CN118681638A - Grinding device for food processing - Google Patents

Abstract

The invention relates to the technical field of grinding devices, in particular to a grinding device for food processing. The grinding machine comprises a supporting frame, wherein a fixing shell is fixedly connected to the upper side of the supporting frame, a grinding disc is rotationally connected to the fixing shell, a material distributing frame is fixedly connected to the fixing shell, a filtering frame is rotationally connected to the upper side of the material distributing frame, a material distributing frame fixedly connected to the lower side of the material distributing frame is divided into three parts by the material distributing frame, the area of the material distributing frame in the fixing shell is divided into three parts by the material distributing frame, and arc-shaped fixing blocks in contact with the inner wall of the fixing shell are arranged in each part. According to the invention, materials with different sizes are filtered by utilizing different apertures of the filtering holes on the filtering frame, and the materials with different sizes are conveyed between the corresponding arc-shaped fixed blocks and the grinding disc, so that the raw materials with fixed sizes are precisely ground, and the problem that when the materials are ground, the whole grinding time is prolonged due to long grinding time required by the large materials, and the grinding efficiency is influenced is avoided.

Description

Grinding device for food processing

Technical Field

The invention belongs to the technical field of grinding devices and discloses a grinding device for food processing.

Background Art

In the process of producing flour, a grinder is needed to grind wheat into flour. However, in the process of grinding wheat, when the wheat grains are poured into the grinder and the millstone rotates to grind the wheat grains into flour of uniform size and coarseness, the wheat grains are poured into the grinder together, and the sizes of the wheat grains entering the grinder are not the same. Therefore, when the grinder grinds the wheat grains, if the large wheat grains and the small wheat grains are ground at the same time, then when the small wheat grains are ground to the standard, the large wheat grains have not been ground to the standard, which will cause the qualified finished products to be over-grinded. At the same time, since the grinding time required for large wheat grains is longer than that for small wheat grains, the large wheat grains occupy the millstone for a longer time, and since the large wheat grains have been occupying the millstone, the overall grinding time increases, affecting the grinding efficiency of the grinder.

Summary of the invention

In order to overcome the shortcomings mentioned in the above background technology, the present invention provides a grinding device for food processing.

The technical solution is as follows: a grinding device for food processing, comprises a support frame, a fixed shell is fixedly connected to the upper side of the support frame, the fixed shell is provided with a feed inlet and a discharge port, the feed inlet is located on the upper side of the discharge port, the feed inlet of the fixed shell is fixedly connected and connected with a feed hopper, a grinding disc is rotatably connected in the fixed shell, the support frame is installed with a first motor, the output shaft of the first motor is fixedly connected to the grinding disc, a dividing frame located between the grinding disc and the feed inlet is fixedly connected in the fixed shell, a filter frame is rotatably connected to the upper side of the dividing frame, the filter frame is connected with the feed hopper, a dividing frame fixedly connected to the fixed shell with respect to the lower side of the dividing frame, the dividing frame divides the area in the fixed shell where it is located into three parts, and each part is provided with an arc-shaped fixed block in contact with the inner wall of the fixed shell, the three arc-shaped fixed blocks are all cooperated with the grinding disc for grinding raw materials, and an anti-blocking cleaning mechanism is provided on the fixed shell to prevent the filter frame from being blocked.

Preferably, the aperture of the filter holes on the side of the filter frame close to the feed hopper is smaller than the aperture of the filter holes away from the side, and two discharge ports are provided on the material distribution frame, and the discharge port close to the feed hopper is located at the lower side of the filter holes with smaller apertures on the filter frame, and the discharge port away from the feed hopper is located at the lower side of the filter holes with larger apertures on the filter frame.

Preferably, the diameters of the inner arcs of the three arc-shaped fixed blocks are all inconsistent, the arc-shaped fixed block with the smallest diameter among the three arc-shaped fixed blocks is connected to the discharge port on the material distribution frame close to the feed hopper, the arc-shaped fixed block with a middle diameter among the three arc-shaped fixed blocks is connected to the discharge port on the material distribution frame away from the feed hopper, and the arc-shaped fixed block with the largest diameter among the three arc-shaped fixed blocks is connected to the side of the filter frame away from the feed hopper.

Preferably, the grinding disc is fixedly connected with a discharge plate which is flush with the discharge port of the fixed shell, and the discharge plate is used for discharging the ground raw materials.

Preferably, the anti-blocking cleaning mechanism includes a second motor, which is installed in the fixed shell, and the output shaft of the second motor is fixedly connected to a fixed shaft passing through the fixed shell, the fixed shaft is rotatably connected to the fixed shell, and a first rotating wheel is fixedly connected to one side of the fixed shaft located in the fixed shell, and the filter frame is fixedly connected to a second rotating wheel with friction transmission with the first rotating wheel, the fixed shell is rotatably connected to a spiral blade located in the filter frame, and the spiral blade and the fixed shaft are driven by a pulley and a belt, and symmetrically distributed fixed disks are fixedly connected to the upper side of the fixed shell, and the symmetrically distributed fixed disks are all rotatably connected to the fixed shaft, and the fixed disk is slidably connected to a clearing block that slidably cooperates with the filter frame, and an anti-blocking cleaning component for moving the symmetrically distributed clearing blocks is provided on the fixed shaft.

Preferably, the anti-blocking cleaning assembly includes symmetrically distributed cams, the symmetrically distributed cams are all fixed to the fixed shaft, the symmetrically distributed cams are respectively rotatably connected to adjacent fixed disks, the clearing block is fixed to a pressure block located in the adjacent fixed disk, the pressure block is squeezed and matched with the adjacent cam, and a spring is connected between the pressure block and the adjacent fixed disk.

Preferably, a cooling mechanism is also included, which is arranged on the support frame, and is used to reduce the temperature of the grinding location. The cooling mechanism includes a cooling box, which is installed on the upper side of the support frame, and a reflux box is installed on the upper side of the support frame. The reflux box and the cooling box are connected through a delivery pump, and three groups of evenly distributed cooling pipes are fixedly connected to the outer side of the fixed shell, and a liquid inlet pipe is connected to the cooling box between each group of evenly distributed cooling pipes, and a liquid return pipe is connected to the reflux box between each group of evenly distributed cooling pipes, and a cooling and cooling adjustment component is provided on the support frame for adjusting the amount of coolant delivered to each group of evenly distributed cooling pipes.

Preferably, the cooling and temperature adjustment component includes three first pneumatic telescopic parts, the three first pneumatic telescopic parts are all fixedly connected to the upper side of the support frame, three temperature-sensing blocks are fixedly connected to the upper side of the grinding disc, the telescopic end of the first pneumatic telescopic part is sealingly and slidingly matched with the adjacent temperature-sensing blocks, three second pneumatic telescopic parts are fixedly connected to the upper side of the support frame, a connecting pipe is connected between the fixed part of the second pneumatic telescopic part and the fixed part of the adjacent first pneumatic telescopic part, the liquid inlet pipe is fixedly connected and connected to a square shell, and the telescopic end of the second pneumatic telescopic part is fixedly connected to a sealing block sealingly and slidingly connected to the adjacent square shell.

Preferably, the regions where the three groups of evenly distributed cooling pipes and the three temperature sensing blocks are located correspond to the regions where the adjacent arc-shaped fixing blocks are located.

Preferably, a particle size adjustment mechanism is further included, which is arranged on the fixed shell, and is used to adjust the size of the ground material. The particle size adjustment mechanism includes a connecting rod, and the connecting rod is fixedly connected to adjacent arc-shaped fixed blocks, and adjacent arc-shaped fixed blocks are fixedly connected to each other. The fixed shell and the material distribution rack are both slidably connected to the arc-shaped fixed blocks, and the connecting rod is threadedly connected to a threaded rod rotatably connected to the fixed shell.

The beneficial effects of the present invention are as follows: the present invention utilizes the different apertures of the filter holes on the filter frame to filter materials of different sizes, and conveys the materials of different sizes to between the corresponding arc-shaped fixed blocks and the grinding disc, thereby accurately grinding raw materials of fixed sizes, avoiding the situation in which the overall grinding time increases due to the long grinding time required for large materials when grinding materials, thereby affecting the grinding efficiency.

The present invention drives the filter frame to rotate by the output shaft of the second motor to drive the second rotating wheel, so that the material blocked in the filter holes on the filter frame is scraped off by the clearing block, thereby avoiding the filter holes on the filter frame being blocked, which affects the efficiency of the filter frame in screening materials.

The present invention drives the clearing block to move downward through a fixed shaft to squeeze the clogged material in the filter holes on the filter frame, and dredge the filter holes on the filter frame. In this way, the filter holes on the filter frame are protected to prevent the clogged material from squeezing the filter holes and causing damage to the filter holes when the clearing block scrapes off the clogged material in the filter holes.

The present invention detects the temperature of the materials at the three arc-shaped fixed blocks through the temperature-sensitive gas in the three temperature-sensitive blocks, and drives the telescopic end of the second pneumatic telescopic part to drive the adjacent blocking blocks to move upward, thereby increasing the flow area of the coolant in the square shell, thereby accelerating the circulation efficiency of the coolant and accurately cooling the materials at different arc-shaped fixed blocks.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of a three-dimensional structure of the present invention;

FIG2 is a schematic diagram of the three-dimensional structure of the cooling pipe, the second pneumatic telescopic member and the threaded rod of the present invention;

FIG3 is a schematic diagram of the three-dimensional structure of the feed hopper, the grinding disc and the first motor of the present invention;

FIG4 is a schematic diagram of the three-dimensional structure of the material distribution frame, the filter frame and the material distribution rack of the present invention;

FIG5 is an exploded view of the three-dimensional structure of the grinding disc, the material distribution frame and the filter frame of the present invention;

FIG6 is a schematic diagram of the three-dimensional structure of the first impeller, the second impeller and the spiral blades of the present invention;

FIG7 is a schematic diagram of the three-dimensional structure of the cam, the pressure block and the spring of the present invention;

FIG8 is a schematic diagram of the three-dimensional structure of the cooling box, the second pneumatic telescopic member and the connecting rod of the present invention;

FIG9 is a schematic diagram of the three-dimensional structure of the cooling pipe, the liquid inlet pipe and the liquid return pipe of the present invention;

FIG10 is a schematic diagram of the three-dimensional structure of the first pneumatic telescopic member, the temperature sensing block and the connecting pipe of the present invention;

FIG11 is a schematic diagram of the three-dimensional structure of the connecting pipe, the square shell and the blocking block of the present invention;

FIG. 12 is a schematic diagram of the three-dimensional structure of the arc-shaped fixing block, the connecting rod and the threaded rod of the present invention.

Explanation of the accompanying drawings: 1-support frame, 11-fixed shell, 12-feed hopper, 13-grinding disc, 14-first motor, 15-distributing frame, 16-filter frame, 17-distributing frame, 18-arc-shaped fixed block, 19-discharge plate, 2-second motor, 21-fixed shaft, 22-first rotor, 23-second rotor, 24-spiral blade, 25-fixed disk, 26-clearing block, 3-cam, 31-pressure block, 32-spring, 4-cooling box, 41-reflux box, 42-cooling pipe, 43-liquid inlet pipe, 44-liquid return pipe, 5-first pneumatic telescopic member, 51-temperature sensing block, 52-second pneumatic telescopic member, 53-connecting pipe, 54-square shell, 55-blocking block, 6-connecting rod, 61-threaded rod.

DETAILED DESCRIPTION

The present invention will be further described below in conjunction with the accompanying drawings and embodiments.

Embodiment 1: A grinding device for food processing, as shown in FIGS. 1 to 5, comprises a support frame 1, on which a control terminal (not shown in the figure) is arranged, a fixed shell 11 is fixedly connected to the left portion of the upper side of the support frame 1, a feed port is arranged at the upper portion of the left side of the fixed shell 11, a discharge port is arranged at the lower portion of the left side of the fixed shell 11, a feed hopper 12 is fixedly connected and communicated with the feed port of the fixed shell 11, a grinding disc 13 is rotatably connected in the fixed shell 11, a first motor 14 electrically connected to the control terminal is installed at the left portion of the lower side of the support frame 1, and the first motor 14 is electrically connected to the control terminal. The output shaft is fixedly connected to the grinding disc 13, and a distribution frame 15 located between the grinding disc 13 and the feed port is fixedly connected in the fixed shell 11. The left and rear sides of the distribution frame 15 are provided with discharge ports. The upper side of the distribution frame 15 is rotatably connected to a filter frame 16. The aperture of the left filter hole on the filter frame 16 is smaller than the aperture of the right filter hole. The left discharge port on the distribution frame 15 is located at the lower side of the left filter hole on the filter frame 16. The rear discharge port on the distribution frame 15 is located at the lower side of the right filter hole on the filter frame 16. The filter frame 16 is connected to the feed hopper 12. The lower side of the distribution frame 15 is fixedly connected to the There is a material distribution rack 17 fixedly connected to the fixed shell 11, and the material distribution rack 17 divides the area in which it is located in the fixed shell 11 into three parts, and each part is provided with an arc-shaped fixed block 18 in contact with the inner wall of the fixed shell 11, and the inner diameter of the rear arc-shaped fixed block 18 is located between the left front side and the right front side, and the distance between the lower side of the three arc-shaped fixed blocks 18 and the outer side of the grinding disc 13 is consistent, and the area where the left front arc-shaped fixed block 18 is located on the material distribution rack 17 is connected to the left discharge port on the material distribution frame 15, and the area where the rear arc-shaped fixed block 18 is located on the material distribution rack 17 is connected to the material distribution frame 15. The discharge port on the rear side of the material frame 15 is connected, and the area where the right front arc-shaped fixed block 18 is located on the distribution frame 17 is connected to the right side of the filter frame 16. The three arc-shaped fixed blocks 18 are all used in conjunction with the grinding disc 13 to grind the raw materials. The lower side of the grinding disc 13 is flush with the lower side of the discharge port of the fixed shell 11. The grinding disc 13 is fixedly connected with a discharge plate 19, and the material plate 19 is flush with the discharge port on the fixed shell 11, thereby pushing the ground raw materials to be discharged through the discharge port on the fixed shell 11. The fixed shell 11 is provided with an anti-blocking cleaning mechanism for preventing the filter frame 16 from being blocked.

As shown in Figures 6 and 7, the anti-blocking cleaning mechanism includes a second motor 2, which is installed on the upper part of the right side of the fixed shell 11. The output shaft of the second motor 2 is fixedly connected to a fixed shaft 21, which passes through the fixed shell 11 and is rotatably connected thereto. A first rotating wheel 22 is fixedly connected to the left side of the fixed shaft 21, and a second rotating wheel 23 that is frictionally driven with the first rotating wheel 22 is fixedly connected to the right side of the filter frame 16. The fixed shell 11 is rotatably connected to a spiral leaf 24 located in the filter frame 16. The outer diameter of the spiral leaf 24 is consistent with the inner diameter of the filter frame 16, so that the wheat grains pass evenly and at a uniform speed. The spiral leaf 24 is connected to the fixed shaft 21 is driven by a pulley and a belt, and two fixed disks 25 symmetrically distributed on the upper side of the fixed shell 11 are fixedly connected to the upper side, and clearing blocks 26 are slidably connected to the lower sides of the two fixed disks 25. A plurality of isosceles trapezoidal blocks are arranged on the lower side of the clearing blocks 26, and the waists of the isosceles trapezoidal blocks are respectively located on the front and rear sides, and the cross-sectional area of the filter holes on the filter frame 16 is larger than the cross-sectional area of the lower side of the adjacent isosceles trapezoidal blocks, but smaller than the cross-sectional area of the upper side of the adjacent isosceles trapezoidal blocks. The isosceles trapezoidal blocks are used to clean the blockages in the filter holes, and an anti-blocking cleaning component for moving the symmetrically distributed clearing blocks 26 is arranged on the fixed shaft 21.

As shown in Figure 7, the anti-blocking cleaning component includes two cams 3 symmetrically distributed on the left and right, and the two cams 3 symmetrically distributed on the left and right are fixed to the left side of the fixed shaft 21. The two cams 3 symmetrically distributed on the left and right are respectively rotatably connected to the adjacent fixed disks 25, and the fixed disks 25 are rotatably connected to the fixed shaft 21. The clearing block 26 is fixedly connected to a pressure block 31 located in the adjacent fixed disk 25. The upper end of the pressure block 31 is set to an arc shape. When the arc at the upper end of the pressure block 31 is squeezed by the protrusion of the adjacent cam 3, the pressure block 31 moves downward, and a spring 32 is connected between the pressure block 31 and the adjacent fixed disk 25.

When the grinder grinds wheat grains, due to the different sizes of wheat grains, large wheat grains and small wheat grains will be ground at the same time. When the small wheat grains are ground to the standard, the large wheat grains have not been ground to the standard. This may not only cause the qualified finished products to be over-grinded, but also increase the overall grinding time. Therefore, when the device needs to grind raw materials, the staff starts the first motor 14 through the control terminal, and the output shaft of the first motor 14 drives the grinding disc 13 to rotate. The staff puts the raw materials into the feed hopper 12, and then the wheat grains in the feed hopper 12 enter the filter frame 16. After entering the filter frame 16, the raw materials are first filtered by the filter holes on the left side thereof. At this time, a batch of raw materials with the smallest diameter in the filter frame 16 moves downward through the filter holes on the left side thereof, and passes through the discharge port on the left side of the dividing frame 15 and enters between the arc-shaped fixed block 18 on the left front side and the grinding disc 13. At this time, the rotating grinding disc 13 cooperates with the arc-shaped fixed block 18 on the left front side to grind the raw materials entering therebetween.

In the process of the wheat grains in the feed hopper 12 entering the filter frame 16, the wheat grains that have not been filtered by the filter holes on the left side of the filter frame 16 continue to move. When these wheat grains move to the filter holes on the right side of the filter frame 16, the wheat grains with a middle diameter among the wheat grains move downward through the filter holes on the right side of the filter frame 16, and pass through the discharge port on the rear side of the dividing frame 15 and enter between the rear arc-shaped fixed block 18 and the grinding disc 13, and then repeat the above process to be ground. In this process, the wheat grains that have not been filtered, after passing through the filter frame 16, move downward into between the right front arc-shaped fixed block 18 and the grinding disc 13, and then repeat the above process to grind the wheat grains.

The different sizes of wheat grains are filtered by utilizing the different apertures of the filter holes on the filter frame 16, and the wheat grains of different sizes are transported to between the corresponding arc-shaped fixed block 18 and the grinding disc 13, so as to accurately grind the raw materials of fixed sizes, thereby avoiding the situation in which the overall grinding time increases due to the long grinding time required for grinding large wheat grains, thereby affecting the grinding efficiency.

When the staff puts the raw materials into the feed hopper 12, the staff starts the second motor 2 through the control terminal. The output shaft of the second motor 2 drives the fixed shaft 21 to rotate. The fixed shaft 21 rotates through the pulley and belt drive spiral blades 24. The spiral blades 24 cooperate with the filter frame 16 to make the wheat grains pass evenly and at a uniform speed, ensuring that the wheat grains are fully filtered.

During the rotation of the fixed shaft 21, the fixed shaft 21 drives the first rotating wheel 22 to rotate, and the first rotating wheel 22 drives the filter frame 16 to rotate through the friction transmission of the second rotating wheel 23, so that the wheat grains blocked in the filter holes on the filter frame 16 are scraped off by the clearing block 26, so as to avoid the filter holes on the filter frame 16 being blocked, which affects the efficiency of the filter frame 16 in screening wheat grains.

During the rotation of the fixed shaft 21, the fixed shaft 21 drives the cam 3 to rotate and squeeze the adjacent pressure block 31. After being squeezed, the pressure block 31 drives the clearing block 26 to move downward and compress the adjacent spring 32. The clearing block 26 moves downward to squeeze the wheat grains blocked in the filter holes on the filter frame 16, and clears the filter holes on the filter frame 16. In this way, the filter holes on the filter frame 16 are protected to avoid the blocked wheat grains squeezing the filter holes when the clearing block 26 scrapes off the blocked wheat grains in the filter holes, causing damage to the filter holes.

In the above process, the ground wheat grains fall between the fixed shell 11 and the grinding disc 13, and then the wheat grains are discharged through the discharge port on the fixed shell 11. In this process, the grinding disc 13 drives the discharge plate 19 to rotate and push the ground wheat grains, thereby accelerating the discharge speed of the wheat grains between the fixed shell 11 and the grinding disc 13.

After all the wheat grains are ground and discharged from the fixed shell 11, the staff turns off the first motor 14 and the second motor 2 through the control terminal.

In this embodiment, the connection relationship between the fixed shell 11 and the material distribution rack 17 and the arc-shaped fixed block 18 is a fixed connection, but this is only used to limit this embodiment. In other embodiments, the connection relationship between the fixed shell 11 and the material distribution rack 17 and the arc-shaped fixed block 18 can be a sliding connection. The specific connection relationship can be seen from the specific description in the embodiment.

Embodiment 2: Based on Embodiment 1, as shown in FIGS. 8-11 , a cooling mechanism is further included. The cooling mechanism is disposed on the support frame 1. The cooling mechanism is used to reduce the temperature of the grinding location. The cooling mechanism includes a cooling box 4. A cooling device is disposed in the cooling box 4. The cooling box 4 is mounted on the upper side of the support frame 1. A reflux box 41 is mounted on the upper side of the support frame 1. The reflux box 41 and the cooling box 4 are connected via a delivery pump. Three groups of evenly distributed cooling pipes 42 are fixedly connected to the outer side of the fixed shell 11. The three groups of evenly distributed cooling pipes 42 are respectively located on the outside of adjacent arc-shaped fixed blocks 18. The distance between the uppermost side and the lowermost side of each group of evenly distributed cooling pipes 42 is consistent with the height of the adjacent arc-shaped fixed blocks 18. A liquid inlet pipe 43 is connected between each group of evenly distributed cooling pipes 42 and the cooling box 4. A liquid return pipe 44 is connected between each group of evenly distributed cooling pipes 42 and the reflux box 41. A cooling and temperature adjustment component for adjusting the amount of coolant delivered to each group of evenly distributed cooling pipes 42 is provided on the support frame 1.

As shown in Figures 8 to 11, the cooling and temperature reduction adjustment component includes three first pneumatic telescopic parts 5, and the three first pneumatic telescopic parts 5 are fixedly connected to the upper side of the support frame 1. Three temperature sensing blocks 51 are fixedly connected to the upper side of the grinding disc 13. The three temperature sensing blocks 51 are respectively located on the lower sides of adjacent arc-shaped fixed blocks 18. The telescopic ends of the first pneumatic telescopic parts 5 are sealed and slidably matched with the adjacent temperature sensing blocks 51. A cavity is provided in the temperature sensing block 51, and the cavity of the temperature sensing block 51 is divided into two parts by the telescopic ends of the adjacent first pneumatic telescopic parts 5. The upper part is filled with temperature-sensitive gas whose volume changes with temperature. Three second pneumatic telescopic parts 52 are fixedly connected to the upper side of the support frame 1. The fixed parts of the three second pneumatic telescopic parts 52 are connected to the fixed parts of the adjacent first pneumatic telescopic parts 5 via connecting pipes 53. The liquid inlet pipe 43 is fixedly connected and connected to a square shell 54. The telescopic end of the second pneumatic telescopic part 52 is fixedly connected to a blocking block 55. The blocking block 55 is sealingly and slidably connected to the adjacent square shell 54, thereby regulating the flow area of the coolant in the adjacent square shell 54.

When the staff starts the second motor 2 through the control terminal, the cooling box 4 and the delivery pump are started through the control terminal at the same time. The cooling box 4 cools the coolant therein, and the delivery pump delivers the cooled coolant into three groups of evenly distributed cooling pipes 42 through three liquid inlet pipes 43. Each group of evenly distributed cooling pipes 42 cools the wheat grains ground between the grinding disc 13 and the adjacent arc-shaped fixed blocks 18.

In the above process, since the sizes of the wheat grains ground by the three arc-shaped fixed blocks 18 are different, the temperatures of the wheat grains at the three arc-shaped fixed blocks 18 are also different. Therefore, the temperatures of the wheat grains at the three arc-shaped fixed blocks 18 are detected by the temperature-sensitive gases in the three temperature-sensitive blocks 51. When the temperature-sensitive gases in the temperature-sensitive blocks 51 detect that the temperature of the wheat grains at the corresponding arc-shaped fixed blocks 18 has increased, the temperature-sensitive gases in the temperature-sensitive blocks 51 expand and squeeze the telescopic ends of the adjacent first pneumatic telescopic parts 5 to move downward. Subsequently, the gas in the fixed part of the first pneumatic telescopic part 5 enters the fixed part of the adjacent second pneumatic telescopic part 52 through the adjacent connecting pipe 53, so that the telescopic end of the second pneumatic telescopic part 52 drives the adjacent blocking block 55 to move upward, thereby increasing the flow area of the coolant in the square shell 54, thereby accelerating the circulation efficiency of the coolant and accurately cooling the wheat grains at different arc-shaped fixed blocks 18.

Embodiment 3: On the basis of Embodiment 2, as shown in Figures 8 and 12, it also includes a particle size adjustment mechanism, which is arranged on the fixed shell 11, and the particle size adjustment mechanism is used to adjust the size of the wheat grains after grinding. The particle size adjustment mechanism includes a connecting rod 6, and the connecting rod 6 is fixed to the arc-shaped fixed block 18 on the left front side. Two adjacent arc-shaped fixed blocks 18 among the three arc-shaped fixed blocks 18 are fixed to each other through connecting blocks, and the connecting blocks between two adjacent arc-shaped fixed blocks 18 slide on the distribution rack 17. The fixed shell 11 and the distribution rack 17 are both slidably connected to the arc-shaped fixed blocks 18, and the connecting rod 6 is threadedly connected to a threaded rod 61 that is rotatably connected to the fixed shell 11.

When it is necessary to adjust the size of the ground wheat grains, the staff rotates the threaded rod 61, and the threaded rod 61 rotates the transmission connecting rod 6 to drive the arc-shaped fixed block 18 on the left front side to move, thereby transmitting the other arc-shaped fixed blocks 18 to move synchronously, thereby adjusting the distance between the arc-shaped fixed block 18 and the grinding disc 13, and thus adjusting the size of the ground wheat grains, thereby improving the applicability of the device.

The above embodiments are only for illustrating the technical concept and features of the present invention, and their purpose is to enable people familiar with the technology to understand the content of the present invention and implement it accordingly, and they cannot be used to limit the protection scope of the present invention. Any equivalent changes or modifications made according to the spirit of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a grinding device for food processing, includes support frame (1), the upside rigid coupling of support frame (1) has fixed shell (11), fixed shell (11) are provided with feed inlet and discharge gate, and the feed inlet is located the upside of discharge gate, the feed inlet department rigid coupling of fixed shell (11) and intercommunication have feeder hopper (12), the rotation of fixed shell (11) is connected with mill (13), first motor (14) are installed to support frame (1), the output shaft of first motor (14) with mill (13) rigid coupling, characterized in that still includes and is located divide material frame (15) between mill (13) and the feed inlet, divide material frame (15) rigid coupling in fixed shell (11), the upside rotation of divide material frame (15) is connected with filter frame (16), filter frame (16) with feeder hopper (12) intercommunication, divide the downside rigid coupling of material frame (15) have with divide material frame (17) of fixed shell (11) rigid coupling, divide material frame (17) into with the fixed part (17) and be used for grinding in the arc-shaped section is divided into in the fixed part (18) and is divided into three in the fixed part (11) and is fixed with the arc-shaped material (18), the fixed shell (11) is provided with an anti-blocking cleaning mechanism for preventing the filter frame (16) from being blocked.

2. The grinding device for food processing according to claim 1, wherein the aperture of the filter frame (16) near the filter hole on one side of the feed hopper (12) is smaller than the aperture far away from the filter hole on the other side, two discharge openings are arranged on the material separating frame (15), the discharge opening near the feed hopper (12) is positioned on the lower side of the filter hole with smaller aperture on the filter frame (16), and the discharge opening far away from the feed hopper (12) is positioned on the lower side of the filter hole with larger aperture on the filter frame (16).

3. The grinding device for food processing according to claim 2, wherein the diameters of the inner arcs of the three arc-shaped fixing blocks (18) are not consistent, the smallest diameter of the three arc-shaped fixing blocks (18) is communicated with a discharge opening of the material separating frame (15) close to the feed hopper (12), the middle diameter of the three arc-shaped fixing blocks (18) is communicated with a discharge opening of the material separating frame (15) far away from the feed hopper (12), and the largest diameter of the three arc-shaped fixing blocks (18) is communicated with one side of the filter frame (16) far away from the feed hopper (12).

4. Grinding device for food processing according to claim 1, characterized in that the grinding disc (13) is fixedly connected with a discharge plate (19) flush with the discharge opening of the fixed shell (11), and the discharge plate (19) is used for discharging ground raw materials.

5. The grinding device for food processing according to claim 2, characterized in that the anti-blocking cleaning mechanism comprises a second motor (2), the second motor (2) is installed in the fixed shell (11), a fixed shaft (21) penetrating through the fixed shell (11) is fixedly connected with the output shaft of the second motor (2), the fixed shaft (21) is rotationally connected with the fixed shell (11), a first rotating wheel (22) is fixedly connected with one side of the fixed shaft (21) located in the fixed shell (11), a second rotating wheel (23) in friction transmission with the first rotating wheel (22) is fixedly connected with the filter frame (16), a spiral blade (24) located in the filter frame (16) is rotationally connected with the fixed shaft (21), a symmetrically distributed fixed disc (25) is fixedly connected with the upper side of the fixed shell (11) through a belt wheel and a belt, the symmetrically distributed fixed disc (25) is rotationally connected with the fixed shaft (21), and a sliding block (26) is arranged on the fixed disc (25) and is in sliding block-proof connection with the filter frame (26).

6. The grinding device for food processing according to claim 5, wherein the anti-blocking cleaning assembly comprises symmetrically distributed cams (3), the symmetrically distributed cams (3) are fixedly connected to the fixed shafts (21), the symmetrically distributed cams (3) are respectively and rotatably connected to the adjacent fixed discs (25), the blocking cleaning blocks (26) are fixedly connected with compression blocks (31) located in the adjacent fixed discs (25), the compression blocks (31) are in compression fit with the adjacent cams (3), and springs (32) are connected between the compression blocks (31) and the adjacent fixed discs (25).

7. The grinding device for food processing according to claim 5, further comprising a cooling mechanism, wherein the cooling mechanism is arranged on the supporting frame (1), the cooling mechanism is used for reducing the temperature of a grinding part, the cooling mechanism comprises a cooling box (4), the cooling box (4) is arranged on the upper side of the supporting frame (1), a backflow box (41) is arranged on the upper side of the supporting frame (1), the backflow box (41) and the cooling box (4) are communicated through a conveying pump, three groups of evenly distributed cooling pipes (42) are fixedly connected on the outer side of the fixed shell (11), liquid inlet pipes (43) are respectively communicated between each group of evenly distributed cooling pipes (42) and the cooling box (4), liquid return pipes (44) are respectively communicated between each group of evenly distributed cooling pipes (42) and the backflow box (41), and cooling adjusting components for adjusting conveying cooling liquid amounts into each group of evenly distributed cooling pipes (42) are arranged on the supporting frame (1).

8. The grinding device for food processing according to claim 7, wherein the cooling adjusting assembly comprises three first pneumatic telescopic members (5), the three first pneumatic telescopic members (5) are fixedly connected to the upper side of the supporting frame (1), three temperature sensing blocks (51) are fixedly connected to the upper side in the grinding disc (13), the telescopic ends of the first pneumatic telescopic members (5) are in sealing sliding fit with the adjacent temperature sensing blocks (51), three second pneumatic telescopic members (52) are fixedly connected to the upper side of the supporting frame (1), connecting pipes (53) are communicated between the fixing parts of the second pneumatic telescopic members (52) and the fixing parts of the adjacent first pneumatic telescopic members (5), square shells (54) are fixedly connected and communicated with the liquid inlet pipes (43), and plugging blocks (55) in sealing sliding connection with the adjacent square shells (54) are fixedly connected to the telescopic ends of the second pneumatic telescopic members (52).

9. Grinding device for food processing according to claim 8, characterized in that the three groups of evenly distributed cooling pipes (42) and the three temperature sensing blocks (51) are located in areas corresponding to the areas of adjacent arc-shaped fixed blocks (18), respectively.

10. A grinding device for food processing according to claim 3, further comprising a particle size adjusting mechanism, wherein the particle size adjusting mechanism is arranged on the fixed shell (11), the particle size adjusting mechanism is used for adjusting the size of the ground material, the particle size adjusting mechanism comprises a connecting rod (6), the connecting rod (6) is fixedly connected with the adjacent arc-shaped fixed blocks (18), the adjacent arc-shaped fixed blocks (18) are fixedly connected with each other, the fixed shell (11) and the material distributing frame (17) are both in sliding connection with the arc-shaped fixed blocks (18), and the connecting rod (6) is in threaded connection with a threaded rod (61) which is rotationally connected with the fixed shell (11).