-scale food processing enterprise, it is also a technical problem to be solved how to quickly and effectively reduce the temperature of meat blocks with higher temperature to the indoor environment temperature, thereby improving the production efficiency and obtaining meatballs with superior quality.

As shown in fig. 1, in order to solve the above technical problem, the present invention discloses a meat piece granule air-cooling mechanism 10, which comprises: a meat block mincing device 100 and a meat particle air cooling device 200. The meat mincing device 100 is used for mincing meat into meat particles, and the meat particle air cooling device 200 is used for carrying out air-blowing type cooling on the meat particles. The meat piece particle air cooling mechanism 10 of the invention firstly adopts the meat piece mincing device 100 to mince the meat pieces into meat particles, and large meat pieces are minced into fine meat particles (each particle of meat particle is about 10 g), thus being more beneficial to quickly radiating heat; secondly, the meat grain air cooling device 200 is adopted to carry out air-blowing type cooling on the meat grains, so that heat can be further quickly and effectively dissipated. In particular, the meat particle air-cooling device 200 cools the meat particles by blowing air, but the meat particles are not cooled by water, and once the meat particles are contacted with water, the quality of the meat balls is seriously affected.

Specifically, as shown in fig. 2 and 3, the meat mincing device 100 includes: a meat block mincing bin 110, a meat block mincing cutter 120 and a cutter driving part 130. The meat mincing bin 110 has a feeding port 111 and a discharging port 112, the meat mincing tool 120 is installed in the bin body of the meat mincing bin 110 and is positioned between the feeding port 111 and the discharging port 112, and the tool driving part 130 is in driving connection with the meat mincing tool 120. In the present embodiment, the tool driving part 130 is a motor driving structure.

Specifically, as shown in fig. 4, the meat particle air-cooling device 200 includes: meat particle transmission base 210, meat particle transmission belt 220, belt driving part 230, and blast cooling machine 240. Meat grain conveying belt 220 is arranged on meat grain conveying base 210 in a head-to-tail connection surrounding mode, belt driving portion 230 is connected with meat grain conveying belt 220 in a driving mode, and air supply cooling machine 240 is arranged above meat grain conveying belt 220. In this embodiment, the belt driving unit 230 is a motor driving structure, and the blast cooling unit 240 is an electric fan structure.

As shown in fig. 4 and 5, the meat-grain air-cooling device 200 further includes a meat-grain discharging scraper 250, and the meat-grain discharging scraper 250 is mounted on the meat-grain conveying base 210 and located at one end of the meat-grain conveying belt 220. The meat particle discharging scraper 250 has a discharging inclined plane 251, two ends of the discharging inclined plane 251 respectively form a scraping end 252 and a discharging end 253, and the scraping end 252 is pressed on the belt body of the meat particle conveying belt 220. Further, the meat particle discharging scraper 250 further has an anti-overflow side guard 254, and the anti-overflow side guard 254 is provided on both sides of the discharging inclined surface 251.

The operation principle of the meat-piece-meat-piece air-cooling mechanism 10 having the above-described structure will be described below:

the large meat blocks are put into the bin body of the meat block mincing bin 110 from the feeding port 111, the large meat blocks are minced into fine meat particles by the meat block mincing cutter 120 in the bin body of the meat block mincing bin 110, and the fine meat particles come out from the discharging port 112.

The meat particles discharged from the discharge port 112 continuously fall onto the belt of the meat particle conveying belt 220 of the meat particle air-cooling device 200, and the meat particle conveying belt 220 continuously drives the meat particles thereon to be conveyed to the next station, for example, the next station may be a meat particle beating device, under the driving of the belt driving part 230.

In the process of conveying the meat particles on the meat particle conveying belt 220, because the air supply cooler 240 is arranged above the meat particle conveying belt 220, cold air blown out by the air supply cooler 240 directly reaches the meat particle conveying belt 220, and heat carried by the meat particles on the meat particle conveying belt 220 is taken away, so that the meat particles are cooled.

When the meat particles on the meat particle conveying belt 220 are cooled to the indoor ambient temperature (for example, 22 ℃), the meat particle conveying belt 220 correspondingly conveys the meat particles from one position to another position, and at this time, the meat particles are unloaded from the meat particle conveying belt 220 and enter a meat particle beating device, and the meat particles are beaten by the meat particle beating device, so that the meat particles become meat pulp.

It is known from the general knowledge that meat particles have certain viscosity, and inner particles with viscosity are very easy to stick on the meat particle transmission belt 220 and do not fall off, in order to separate the meat particles from the meat particle transmission belt 220 smoothly, especially, the meat particle transmission base 210 is provided with the meat particle discharging scraper 250, because the material scraping end 252 of the meat particle discharging scraper 250 is pressed on the belt body of the meat particle transmission belt 220, in the process of transmitting the meat particle transmission belt 220, the material scraping end 252 can easily scrape the meat particles on the meat particle transmission belt 220 to the discharging inclined surface 251, and the meat particles come out from the material discharging end 253 and reach the next station.

Wherein, meat grain unloading scraper 250 rotationally establishes on meat grain transmission base 210, like this, can carry out the adaptability to the inclination of unloading inclined plane 251 on meat grain unloading scraper 250 and adjust for the meat grain can accurately reach next station.

Wherein, a plurality of air holes (not shown) are disposed on the belt body of the meat particle transmission belt 220, and the plurality of air holes are distributed in a rectangular array along the transmission direction of the meat particle transmission belt 220. A plurality of air holes are formed in the belt body of the meat particle transmission belt 220, so that heat carried by meat particles can be dissipated more quickly and effectively.

In the present invention, the meat mincing device 100 is mainly used for mincing large meat pieces into fine meat particles, and it should be noted that the fine meat particles are not equivalent to meat pulp, the meat particles are of a fine block-shaped structure, and the meat particles cannot be kneaded into lumps. The method is mainly based on the consideration of a manufacturing process, firstly, large meat blocks are ground into fine meat particles, then the fine meat particles are beaten to obtain meat pulp, then the meat pulp is kneaded into a dough and put into a soup pot, and meat balls with superior quality can be obtained only through a sample process.

The present invention specifically modifies the structure of the meat mincing tool 120 in order to mince large chunks of meat into smaller meat particles. As shown in fig. 3, for example, the meat mincing tool 120 includes a driving mincing shaft 121 and a driven mincing shaft 122, and the tool driving portion 130 is in driving connection with the driving mincing shaft 121. The end of the driving grinding rotating shaft 121 is provided with a driving gear 123, the end of the driven grinding rotating shaft 122 is provided with a driven gear 124, and the driving gear 123 and the driven gear 124 are engaged with each other.

As shown in fig. 3, a plurality of active mincing knives 125 are installed on the shaft body of the active mincing rotating shaft 121, and the plurality of active mincing knives 125 are sequentially arranged at intervals along the axial direction of the active mincing rotating shaft 121; a plurality of driven mincing knives 126 are arranged on the shaft body of the driven mincing rotating shaft 122, and the plurality of driven mincing knives 126 are sequentially arranged at intervals along the axial direction of the driven mincing rotating shaft 122; the plurality of driving mincing knives 125 and the plurality of driven mincing knives 126 are staggered with each other.

The operation principle of the meat mincing tool 120 with the above structure is explained as follows: the cutter driving part 130 drives the driving grinding rotating shaft 121 to rotate, the driving gear 123 is meshed with the driven gear 124, so that the driven grinding rotating shaft 122 also rotates, a plurality of driving grinding knives 125 are installed on the shaft body of the driving grinding rotating shaft 121, a plurality of driven grinding knives 126 are installed on the shaft body of the driven grinding rotating shaft 122, and the plurality of driving grinding knives 125 and the plurality of driven grinding knives 126 are arranged in a staggered mode, so that the plurality of driving grinding knives 125 and the plurality of driven grinding knives 126 which are staggered with each other can grind large meat blocks into small meat particles.

The invention also discloses a meat piece particle air-cooling processing technology, which comprises the following steps:

step one, mincing the meat blocks into meat particles by the meat block mincing device.

And step two, conveying the meat particles through the meat particle air cooling device and simultaneously realizing air-blowing type cooling.

And step three, beating the meat particles by a meat particle beating device to obtain meat pulp.

As can be seen from the above-mentioned processing, the meat-piece-crushing air-cooling mechanism 10 of the present invention may further include a meat-crushing device 300. Next, a specific structure of the meat-particle beating device 300 will be explained:

as shown in fig. 6, the meat particle hammering apparatus 300 includes: a hammering base 310, a hammering driving part 320, a hammering vibration generating part 330, and a hammering hammer 340.

The hammering driving part 320 is installed on the hammering base 310, the hammering hammer 340 is slidably disposed on the hammering base 310 along the vertical direction, and the hammering driving part 320 drives the hammering hammer 340 to vibrate and lift along the vertical direction through the hammering vibration generating part 330.

As shown in fig. 7, the hammering vibration generating portion 330 includes: an elastic carrying rod 331, a left-side linkage rod 332, a right-side linkage rod 333, and a clamping guide frame 334. The clamping guide frame 334 has a clamping cavity 335, the clamping guide frame 334 has a left guide slot 336 and a right guide slot 337, and the left guide slot 336 and the right guide slot 337 are respectively located at two sides of the clamping cavity 335. The knocking hammer 340 is accommodated in the clamping and accommodating cavity 335 in a lifting and sliding manner. One end of the left-side linkage rod 332 and one end of the right-side linkage rod 333 are respectively hinged to two ends of the elastic bearing rod 331, the other end of the left-side linkage rod 332 penetrates through the left-side guide groove 336 and is hinged to the knocking hammer 340, and the other end of the right-side linkage rod 333 penetrates through the right-side guide groove 337 and is hinged to the knocking hammer 340.

As shown in fig. 7, the power output end of the hammering driving part 320 is connected to the middle of the elastic supporting rod 331.

As shown in fig. 7, the cavity wall of the clamping accommodating cavity 335 is provided with a plurality of vibration generating elastic members 338, the plurality of vibration generating elastic members 338 are arranged in a rectangular array along the vertical direction, the knocking hammer 340 is provided with a plurality of vibration generating convex blocks 341, the plurality of vibration generating convex blocks 341 are arranged in a rectangular array along the vertical direction, and the plurality of vibration generating convex blocks 341 and the plurality of vibration generating elastic members 338 are abutted or separated.

Here, it should be particularly noted that the hammering driving portion 320 is connected to the hammering hammer 340 through the hammering vibration generating portion 330, so that the hammering driving portion 320 can drive the hammering hammer 340 to perform a vibration type lifting motion along the vertical direction through the hammering vibration generating portion 330, and it should be particularly noted that the hammering hammer 340 performs the vibration type lifting motion along the vertical direction instead of performing the ordinary lifting motion, and such lifting motion is accompanied by vibration, which is advantageous in that, in the process of each descending of the hammering hammer 340, due to the vibration, the hammering hammer 340 continuously beats the meat particles for many times, and the meat particles are beaten continuously and repeatedly in the process of each descending of the hammering hammer 340, and can be beaten into pulp rapidly, thereby greatly improving the production efficiency.

The operation principle of the meat-particle beating device 300 having the above-described structure will be explained as follows:

the meat particle air-cooling device 200 transfers the air-cooled meat particles to a receiving vessel 400 (shown in fig. 1) located at the meat particle beating device 300.

The hammering driving part 320 directly drives the elastic carrying rod 331 to perform a lifting motion, and the elastic carrying rod 331 drives the hammering hammer 340 to perform a lifting motion through the left-side linkage rod 332 and the right-side linkage rod 333.

The knocking hammer 340 is accommodated in the clamping accommodating cavity 335 in a lifting and sliding manner, and the cavity wall of the clamping accommodating cavity 335 is provided with a plurality of vibration generation elastic parts 338 corresponding to the vibration generation elastic parts 338, and the knocking hammer 340 is provided with a plurality of vibration generation convex blocks 341, so that the vibration generation convex blocks 341 can be abutted against or separated from the vibration generation elastic parts 338 in the lifting and lowering process of the knocking hammer 340, the elastic potential energy accumulated by the elastic bearing rods 331 can be instantaneously exploded at the moment of continuous abutting or separation, and the instantaneously exploded elastic potential energy can act on the knocking hammer 340.

It is further noted that the meat mincing device 100 described above, which minces meat pieces into meat particles, can have the following two advantages: on one hand, the meat is minced into meat particles, and the meat particle air cooling device 200 can be effectively matched, so that the meat particle air cooling device 200 can rapidly cool fine meat particles; on the other hand, the meat pieces are minced into meat particles, which can be effectively matched with the meat particle beating device 300, so that the meat particle beating device 300 can quickly beat the fine meat particles into meat pulp.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (8)

1. A meat piece crumb air cooling mechanism comprising: a meat block mincing device and a meat particle air cooling device; the meat block mincing device is used for mincing meat blocks into meat particles; the meat particle air cooling device is used for carrying out air-blowing type cooling on the meat particles;

the meat piece mincing device comprises: a meat block mincing bin, a meat block mincing cutter and a cutter driving part; the meat block mincing bin is provided with a feeding port and a discharging port, the meat block mincing tool is arranged in a bin body of the meat block mincing bin and is positioned between the feeding port and the discharging port, and the tool driving part is in driving connection with the meat block mincing tool;

the meat grain air cooling device comprises: the meat particle conveying device comprises a meat particle conveying base, a meat particle conveying belt, a belt driving part and an air supply cooling machine; the meat particle transmission belt is arranged on the meat particle transmission base in an end-to-end manner in a surrounding manner, the belt driving part is in driving connection with the meat particle transmission belt, and the air supply cooler is arranged above the meat particle transmission belt;

the meat particle air cooling device also comprises a meat particle discharging scraper bucket, and the meat particle discharging scraper bucket is arranged on the meat particle transmission base and is positioned at one end of the meat particle transmission belt; the meat particle discharging scraper bucket is provided with a discharging inclined plane, a scraping end and a discharging end are respectively formed at two ends of the discharging inclined plane, and the scraping end is pressed on a belt body of the meat particle conveying belt;

its characterized in that, meat piece particle forced air cooling mechanism still includes the meat grain and beats the device, the meat grain is beaten the device and is included: a beating base, a beating driving part, a beating vibration generating part and a beating hammer;

the hammering driving part is arranged on the hammering base, the hammering hammer is arranged on the hammering base in a sliding mode along the vertical direction, and the hammering driving part drives the hammering hammer to do vibrating type lifting motion along the vertical direction through the hammering vibration generating part;

the hammering vibration generating portion includes: the elastic bearing rod, the left side linkage rod, the right side linkage rod and the clamping guide frame; the clamping guide frame is provided with a clamping accommodating cavity, a left side guide groove and a right side guide groove are formed in the clamping guide frame, and the left side guide groove and the right side guide groove are respectively positioned on two sides of the clamping accommodating cavity; the knocking hammer is accommodated in the clamping accommodating cavity in a lifting and sliding manner; one end of the left-side linkage rod and one end of the right-side linkage rod are respectively hinged with two ends of the elastic bearing rod, the other end of the left-side linkage rod penetrates through the left-side guide groove and is hinged with the knocking hammer, and the other end of the right-side linkage rod penetrates through the right-side guide groove and is hinged with the knocking hammer;

the power output end of the hammering driving part is connected with the middle part of the elastic bearing rod;

the cavity wall of chamber is acceptd in the centre gripping is equipped with a plurality of vibrations and takes place the elastic component, and is a plurality of vibrations take place the elastic component and be rectangular array along vertical direction and arrange, strike and be equipped with a plurality of vibrations on the hammer and take place the lug, it is a plurality of vibrations take place the lug and a plurality of vibrations take place the elastic component and support and hold or separate.

2. The meat chunk and pellet air-cooling mechanism of claim 1, wherein the meat pellet discharging scraper bucket further comprises anti-overflow side baffles, and the anti-overflow side baffles are arranged on two sides of the discharging inclined plane.

3. The meat chunk and pellet air-cooling mechanism of claim 2 wherein the pellet feed scraper is rotatably disposed on the pellet transport base.

4. The meat chunk and pellet air-cooling mechanism of claim 1 wherein the air-supply cooler is an electric fan configuration.

5. The meat chunk and pellet air-cooling mechanism of claim 1, wherein the cutter driving part is a motor driving structure.

6. The meat chunk and pellet air-cooling mechanism of claim 1, wherein a plurality of air holes are formed on the belt body of the meat pellet conveying belt, and the plurality of air holes are distributed in a rectangular array along the conveying direction of the meat pellet conveying belt.

7. The meat chunk and particle air-cooling mechanism of claim 1, wherein the meat chunk mincing tool comprises a driving mincing rotating shaft and a driven mincing rotating shaft, and the tool driving part is in driving connection with the driving mincing rotating shaft; a driving gear is arranged at the end part of the driving rubbing rotating shaft, a driven gear is arranged at the end part of the driven rubbing rotating shaft, and the driving gear is meshed with the driven gear;

a plurality of active mincing knives are arranged on the shaft body of the active mincing rotating shaft and are sequentially arranged at intervals along the axial direction of the active mincing rotating shaft; a plurality of driven mincing knives are arranged on the shaft body of the driven mincing rotating shaft and are sequentially arranged at intervals along the axial direction of the driven mincing rotating shaft; the plurality of driving mincing knives and the plurality of driven mincing knives are arranged in a staggered way.

8. A meat piece particle air-cooling processing technology is characterized by comprising the following steps:

firstly, mincing meat blocks into meat particles by the meat block mincing device of any one of claims 1 to 7;

step two, conveying the meat particles by the meat particle air cooling device of any one of claims 1 to 7 and simultaneously realizing air-blowing type cooling.

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