阅读说明：本技术 一种自动化肉类食品加工设备 (Automatic change meat food processing equipment ) 是由 夏江华 于 2020-06-30 设计创作，主要内容包括：本发明公开了一种自动化肉类食品加工设备,包括主机体,所述主机体内设有搅碎室,所述搅碎室的底部设有出料口,所述搅碎室的顶部设有解冻室,所述搅碎室的右侧壁内设有开口向右的入料口,所述搅碎室的上侧位置转动配合连接有转动托盘,所述搅碎室的左侧设有第一内腔,所述第一内腔与所述搅碎室之间转动配合连接有第一转轴,所述第一转轴的右侧末端与所述转动托盘动力配合连接,所述搅碎室内设有搅碎刀组,所述第一内腔的底部设有前后延伸的第二内腔,所述搅碎室的前后设有左右延伸设置的第三内腔,所述第三内腔的左侧末端与所述第二内腔相连通设置,所述第二内腔和所述第三内腔内设有驱动控制机构,本发明能实现解冻以及搅碎工作,提高了安全性和效率。(The invention discloses automatic meat food processing equipment which comprises a main machine body, wherein a stirring chamber is arranged in the main machine body, a discharge hole is formed in the bottom of the stirring chamber, a thawing chamber is formed in the top of the stirring chamber, a feeding hole with a right opening is formed in the right side wall of the stirring chamber, a rotating tray is connected to the upper side of the stirring chamber in a rotating matching mode, a first inner cavity is formed in the left side of the stirring chamber, a first rotating shaft is connected between the first inner cavity and the stirring chamber in a rotating matching mode, the right end of the first rotating shaft is connected with the rotating tray in a power matching mode, a stirring cutter set is arranged in the stirring chamber, a second inner cavity extending front and back is formed in the bottom of the first inner cavity, a third inner cavity extending left and right is formed in the front and back of the stirring chamber, the left end of the third inner cavity is communicated with the second inner cavity, and a drive control mechanism is arranged in the second inner cavity and the third inner cavity, the invention can realize the unfreezing and crushing work and improve the safety and the efficiency.)

1. The utility model provides an automatic change meat product processing equipment, includes the host computer body, the internal garrulous room that stirs that is equipped with of host computer, the bottom of stirring garrulous room is equipped with discharge gate, its characterized in that: the top of the stirring and crushing chamber is provided with a thawing chamber, a feeding opening with a right opening is arranged in the right side wall of the stirring and crushing chamber, the upper side of the stirring and crushing chamber is connected with a rotating tray in a rotating fit manner, the left side of the stirring and crushing chamber is provided with a first inner cavity, a first rotating shaft is connected between the first inner cavity and the stirring and crushing chamber in a rotating fit manner, the right side end of the first rotating shaft is connected with the rotating tray in a power fit manner, the left side end of the first rotating shaft is fixedly provided with a cam, the left side of the cam is connected with a worm gear in a power manner, the top wall of the first inner cavity is communicated with an electrified guide groove, the electrified guide groove is connected with a top pressure rod which extends up and down in a sliding fit manner, the top end surface of the top pressure rod is fixedly provided with a conductive head, a first spring is fixedly arranged between the top pressure rod and the top, the stirring and crushing device is characterized in that a stirring and crushing cutter set is arranged in the stirring and crushing chamber, a second inner cavity extending from front to back is formed in the bottom of the first inner cavity, a third inner cavity extending from left to right is formed in the front and back of the stirring and crushing chamber, the left end of the third inner cavity is communicated with the second inner cavity, and a driving control mechanism is arranged in the second inner cavity and the third inner cavity.

2. An automated meat product processing apparatus as recited in claim 1, wherein: and a discharge door body is arranged at the bottom of the discharge hole.

3. An automated meat product processing apparatus as recited in claim 1, wherein: and infrared thawing mechanisms are symmetrically arranged on the front side and the rear side of the thawing chamber.

4. An automated meat product processing apparatus as recited in claim 1, wherein: a lifting inner cavity which extends up and down is arranged in the feeding hole in a penetrating manner, a rolling cavity is arranged at the lower side position of the lifting inner cavity, a rolling wheel is connected in the rolling cavity in a rotating fit manner, a rolling driving motor which is connected with the rolling wheel in a power fit manner is fixedly arranged in the left side wall of the rolling cavity, a lifting baffle is connected in the lifting inner cavity in a sliding fit manner, a second spring is connected in the lifting baffle in a top-pressing fit manner, a first pull rope is further fixedly arranged on the bottom end face of the lifting baffle, one side, away from the lifting baffle, of the first pull rope extends into the rolling cavity and is fixedly connected with the rolling wheel, an embedded groove is arranged in the left side wall of the lifting inner cavity, a wedge-shaped sliding block is connected in the embedded groove in a sliding fit manner, the embedded groove is positioned at the upper side position, a third spring is fixedly arranged between the wedge-shaped sliding block and the left side wall of the embedded groove, and an inclined plane groove is formed in the position, close to the top, of the left end face of the lifting baffle.

5. An automated meat product processing apparatus as recited in claim 1, wherein: the driving control mechanism comprises a stirring motor fixed on the front side wall of the third inner cavity, the rear side end of the stirring motor is in power connection with a first belt wheel, a second rotating shaft is connected between the third inner cavity and the stirring chamber in a rotating fit manner, the rear side end of the second rotating shaft is in power fit connection with the stirring cutter set, the front side end of the second rotating shaft is fixedly connected with the rear side end of the first belt wheel, the second inner cavity is in rotating fit connection with a third rotating shaft which extends forwards and backwards, a second belt wheel which is opposite to the first belt wheel is fixedly arranged on the third rotating shaft, a transmission belt is in power fit connection between the first belt wheel and the second belt wheel, a first bevel gear fixedly connected with the third rotating shaft is arranged on the rear side of the second belt wheel, and a fourth rotating shaft is in rotating fit connection between the first inner cavity and the second inner cavity, the top of the fourth rotating shaft is fixedly provided with a worm meshed with the worm wheel, the bottom of the fourth rotating shaft is fixedly provided with a first gear located in the second inner cavity, the top wall of the second inner cavity is connected with a fifth rotating shaft in a rotating fit mode, the fifth rotating shaft is located at the front side position of the first gear, the tail end of the bottom of the fifth rotating shaft is fixedly provided with a second bevel gear meshed with the first bevel gear, the upper side of the second bevel gear is provided with a fixing plate fixedly connected with the fifth rotating shaft, the upper side of the fixing plate is provided with a second gear in a spline fit connection with the fifth rotating shaft, a tension spring is fixedly arranged between the second gear and the fixing plate, an annular groove with a T-shaped section is arranged in the second gear, and a connecting block is connected in the annular groove in a sliding fit mode.

6. An automated meat product processing apparatus according to claim 5, wherein: an adjusting sliding cavity is also arranged in the upper side wall body of the second inner cavity, an adjusting sliding block is connected in the adjusting sliding cavity in a sliding fit manner, the top end surface of the adjusting slide block is connected with an adjusting screw rod in a matching way through internal threads, the top end of the adjusting screw rod is connected with an adjusting motor fixedly embedded in the top wall of the adjusting slide cavity in a power matching way, a pull rod is connected between the adjusting sliding cavity and the second inner cavity in a sliding fit manner, the top tail end of the pull rod is fixedly connected with the bottom end face of the adjusting slide block, the bottom end of the pull rod is fixedly connected with the connecting block, an embedded groove is communicated and arranged in the front side wall of the adjusting sliding cavity, an inclined plane sliding strip is connected in the embedded groove in a sliding fit mode, a fourth spring is fixedly arranged between the inclined plane sliding strip and the front side wall of the embedded groove, and a second pull rope is fixedly arranged on the top end surface of the inclined plane slide bar, and the other end of the second pull rope extends into the embedded groove and is fixedly connected with the wedge-shaped sliding block.

7. An automated meat product processing apparatus as recited in claim, wherein: the touch sensor and the conductive head are electrically connected with the infrared unfreezing mechanism.

Technical Field

The invention relates to the technical field of food processing, in particular to automatic meat food processing equipment.

Background

With the increasing requirements of people on the quality and variety of food, various meat products appear on dining tables of people, especially frozen meat products, and meet the fast-paced life requirements of people. The processing technology for meat product molding is traditionally processed by adopting a manual cutting or stirring mode, and has the disadvantages of large labor capacity, low working efficiency and low safety. However, the method cannot meet the requirements of modern production, and people need a device which is reasonable in structural design, convenient to use and simple to operate and is used for rapidly processing frozen meat.

Disclosure of Invention

The invention aims to provide an automatic meat food processing device which is used for overcoming the defects in the prior art.

The automatic meat food processing equipment comprises a main machine body, wherein a stirring chamber is arranged in the main machine body, a discharge hole is formed in the bottom of the stirring chamber, a thawing chamber is formed in the top of the stirring chamber, a feeding hole with a right opening is formed in the right side wall of the stirring chamber, a rotating tray is connected to the upper side of the stirring chamber in a rotating matching mode, a first inner cavity is formed in the left side of the stirring chamber, a first rotating shaft is connected between the first inner cavity and the stirring chamber in a rotating matching mode, the right end of the first rotating shaft is connected with the rotating tray in a power matching mode, a cam is fixedly arranged at the left end of the first rotating shaft, a worm wheel is connected to the left end of the cam in a power-on mode, an electrified guide groove is formed in the top wall of the first inner cavity in a communicating mode, a top pressure rod extending up and down is connected in the electrified guide groove in a sliding matching mode, and a conductive head is fixedly, the electric power crushing device is characterized in that a first spring is fixedly arranged between the top pressure rod and the top wall of the electrified guide groove, a power supply hole connected with a mains supply is formed in the top wall of the electrified guide groove, a crushing cutter set is arranged in the crushing chamber, a second inner cavity extending front and back is formed in the bottom of the first inner cavity, a third inner cavity extending left and right is formed in the front and back of the crushing chamber, the left end of the third inner cavity is communicated with the second inner cavity, and a driving control mechanism is arranged in the second inner cavity and the third inner cavity.

According to the further technical scheme, a discharge door body is arranged at the bottom of the discharge port.

According to a further technical scheme, the front side and the rear side of the thawing chamber are symmetrically provided with infrared thawing mechanisms.

According to a further technical scheme, a lifting inner cavity which extends up and down is arranged in the feeding hole in a penetrating mode, a rolling cavity is arranged at the lower side position of the lifting inner cavity, a rolling wheel is connected in the rolling cavity in a rotating fit mode, a rolling driving motor which is connected with the rolling wheel in a power fit mode is fixedly arranged in the left side wall of the rolling cavity, a lifting baffle is connected in the lifting inner cavity in a sliding fit mode, a second spring is connected in the lifting baffle in a top-pressing fit mode, a first pull rope is further fixedly arranged on the bottom end face of the lifting baffle, one side, away from the lifting baffle, of the first pull rope extends into the rolling cavity and is fixedly connected with the rolling wheel, an embedded groove is arranged in the left side wall of the lifting inner cavity, a wedge-shaped sliding block is connected in the embedded groove in a sliding fit mode, the embedded groove is located at the upper side, a third spring is fixedly arranged between the wedge-shaped sliding block and the left side wall of the embedded groove, and an inclined plane groove is formed in the position, close to the top, of the left end face of the lifting baffle.

In a further technical scheme, the driving control mechanism comprises a mincing motor fixed on the front side wall of the third inner cavity, the rear side end of the mincing motor is in power connection with a first belt wheel, a second rotating shaft is in rotating fit connection with the mincing chamber, the rear side end of the second rotating shaft is in power fit connection with the mincing knife set, the front side end of the second rotating shaft is fixedly connected with the rear side end of the first belt wheel, a third rotating shaft which extends forwards and backwards is in rotating fit connection with the second inner cavity, a second belt wheel which is opposite to the first belt wheel is fixedly arranged on the third rotating shaft, a transmission belt is in power fit connection with the first belt wheel and the second belt wheel, a first bevel gear which is fixedly connected with the third rotating shaft is arranged on the rear side of the second belt wheel, and a fourth rotating shaft is in rotating fit connection with the first inner cavity and the second inner cavity, the top of the fourth rotating shaft is fixedly provided with a worm meshed with the worm wheel, the bottom of the fourth rotating shaft is fixedly provided with a first gear located in the second inner cavity, the top wall of the second inner cavity is connected with a fifth rotating shaft in a rotating fit mode, the fifth rotating shaft is located at the front side position of the first gear, the tail end of the bottom of the fifth rotating shaft is fixedly provided with a second bevel gear meshed with the first bevel gear, the upper side of the second bevel gear is provided with a fixing plate fixedly connected with the fifth rotating shaft, the upper side of the fixing plate is provided with a second gear in a spline fit connection with the fifth rotating shaft, a tension spring is fixedly arranged between the second gear and the fixing plate, an annular groove with a T-shaped section is arranged in the second gear, and a connecting block is connected in the annular groove in a sliding fit mode.

According to a further technical scheme, an adjusting slide cavity is further arranged in the upper side wall body of the second inner cavity, an adjusting slide block is connected in the adjusting slide cavity in a sliding fit manner, an adjusting screw rod is connected to the top end face of the adjusting slide block in a threaded fit manner, the top end of the adjusting screw rod is connected with an adjusting motor fixedly embedded in the top wall of the adjusting slide cavity in a power fit manner, a pull rod is connected between the adjusting slide cavity and the second inner cavity in a sliding fit manner, the top end of the pull rod is fixedly connected with the bottom end face of the adjusting slide block, the bottom end of the pull rod is fixedly connected with the connecting block, an embedded groove is communicated and arranged in the front side wall of the adjusting slide cavity, an inclined plane slide bar is connected in the embedded groove in a sliding fit manner, a fourth spring is fixedly arranged between the inclined plane slide bar and the front side wall of the embedded groove, and a second, the other end of the second pull rope extends into the embedded groove and is fixedly connected with the wedge-shaped sliding block.

According to the further technical scheme, the touch sensor and the conductive head are electrically connected with the infrared unfreezing mechanism.

Drawings

FIG. 1 is a schematic view of the internal structure of an automated meat product processing apparatus of the present invention;

FIG. 2 is a cross-sectional view A-A of FIG. 1 in accordance with the present invention;

FIG. 3 is a cross-sectional view of B-B of FIG. 1 in accordance with the present invention;

FIG. 4 is an enlarged schematic view of C of FIG. 1 in accordance with the present invention;

FIG. 5 is an enlarged schematic view of D of FIG. 3 of the present invention;

FIG. 6 is an enlarged schematic view of E of FIG. 1 according to the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 6, an automatic meat processing device according to an embodiment of the present invention includes a main body 110, a stirring chamber 120 is disposed in the main body 110, a discharge hole 121 is disposed at the bottom of the stirring chamber 120, a thawing chamber 111 is disposed at the top of the stirring chamber 120, a feeding hole 113 with a right opening is disposed in the right sidewall of the stirring chamber 120, a rotating tray 122 is rotatably coupled to the upper side of the stirring chamber 120, a first inner cavity 123 is disposed at the left side of the stirring chamber 120, a first rotating shaft 124 is rotatably coupled between the first inner cavity 123 and the stirring chamber 120, the right end of the first rotating shaft 124 is rotatably coupled to the rotating tray 122, a cam 127 is fixedly disposed at the left end of the first rotating shaft 124, a worm gear 125 is dynamically coupled to the left side of the cam 127, an energizing guide groove 162 is disposed in the top wall of the first inner cavity 123, the electric crushing device is characterized in that a jacking rod 163 which extends up and down is connected in the electrifying guide groove 162 in a sliding fit mode, a conductive head 165 is fixedly arranged on the end face of the top of the jacking rod 163, a first spring 164 is fixedly arranged between the jacking rod 163 and the top wall of the electrifying guide groove 162, a power supply hole 166 which is connected with mains supply is arranged in the top wall of the electrifying guide groove 162, a crushing cutter set 136 is arranged in the stirring chamber 120, a second inner cavity 129 which extends front and back is arranged at the bottom of the first inner cavity 123, a third inner cavity 133 which extends left and right is arranged in front and back of the stirring chamber 120, the tail end of the left side of the third inner cavity 133 is communicated with the second inner cavity 129, and a drive control mechanism is arranged in the second inner cavity.

Advantageously or exemplarily, the discharge port 121 is provided with a discharge door body (not shown) at the bottom thereof so as to facilitate the processing material.

Beneficially or exemplarily, the front side and the rear side of the thawing chamber 111 are symmetrically provided with the infrared thawing mechanisms 112, so as to improve the processing efficiency of the frozen meat.

Beneficially or exemplarily, an up-down inner cavity 114 extending up and down is disposed through the material inlet 113, a winding cavity 117 is disposed at a lower side position of the up-down inner cavity 114, a winding wheel 118 is rotatably and cooperatively connected to the winding cavity 117, a winding driving motor 119 in power fit connection with the winding wheel 118 is fixedly disposed in a left side wall of the winding cavity 117, a lifting baffle 115 is slidably and cooperatively connected to the up-down inner cavity 114, a second spring 116 is connected to a bottom portion of the lifting baffle 115 in a pressing and cooperating manner, a first pulling rope 150 is further fixedly disposed on a bottom end surface of the lifting baffle 115, a side of the first pulling rope 150 away from the lifting baffle 115 extends into the winding cavity 117 and is fixedly connected to the winding wheel 118, an embedded groove 147 is disposed in a left side wall of the up-down inner cavity 114, a wedge-shaped slider 148 is slidably and cooperatively connected to the embedded groove 147, and is located at an upper side position of the material, a touch sensor 152 is fixedly arranged on the top wall of the lifting inner cavity 114, a third spring 149 is fixedly arranged between the wedge-shaped slider 148 and the left side wall of the embedded groove 147, and an inclined plane groove 151 is arranged at the position, close to the top, of the left side end face of the lifting baffle plate 115, so that the lifting shielding work of the lifting baffle plate 115 is automatically controlled, and the safety is improved.

Advantageously or exemplarily, the driving control mechanism includes a mincing motor 134 fixed on a front side wall of the third inner cavity 133, a first belt pulley 137 is power-connected to a rear side end of the mincing motor 134, a second rotating shaft 135 is rotationally coupled between the third inner cavity 133 and the mincing chamber 120, a rear side end of the second rotating shaft 135 is power-coupled to the mincing knife set 136, a front side end of the second rotating shaft 135 is fixedly connected to a rear side end of the first belt pulley 137, a third rotating shaft 130 extending forward and backward is rotationally coupled to the second inner cavity 129, a second belt pulley 132 opposite to the first belt pulley 137 is fixedly arranged on the third rotating shaft 130, a transmission belt 136 is power-coupled between the first belt pulley 137 and the second belt pulley 132, a first bevel gear 131 fixedly connected to the third rotating shaft 130 is arranged on a rear side of the second belt pulley 132, a fourth rotating shaft 128 is connected between the first inner cavity 123 and the second inner cavity 129 in a rotating fit manner, a worm 126 engaged with the worm wheel 125 is fixedly arranged at the top of the fourth rotating shaft 128, a first gear 139 positioned in the second inner cavity 129 is fixedly arranged at the bottom of the fourth rotating shaft 128, a fifth rotating shaft 140 is connected to the top wall of the second inner cavity 129 in a rotating fit manner, the fifth rotating shaft 140 is positioned at the front side of the first gear 139, a second bevel gear 141 engaged with the first bevel gear 131 is fixedly arranged at the bottom end of the fifth rotating shaft 140, a fixing plate 142 fixedly connected with the fifth rotating shaft 140 is arranged on the upper side of the second bevel gear 141, a second gear 144 spline engaged with the fifth rotating shaft 140 is arranged on the upper side of the fixing plate 142, and a tension spring 143 is fixedly arranged between the second gear 144 and the fixing plate 142, an annular groove 145 with a T-shaped section is formed in the second gear 144, and a connecting block 146 is connected to the annular groove 145 in a sliding fit mode, so that the driving work of automatically controlling the mashing is realized.

Beneficially or exemplarily, an adjusting slide cavity 153 is further provided in the upper side wall of the second inner cavity 129, an adjusting slide block 154 is connected in the adjusting slide cavity 153 in a sliding fit manner, an adjusting screw 155 is connected in a top end surface of the adjusting slide block 154 in a threaded fit manner, a top end of the adjusting screw 155 is in a power fit connection with an adjusting motor 160 fixedly embedded in a top wall of the adjusting slide cavity 153, a pull rod 156 is connected between the adjusting slide cavity 153 and the second inner cavity 129 in a sliding fit manner, a top end of the pull rod 156 is fixedly connected with a bottom end surface of the adjusting slide block 154, a bottom end of the pull rod 156 is fixedly connected with the connecting block 146, an embedded groove 157 is provided in the front side wall of the adjusting slide cavity 153 in a communicating manner, an inclined slide strip 158 is connected in a sliding fit manner in the embedded groove 157, a fourth spring 161 is fixedly provided between the inclined slide strip 158 and the front side wall of the, a second pulling rope 159 is fixedly arranged on the top end face of the inclined-plane sliding strip 158, and the other end of the second pulling rope 159 extends into the embedded groove 147 and is fixedly connected with the wedge-shaped sliding block 148.

Advantageously or exemplarily, the touch sensor 152 and the conductive head 165 are electrically connected to the infrared thawing mechanism 112.

At the initial state, the top end face of the rotating tray 122 and the bottom end face of the unfreezing chamber 111 are in the same horizontal state, at this time, the protruding portion of the cam 127 is in a vertical state, and then the cam 127 is in abutting fit with the bottom end face of the abutting rod 163, so that the abutting rod 163 drives the conductive head 165 to move upward against the abutting force of the first spring 164, so that the conductive head 165 is in a fitting connection with the power supply hole 166, at the same time, the lifting baffle 115 is under the abutting force of the second spring 116, so that the lifting baffle 115 is located at the topmost position in the lifting inner cavity 114, so that the inclined plane groove 151 on the lifting baffle 115 is located at the opposite position to the wedge-shaped slider 148, at this time, the wedge-shaped slider 148 is under the abutting force of the third spring 149, so that the wedge-shaped slider 148 is in a fitting connection with the inclined plane groove 151, so as to achieve the locking operation of the, at this time, the adjusting slider 154 drives the second gear 144 to move away from the first gear 139 through the pull rod 156, and at the same time, the top of the adjusting slider 154 moves away from the insertion groove 157, and the inclined-surface slide strip 158 receives the pressing force of the fourth spring 161, so that the left section of the inclined-surface slide strip 158 extends into the adjusting slide cavity 153.

Principle of operation

An adjusting motor 160 drives an adjusting screw 155 to rotate, the adjusting screw 155 drives an adjusting slider 154 to slide along the top direction of an adjusting sliding cavity 153, the adjusting slider 154 is abutted against an inclined surface sliding strip 158, the inclined surface sliding strip 158 overcomes the jacking force of a fourth spring 161 and moves towards an embedded groove 157, at the moment, a second pull rope 159 on the inclined surface sliding strip 158 drives a wedge-shaped slider 148 to overcome the jacking force of a third spring 149, the wedge-shaped slider 148 moves towards an inner embedded groove 147 and further the wedge-shaped slider 148 is far away from the inclined surface groove 151, then a winding driving motor 119 controls a winding wheel 118 to rotate, further the winding wheel 118 drives a lifting baffle plate 115 to move downwards by overcoming the jacking force of a second spring 116 through a first pull rope 150, further a feeding port 113 is opened, then frozen meat to be processed is placed on a rotating tray 122 in a horizontal placement state, and then the winding wheel 118 is controlled to rotate reversely by the winding driving motor 119, the lifting baffle 115 is reset, the adjusting motor 160 drives the adjusting screw 155 to rotate reversely, the adjusting slider 154 is reset, the wedge-shaped slider 148 is matched and connected with the inclined groove 151 again under the action of the jacking force of the third spring 149, and meanwhile, the lifting baffle 115 is abutted against the touch sensor 152 when moving upwards, so that the touch sensor 152 sends a signal and controls the infrared unfreezing mechanism 112 to unfreeze;

after thawing, the adjusting motor 160 drives the adjusting screw 155 to rotate again, the adjusting screw 155 drives the adjusting slider 154 to slide along the top direction of the adjusting slide cavity 153, the adjusting slider 154 drives the second gear 144 to move upwards through the pull rod 156, so that the second gear 144 is engaged with the first gear 139, at this time, the mincing motor 134 controls the first pulley 137 to drive the second gear 144 to rotate with the first gear 139, so that the worm 126 drives the worm 125 to rotate, and further the worm 125 drives the rotating tray 122 to rotate, so that the thawed meat on the rotating tray 122 falls into the mincing chamber 120, at this time, as the rotation of the cam 127 is far away from the top pressure rod 163, the top pressure rod 163 is pressed by the first spring 164, so that the conductive head 165 on the top pressure rod 163 is separated from the power supply hole 166, then the adjusting motor 160 drives the adjusting screw 155 to rotate in the opposite direction, the adjusting slider 154 is driven by the adjusting screw 155 to slide along the bottom direction of the adjusting slide cavity 153, the second gear 144 is moved to the initial position, and then the first pulley 137 is controlled by the mincing motor 134 to drive the second rotating shaft 135 and the mincing knife set 136 to rotate, so as to realize the rapid mincing operation.

The invention has the beneficial effects that: the automatic control device can automatically control the horizontal placing work of the rotating tray 122, is convenient to unfreeze, can automatically control the lifting work of the lifting baffle 115, can realize the automatic locking and opening work of the lifting baffle 115, improves the safety of processing operation, can control the clutch control work of the second gear 144 and the first gear 139, further conveniently controls the driving work of the rotating tray 122, greatly improves the convenience of blanking, realizes the running stability of the rotating tray 122 through the matching work of the worm 126 and the worm wheel 125, can execute the self-locking work of the rotating tray 122, controls the rotation of the crushing cutter set 136 through the crushing motor 134, realizes the quick crushing work, reduces the labor capacity of workers, and improves the working efficiency.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.