CN112841263B - Imitative hand is beaten meat ball processingequipment - Google Patents

Abstract

The invention relates to the technical field of food manufacturing machinery, in particular to a hand-beating-simulated meatball processing device which comprises an upper shell, a driving assembly, a beating assembly and a container, wherein the upper shell is provided with a first cavity and a second cavity; the driving assembly is arranged inside the upper shell and comprises a driving motor, a crankshaft and a connecting rod, the driving motor is fixedly connected inside the upper shell, a power output shaft of the driving motor is fixedly connected with one end of the crankshaft, and at least two crank throws opposite in direction are arranged on the crankshaft. The invention has the beneficial effects that: the hammer body is connected with the upper shell through the spring, so that the hammer body can simulate the 'hand raising' action of manual hammering when hammering to the bottom end, and the processed meatballs are ensured to have elasticity; the hammer block pushes down the drive through two at least sliders, and the slider of difference is different in the inside position of hammer block, and the regional change of hammering effort when can imitate artifical hammering, and then the meat thick liquids that make the hammering out process degree more unanimous everywhere, avoids having great difference between the meatball taste of same batch.

Description

Imitative hand is beaten meat ball processingequipment

Technical Field

The invention relates to the technical field of food manufacturing machinery, in particular to a device for processing handmade-simulated meat balls.

Background

The processing process of the authentic hand-made meatballs generally comprises the steps of beating the chopped beef manually and repeatedly until meat pulp is formed, then adding ingredients into the meat pulp and stirring, and finally extruding the stirred meat pulp into pills and putting the pills into a pot for cooking. It is famous for the taste Q elastic, and delicious. In the process of manual beating, a large amount of time and manpower are consumed, so that the processing efficiency of the traditional hand-beating meatballs is low, and the fast food processing industry is not facilitated. Therefore, in the existing production process, most factories use a mechanical beating mode to replace manual beating to obtain meat pulp.

However, the manual hand-beating process often can not be simulated well in the course of working to current machining device, the biggest difference of the two lies in, the manual work is beaten and is mainly relies on hammer block self gravity to beat meat at whole hammer-dropping in-process to there is the action of one "lift the hand" when the hammer that drops to the bottom, can reduce the impact force of hammer block to meat when dropping to the bottom like this, make the in-process of whole hammering, the acceleration is constantly changing, and then guarantee that whole hammering in-process dynamics is comparatively balanced. The existing dropping hammer process of mechanical beating is usually uniform deceleration motion, and meat cannot rebound in time after being beaten to the bottom end, so that the elasticity of the mechanically processed meat balls is not as good as that of the manually beaten meat balls, and the taste of the meat balls is further influenced. In addition, the force application areas of the existing mechanical processing devices are the same position every time when the hammer falls, so that the processing degrees of all parts of the processed meat pulp are different, and the taste of the meat balls is also influenced.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: provided is a hand-beating-simulated meat ball processing device which can simulate the taste of hand-beating meat balls and can uniformly beat meat pulp.

In order to solve the technical problems, the technical scheme of the invention is as follows: a hand-beating-simulated meatball processing device comprises an upper shell, a driving assembly, a beating assembly and a container;

the driving assembly is arranged in the upper shell and comprises a driving motor, a crankshaft and a connecting rod, the driving motor is fixedly connected in the upper shell, a power output shaft of the driving motor is fixedly connected with one end of the crankshaft, at least two crank throws in opposite directions are arranged on the crankshaft, the number of the connecting rods is consistent with that of the crank throws, one end of the connecting rod is rotatably connected with the crank throws, and the other end of the connecting rod is rotatably connected with a sliding block;

the bottom of the upper shell is provided with an opening, the hammering assembly comprises a hammer body, the hammer body is connected into the opening at the bottom of the upper shell in a sliding manner, the edge of the top of the hammer body is provided with a flange, the flange is elastically connected with the bottom of the upper shell through a spring, the top of the hammer body is provided with sliding grooves with the number consistent with that of the connecting rods, and sliding blocks of the connecting rods are connected into the corresponding sliding grooves in a sliding manner;

the container is detachably connected to the bottom of the upper shell, and the bottom of the hammer body extends to the inside of the container.

The stirring device comprises a container, and is characterized by comprising a transmission assembly and a stirring assembly, wherein the stirring assembly comprises a roller and a plurality of stirring blades, the roller is rotatably connected inside the container, the top of the roller is connected with the driving assembly through the transmission assembly, and the stirring blades are uniformly and fixedly connected to the inner wall of the roller along the circumferential direction.

Specifically, the transmission assembly comprises a driving gear and a driven gear ring, the driving gear is fixedly connected to the crankshaft, the driven gear ring is fixedly connected to the top of the roller, and the driven gear ring is meshed with the driving gear.

Specifically, the roller top is equipped with a plurality of locating pieces, be equipped with the constant head tank corresponding with the locating piece on the inner wall of driven ring gear, the top of roller just is located to driven ring gear cover the locating piece inlays to be located in the constant head tank.

The stirring assembly further comprises a bearing, the bearing is sleeved on the outer wall of the roller and fixedly connected with the roller, a plurality of clamping blocks are fixedly connected to the outer ring of the bearing, a longitudinal sliding groove corresponding to each clamping block is formed in the inner wall of the container, and each clamping block is slidably connected to the corresponding longitudinal sliding groove.

Specifically, beat the subassembly and still include a plurality of pressure sensor, a plurality of fixed slots have evenly been seted up to the bottom of hammer block, pressure sensor fixed connection is in the fixed slot, pressure sensor is connected with driving motor's control system electricity.

Specifically, the bottom end of the pressure sensor and the bottom end of the hammer body are located on the same horizontal plane.

Specifically, a cooling oil cavity, an outer oil duct and a radiating fin are arranged on the upper shell, the outer oil duct is communicated with the cooling oil cavity through a one-way valve, the radiating fin is fixedly connected to the outside of the outer oil duct, an inner oil duct is arranged inside the hammer body, one end of the inner oil duct is communicated with the sliding groove, and the other end of the inner oil duct is communicated with the outer oil duct on the upper shell through a flexible pipeline.

Specifically, the outer side of the sliding block is sleeved with a sealing ring.

Specifically, the side wall of the container is provided with a ventilation port, and a ventilation fan is fixedly connected in the ventilation port.

The invention has the beneficial effects that: the hammer body is connected with the upper shell through the spring, so that the hammer body can simulate the 'hand raising' action of manual hammering when hammering to the bottom end, and the processed meatballs are ensured to have elasticity; the hammer body is driven to be pressed downwards through at least two sliding blocks, different sliding blocks are different in position inside the hammer body, and regional change of hammering acting force during manual hammering can be simulated, so that processing degrees of hammered meat pulp are more consistent everywhere, and great difference between tastes of meatballs in the same batch is avoided; the hammer body is driven to move by driving the plurality of sliding blocks through the same crankshaft, so that the hammering efficiency of the hammer body can be effectively improved, and the energy consumption of the driving motor can be further saved.

Drawings

FIG. 1 is a schematic structural diagram of a device for processing simulated handmade meatballs according to an embodiment of the present invention;

FIG. 2 is a schematic view of a portion of the internal structure of a device for processing simulated handmade meatballs according to an embodiment of the present invention;

FIG. 3 is a top view of a drum according to an embodiment of the present invention;

description of reference numerals:

1. an upper housing; 11. an opening; 12. cooling the oil cavity; 13. an outer oil gallery; 14. a heat sink; 2. a drive assembly; 21. a drive motor; 22. a crankshaft; 221. a crank throw; 23. a connecting rod; 231. a slider; 3. a hammering assembly; 31. a hammer body; 311. a flange; 312. a chute; 313. an inner oil gallery; 32. a pressure sensor; 4. a container; 41. a longitudinal slot; 42. a ventilation fan; 5. a transmission assembly; 51. a driving gear; 52. a driven gear ring; 6. a stirring component; 61. a drum; 62. turning over the stirring blades; 63. and a bearing.

Detailed Description

In order to explain technical contents, achieved objects, and effects of the present invention in detail, the following description is made with reference to the accompanying drawings in combination with the embodiments.

Referring to fig. 1 to 3, the device for processing artificial hand-beaten meat balls according to the invention comprises an upper casing 1, a driving assembly 2, a beating assembly 3 and a container 4;

the driving assembly 2 is arranged inside the upper shell 1, the driving assembly 2 comprises a driving motor 21, a crankshaft 22 and a connecting rod 23, the driving motor 21 is fixedly connected inside the upper shell 1, a power output shaft of the driving motor 21 is fixedly connected with one end of the crankshaft 22, at least two opposite crank throws 221 are arranged on the crankshaft 22, the number of the connecting rods 23 is consistent with that of the crank throws 221, one end of the connecting rod 23 is rotatably connected with the crank throws 221, and the other end of the connecting rod 23 is rotatably connected with a sliding block 231;

the bottom of the upper shell 1 is provided with an opening 11, the hammering assembly 3 comprises a hammer body 31, the hammer body 31 is slidably connected into the opening 11 at the bottom of the upper shell 1, the top edge of the hammer body 31 is provided with a flange 311, the flange 311 is elastically connected with the bottom of the upper shell 1 through a spring, the top of the hammer body 31 is provided with sliding grooves 312 with the same number as the connecting rods 23, and the sliding blocks 231 of the connecting rods 23 are slidably connected into the corresponding sliding grooves 312;

the container 4 is detachably connected to the bottom of the upper casing 1, and the bottom of the hammer body 31 extends into the container 4.

The working principle of the invention is as follows: go up casing 1 and fix on the processing board through outside fixing device, before the processing, put into container 4 with the meat that cuts well earlier to install container 4 to supreme casing 1 bottom, utilize the bottom that bears container 4 afterwards to hold, avoid leading to container 4 and last casing 1 to take place to break away from because the impact of hammer block 31 in the course of working.

During processing, the power supply of the driving motor 21 is switched on, the driving motor 21 drives one end of the connecting rod 23 to rotate, the sliding blocks 231 at the other end of the connecting rod 23 slide up and down in the sliding grooves 312 of the hammer body 31 in a reciprocating mode, at least two sliding blocks 231 push the hammer body 31 to press down in turn and hammer meat in the container 4, and due to the fact that different sliding blocks 231 are different in position in the hammer body 31, the force action area of each hammer blow of the hammer body 31 is different, and therefore the regional change of the hammer blow acting force during manual hammering is simulated. Simultaneously because hammer block 31 is through elastic connection between spring and the last casing 1, consequently hammer block 31 whereabouts in-process receives the influence of spring elastic force, especially when hammer block 31 hammering to the lower extreme, slider 231 shifts up this moment, and the spring contracts fast and drives hammer block 31 and rises rapidly to the action of "raising one's hands" when can imitate artifical hammering ensures that meat can kick-back fast when being hammered to the lower extreme, guarantees that the meat ball that processes has elasticity more.

In addition, because the plurality of sliding blocks 231 are driven by one crankshaft 22 to drive the hammer body 31 to move, the hammer body 31 can perform up-and-down reciprocating motion for a plurality of times under the condition that the crankshaft 22 rotates for a circle, the hammering efficiency of the hammer body 31 is greatly improved, and meanwhile, the energy consumption of the driving motor 21 can be saved.

As can be seen from the above description, the beneficial effects of the present invention are: the hammer body is connected with the upper shell through the spring, so that the hammer body can simulate the 'hand raising' action of manual hammering when hammering to the bottom end, and the processed meatballs are ensured to have elasticity; the hammer body is driven to be pressed downwards through at least two sliding blocks, different sliding blocks are different in position inside the hammer body, and regional change of hammering acting force during manual hammering can be simulated, so that processing degrees of hammered meat pulp are more consistent everywhere, and great difference between tastes of meatballs in the same batch is avoided; the hammer body is driven to move by driving the plurality of sliding blocks through the same crankshaft, so that the hammering efficiency of the hammer body can be effectively improved, and the energy consumption of the driving motor can be further saved.

Further, the stirring device comprises a transmission assembly 5 and a stirring assembly 6, wherein the stirring assembly 6 comprises a roller 61 and a plurality of stirring blades 62, the roller 61 is rotatably connected inside the container 4, the top of the roller 61 is connected with the driving assembly 2 through the transmission assembly 5, and the stirring blades 62 are uniformly and fixedly connected to the inner wall of the roller 61 along the circumferential direction.

According to the description, under the observation condition of an overlooking visual angle, a certain included angle is formed between the projection line of the stirring blade and the radius of the roller, the driving assembly drives the hammer body, the roller can rotate in the container through the transmission assembly, the stirring blade moves relative to the bottom of the container along with the rotation of the roller, and then the meat pulp which is hammered to the outside of the range of the hammer body is driven by the stirring blade to be stirred into the hammering range of the hammer body again.

Further, the transmission assembly 5 includes a driving gear 51 and a driven gear ring 52, the driving gear 51 is fixedly connected to the crankshaft 22, the driven gear ring 52 is fixedly connected to the top of the drum 61, and the driven gear ring 52 is engaged with the driving gear 51.

As apparent from the above description, the driving gear and the driven gear ring are bevel gears engaged with each other, so that the direction of power transmission can be changed, and the driving gear and the driven gear ring can be freely separated or engaged, so that the driving gear ring and the driven gear ring can be rapidly engaged with each other while the container is mounted to the bottom of the upper case.

Further, a plurality of locating blocks are arranged at the top end of the roller 61, locating grooves corresponding to the locating blocks are formed in the inner wall of the driven gear ring 52, the driven gear ring 52 is sleeved on the top of the roller 61, and the locating blocks are embedded in the locating grooves.

As can be seen from the above description, the driven gear ring and the roller can be conveniently disassembled and assembled, so that the driven gear ring can be conveniently maintained and replaced.

Further, the stirring assembly 6 further comprises a bearing 63, the bearing 63 is sleeved on the outer wall of the roller 61 and is fixedly connected with the roller 61, a plurality of clamping blocks are fixedly connected to the outer ring of the bearing 63, a longitudinal groove 41 corresponding to the clamping blocks is formed in the inner wall of the container 4, and the clamping blocks are slidably connected in the longitudinal groove 41.

As can be seen from the above description, the bearing can rotate more smoothly and stably, and the fixture block and the longitudinal groove can ensure that the outer ring of the bearing cannot rotate relative to the inner wall of the container.

Further, the hammering assembly 3 further comprises a plurality of pressure sensors 32, a plurality of fixing grooves are uniformly formed in the bottom end of the hammer body 31, the pressure sensors 32 are fixedly connected in the fixing grooves, and the pressure sensors 32 are electrically connected with a control system of the driving motor 21.

It can be known from the above description that, when pressure sensor can respond to the hammer block hammering, the counter force that the hammer block bottom received, because meat is at the in-process that the hammering formed meat thick liquid, the meat quality changes, its counter force to the hammer block can change, and pressure sensor can receive force feedback to driving motor's control system at every turn, when pressure variation reached certain threshold value, driving motor's control system can change driving motor's rotational speed, and then realize the change of hammering frequency, thereby can realize adjusting this process of beating frequency according to the power of meat quality feedback when simulating the manual process. In addition, a plurality of pressure sensor arrange in the different positions of hammer block bottom, and the effort that the pressure sensor when the different positions feedbacked tends to be the same, then can explain that each part hammering of meat thick liquid is even, and driving motor's control system can judge whether hammering of meat thick liquid is accomplished according to the even degree of each pressure sensor feedback dynamics and whether reach predetermined threshold value in combination pressure sensor's feedback dynamics. Therefore, the processing device can adaptively adjust the hammering frequency of hammering time according to different meat qualities processed each time, and meat pulp of different batches can reach the unified standard.

Further, the bottom end of the pressure sensor 32 is located at the same horizontal plane as the bottom end of the hammer body 31.

Further, a cooling oil cavity 12, an outer oil channel 13 and a heat sink 14 are arranged on the upper shell 1, the outer oil channel 13 is communicated with the cooling oil cavity 12 through a one-way valve, the heat sink 14 is fixedly connected to the outside of the outer oil channel 13, an inner oil channel 313 is arranged inside the hammer body 31, one end of the inner oil channel 313 is communicated with the sliding groove 312, and the other end of the inner oil channel 313 is communicated with the outer oil channel 13 on the upper shell 1 through a flexible pipeline.

According to the description, the hammer body is easy to generate heat after being hit for a long time, and in order to avoid the denaturation of protein of meat pulp caused by the temperature rise of the hammer body, the slide block can be directly used as an oil pump, so that cooling oil is continuously circulated and exchanges heat between the inner oil duct and the outer oil duct, the effect of reducing the temperature of the hammer body is achieved, and the influence on the taste due to the denaturation of the protein of the meat pulp is avoided. In addition, the cooling oil has a certain damping effect, so that the rigid impact force between the sliding grooves of the sliding block and the hammer body can be reduced, and the service life of the sliding block and the hammer body is prolonged.

Further, a sealing ring is sleeved outside the slider 231.

From the above description, the seal ring can prevent the cooling oil from leaking.

Further, a ventilation port is formed in the side wall of the container 4, and a ventilation fan 42 is fixedly connected in the ventilation port.

According to the above description, the ventilation ports and the fan can ventilate and cool the inside of the container, so that the phenomenon that the taste of the meat pulp is influenced by the temperature rise inside the container is avoided.

Example one

A simulated hand-beating meat ball processing device is shown in figure 1 and comprises an upper shell 1, a driving assembly 2, a beating assembly 3 and a container 4;

the drive assembly 2 is arranged inside the upper shell 1, the drive assembly 2 comprises a drive motor 21, a crankshaft 22 and a connecting rod 23, the drive motor 21 is fixedly connected inside the upper shell 1, a power output shaft of the drive motor 21 is fixedly connected with one end of the crankshaft 22, as shown in fig. 2, at least two crank throws 221 opposite in direction are arranged on the crankshaft 22, the number of the connecting rods 23 is consistent with that of the crank throws 221, one end of the connecting rod 23 is rotatably connected with the crank throws 221, the other end of the connecting rod 23 is rotatably connected with a sliding block 231, the crank throws 221 comprise two crank arms and connecting rod journals which are fixedly connected between the two crank arms and are parallel to main journals of the cranks, and one ends, far away from diameters of the connecting rod journals, of the crank arms are provided with balance weights.

The bottom of the upper shell 1 is provided with an opening 11, wherein the opening 11 is a tubular opening, the hammering assembly 3 comprises a hammer body 31 and a plurality of pressure sensors 32, the hammer body 31 is slidably connected in the opening 11 at the bottom of the upper shell 1, the top edge of the hammer body 31 is provided with a flange 311, the flange 311 is elastically connected with the bottom of the upper shell 1 through a spring, the top of the hammer body 31 is provided with sliding grooves 312 with the same number as the connecting rods 23, the sliding blocks 231 of the connecting rods 23 are slidably connected in the corresponding sliding grooves 312, the bottom end of the hammer body 31 is uniformly provided with a plurality of fixing grooves, the pressure sensors 32 are fixedly connected in the fixing grooves, the pressure sensors 32 are electrically connected with the control system of the driving motor 21, and the bottom ends of the pressure sensors 32 and the hammer body 31 are located on the same horizontal plane;

the upper shell 1 is provided with a cooling oil cavity 12, an outer oil channel 13 and a radiating fin 14, the outer oil channel 13 is communicated with the cooling oil cavity 12 through a one-way valve, the radiating fin 14 is fixedly connected to the outside of the outer oil channel 13, an inner oil channel 313 is arranged inside the hammer body 31, one end of the inner oil channel 313 is communicated with the sliding groove 312, the other end of the inner oil channel 313 is communicated with the outer oil channel 13 on the upper shell 1 through a flexible pipeline, and a sealing ring is sleeved on the outer side of the sliding block 231;

the container 4 is detachably connected to the bottom of the upper shell 1, wherein the container 4 can be connected to the bottom of the upper shell 1 through threads or clamped through a buckle, the bottom of the hammer body 31 extends into the container 4, a ventilation port is formed in the side wall of the container 4, and a ventilation fan 42 is fixedly connected in the ventilation port;

the stirring device comprises a container, and is characterized by further comprising a transmission assembly 5 and a stirring assembly 6, wherein the stirring assembly 6 comprises a roller 61 and a plurality of stirring blades 62, the roller 61 is rotatably connected inside the container 4, the top of the roller 61 is connected with a driving assembly 2 through the transmission assembly 5, as shown in fig. 3, the plurality of stirring blades 62 are uniformly and fixedly connected to the inner wall of the roller 61 along the circumferential direction, the stirring assembly 6 further comprises a bearing 63, the bearing 63 is sleeved on the outer wall of the roller 61 and fixedly connected with the roller 61, a plurality of clamping blocks are fixedly connected to the outer ring of the bearing 63, a longitudinal groove 41 corresponding to the clamping blocks is formed in the inner wall of the container 4, and the clamping blocks are slidably connected in the longitudinal groove 41;

the transmission assembly 5 comprises a driving gear 51 and a driven gear ring 52, the driving gear 51 and the driven gear ring 52 are both bevel gears, the driving gear 51 is fixedly connected to the crankshaft 22, the driven gear ring 52 is fixedly connected to the top of the roller 61, the driven gear ring 52 is meshed with the driving gear 51, a plurality of positioning blocks are arranged at the top end of the roller 61, positioning grooves corresponding to the positioning blocks are formed in the inner wall of the driven gear ring 52, the driven gear ring 52 is sleeved on the top of the roller 61, and the positioning blocks are embedded in the positioning grooves.

In conclusion, the beneficial effects provided by the invention are as follows: the hammer body is connected with the upper shell through the spring, so that the hammer body can simulate the 'hand raising' action of manual hammering when hammering to the bottom end, and the processed meatballs are ensured to have elasticity; the hammer body is driven to be pressed downwards through at least two sliding blocks, different sliding blocks are different in position inside the hammer body, and regional change of hammering acting force during manual hammering can be simulated, so that processing degrees of hammered meat pulp are more consistent everywhere, and great difference between tastes of meatballs in the same batch is avoided; the hammer body is driven to move by driving the plurality of sliding blocks through the same crankshaft, so that the hammering efficiency of the hammer body can be effectively improved, and the energy consumption of the driving motor can be further saved. Overlook under the observation condition of visual angle, have certain contained angle between the radius of the projection line of stirring the blade and cylinder, and drive assembly when the drive hammer block, can also make the cylinder at the container internal rotation through drive assembly, stir the blade along with the rotation of cylinder this moment, the relative container bottom in its bottom moves, and then can make the meat thick liquid that is hammered to hammer block scope outside under stirring the blade's drive and be stirred the hammering within range of hammer block again. The driving gear and the driven gear ring are bevel gears engaged with each other, so that the direction of power transmission can be changed, and the driving gear and the driven gear ring can be freely separated or engaged, so that the driving gear ring and the driven gear ring can be rapidly engaged with each other while the container is mounted to the bottom of the upper housing. The driven gear ring and the roller can be conveniently disassembled and assembled, so that the driven gear ring is convenient to maintain and replace. The roller is more smooth and stable when the bearing can rotate, and the fixture block and the longitudinal groove can ensure that the outer ring of the bearing cannot rotate relative to the inner wall of the container. When pressure sensor can respond to the hammer block hammering, the counter force that the hammer block top received, because meat forms the in-process of meat thick liquid at the hammering, the meat quality changes, it can change the counter force of hammer block, and pressure sensor can receive force feedback to driving motor's control system at every turn, when pressure variation reaches certain threshold value, driving motor's control system can change driving motor's rotational speed, and then realize the change of hammering frequency, thereby can realize adjusting this process of beating frequency according to the power of meat quality feedback when simulating artifical manual process. In addition, a plurality of pressure sensor arrange in the different positions of hammer block bottom, and the effort that the pressure sensor when the different positions feedbacked tends to be the same, then can explain that each part hammering of meat thick liquid is even, and driving motor's control system can judge whether hammering of meat thick liquid is accomplished according to the even degree of each pressure sensor feedback dynamics and whether reach predetermined threshold value in combination pressure sensor's feedback dynamics. Therefore, the processing device can adaptively adjust the hammering frequency of hammering time according to different meat qualities processed each time, and meat pulp of different batches can reach the unified standard. Because the hammer body is easy to generate heat after being hit for a long time, in order to avoid the temperature rise of the hammer body to cause the protein of the meat paste to generate denaturation, the slide block can be directly used as an oil pump, so that the cooling oil continuously circulates and exchanges heat between the inner oil duct and the outer oil duct, the effect of reducing the temperature of the hammer body is achieved, and the influence on the taste due to the denaturation of the protein of the meat paste is avoided. In addition, the cooling oil has a certain damping effect, so that the rigid impact force between the sliding grooves of the sliding block and the hammer body can be reduced, and the service life of the sliding block and the hammer body is prolonged. The sealing ring can avoid the cooling oil from leaking. The draught port and the fan can ventilate and cool the inside of the container, and the inside temperature rise of the container is avoided to influence the taste of the meat pulp.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent changes made by using the contents of the present specification and the drawings, or applied directly or indirectly to the related technical fields, are included in the scope of the present invention.

Claims (7)

1. A hand-beating-simulated meat ball processing device is characterized by comprising an upper shell, a driving assembly, a beating assembly and a container;

the driving assembly is arranged in the upper shell and comprises a driving motor, a crankshaft and a connecting rod, the driving motor is fixedly connected in the upper shell, a power output shaft of the driving motor is fixedly connected with one end of the crankshaft, at least two crank throws in opposite directions are arranged on the crankshaft, the number of the connecting rods is consistent with that of the crank throws, one end of the connecting rod is rotatably connected with the crank throws, and the other end of the connecting rod is rotatably connected with a sliding block;

the bottom of the upper shell is provided with an opening, the hammering assembly comprises a hammer body, the hammer body is connected into the opening at the bottom of the upper shell in a sliding manner, the edge of the top of the hammer body is provided with a flange, the flange is elastically connected with the bottom of the upper shell through a spring, the top of the hammer body is provided with sliding grooves with the number consistent with that of the connecting rods, and sliding blocks of the connecting rods are connected into the corresponding sliding grooves in a sliding manner;

the container is detachably connected to the bottom of the upper shell, and the bottom of the hammer body extends into the container;

the stirring device comprises a container, and is characterized by further comprising a transmission assembly and a stirring assembly, wherein the stirring assembly comprises a roller and a plurality of stirring blades, the roller is rotatably connected inside the container, the top of the roller is connected with the driving assembly through the transmission assembly, and the stirring blades are uniformly and fixedly connected to the inner wall of the roller along the circumferential direction;

the transmission assembly comprises a driving gear and a driven gear ring, the driving gear is fixedly connected to the crankshaft, the driven gear ring is fixedly connected to the top of the roller, and the driven gear ring is meshed with the driving gear;

the hammer is characterized in that the upper shell is provided with a cooling oil cavity, an outer oil duct and a radiating fin, the outer oil duct is communicated with the cooling oil cavity through a one-way valve, the radiating fin is fixedly connected to the outside of the outer oil duct, an inner oil duct is arranged inside the hammer body, one end of the inner oil duct is communicated with the sliding groove, and the other end of the inner oil duct is communicated with the outer oil duct on the upper shell through a flexible pipeline.

2. The device for processing imitation handmade meatballs according to claim 1, wherein a plurality of positioning blocks are arranged at the top end of the drum, positioning grooves corresponding to the positioning blocks are arranged on the inner wall of the driven gear ring, the driven gear ring is sleeved at the top of the drum, and the positioning blocks are embedded in the positioning grooves.

3. The device for processing imitation handmade meatballs according to claim 1, wherein the stirring assembly further comprises a bearing, the bearing is sleeved on the outer wall of the roller and is fixedly connected with the roller, a plurality of clamping blocks are fixedly connected to the outer ring of the bearing, a longitudinal groove corresponding to the clamping blocks is formed in the inner wall of the container, and the clamping blocks are slidably connected in the longitudinal groove.

4. The device for processing the imitation handmade meatballs according to claim 1, wherein the hammering assembly further comprises a plurality of pressure sensors, a plurality of fixing grooves are uniformly formed in the bottom end of the hammer body, the pressure sensors are fixedly connected in the fixing grooves, and the pressure sensors are electrically connected with a control system of the driving motor.

5. The device for processing imitation handmade meatballs according to claim 4, wherein the bottom end of the pressure sensor is located at the same level as the bottom end of the hammer body.

6. The device for processing the imitation handmade meatballs according to claim 1, wherein a sealing ring is sleeved outside the sliding block.

7. The device for processing the imitation handmade meatballs according to claim 1, wherein a ventilation port is formed in a side wall of the container, and a ventilation fan is fixedly connected in the ventilation port.

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