阅读说明：本技术 一种食品加工用切肉装置 (Meat cutting device for food processing ) 是由 戴友翠 于 2021-08-05 设计创作，主要内容包括：本发明公开了一种食品加工用切肉装置,包括台架、支撑框架、支撑盒、进料斗、通管、转移通道、吹击组件、击打组件、振动组件和切割组件；所述支撑盒设置于所述台架的上表面；所述支撑框架设置于支撑盒的上表面；所述支撑框架包括竖直设置的第一侧壁；所述通管竖直嵌设于所述第一侧壁；所述进料斗的出口呈圆孔状,且孔径为预设孔径；所述进料斗的出口通过波纹管连通于所述通管的顶端开口；通过本发明提出的食品加工用切肉装置,能够自动对鸭脖进行角度调整,不再需要人工将鸭脖的切割角度进行调节,大大降低了工作人员的切制工作量,提升了切制的效率。(The invention discloses a meat cutting device for food processing, which comprises a rack, a supporting frame, a supporting box, a feeding hopper, a through pipe, a transfer channel, a blowing component, a beating component, a vibrating component and a cutting component, wherein the rack is provided with a support frame; the supporting box is arranged on the upper surface of the rack; the supporting frame is arranged on the upper surface of the supporting box; the support frame comprises a first side wall which is vertically arranged; the through pipe is vertically embedded in the first side wall; the outlet of the feed hopper is in a circular hole shape, and the aperture is a preset aperture; the outlet of the feed hopper is communicated with the top end opening of the through pipe through a corrugated pipe; the meat cutting device for food processing can automatically adjust the angle of the duck neck, does not need to manually adjust the cutting angle of the duck neck, greatly reduces the cutting workload of workers and improves the cutting efficiency.)

1. A meat cutting device for food processing is characterized by comprising a rack, a supporting frame, a supporting box, a feeding hopper, a through pipe, a transfer channel, a blowing component, a beating component, a vibrating component and a cutting component; the supporting box is arranged on the upper surface of the rack; the supporting frame is arranged on the upper surface of the supporting box; the support frame comprises a first side wall which is vertically arranged; the through pipe is vertically embedded in the first side wall;

the outlet of the feed hopper is in a circular hole shape, and the aperture is a preset aperture; the outlet of the feed hopper is communicated with the top end opening of the through pipe through a corrugated pipe; the transfer channel comprises a supporting plate, an upper cover plate, a first side plate and a second side plate which are arranged oppositely and vertically; the first side plate and the second side plate are in a right trapezoid shape; the supporting plate is connected with the upper surface of the supporting box; the first side plate and the second side plate are both connected to the upper surface of the supporting plate; the upper cover plate is obliquely arranged and connected between the top of the first side plate and the top of the second side plate; the transfer channel is formed with an inlet end and an outlet end;

the cutting assembly comprises a semicircular groove body, a cutter and a driving part; the cutter is arranged right above the semicircular groove body; the cutter is semicircular; the driving part is used for driving the cutter to vertically move and is embedded into the semicircular groove body in a matching manner so as to cut the material in the semicircular groove body;

a discharge long hole is vertically formed in the lower part of the through pipe; the inlet end is connected with the through pipe and communicated with the discharge long hole; the semicircular groove body extends along the horizontal direction, is arranged on the upper surface of the rack and is right opposite to the outlet end;

the vibration component is used for vibrating the feed hopper so as to enable materials to enter the through pipe vertically in sequence; the blowing component is used for blowing the materials positioned at the lowest part of the through pipe so as to enable the materials to be poured and enter the transfer channel; the beating assembly is used for beating the poured materials, so that the poured materials enter the semicircular groove body.

2. The meat cutting device for food processing as claimed in claim 1, wherein the vibration assembly includes a vibration motor, a first sleeve, a first spring, a connecting rod and a lifting rod; the vertical first sleeve is arranged on the upper surface of the supporting frame; the connecting rod is horizontally connected to the outer wall of the feed hopper; the lifting rod is vertically connected to one end, far away from the feed hopper, of the connecting rod; the lifting rod is matched with the first sleeve and is embedded in the first sleeve in a sliding manner; the first spring is sleeved on the lifting rod; one end of the first spring is connected to the connecting rod, and the other end of the first spring is connected to the top of the first sleeve; the vibration motor is arranged on the outer wall of the vibration motor.

3. The meat cutting device for food processing as claimed in claim 1, wherein the blowing assembly comprises a rotating arm, a supporting piece, a second sleeve, a stop lever, an air nozzle and an air pump; the supporting box is provided with a groove; the supporting frame is provided with an inner cavity; the bottom end of the through pipe is open and is communicated with the groove; the groove is communicated with the inner cavity; the lower edge of the discharge long hole is aligned with the upper surface of the supporting plate;

the middle part of the rotating arm is hinged with the groove; the rotating surface of the rotating arm is a vertical surface; one end of the rotating arm is connected with the bearing sheet; the supporting sheet can be lifted in the through pipe; the second sleeve is vertically arranged in the inner cavity; the stop lever is vertically embedded in the second sleeve in a sliding manner; the air nozzle is arranged in the inner cavity; the through pipe is provided with an air outlet; the air outlet is positioned in the vertical range of the discharging long hole; the air nozzle is right opposite to the air outlet; the air pump is communicated with the air nozzle; the air injection direction of the air injection nozzle is the horizontal direction;

the lower end of the stop lever is movably contacted with the upper surface of one end of the rotating arm far away from the bearing sheet; the upper end of the stop lever can block the air horizontally sprayed to the air outlet by the air nozzle.

4. The meat cutting apparatus as claimed in claim 3, wherein the blowing assembly further comprises a stopper and a stopper; the structure that the upper end of pin can block the air that air nozzle level spouts to the venthole does:

the middle part of the baffle plate is provided with an air hole; the baffle plate is vertically arranged at the top end of the baffle rod; the limiting block is arranged in the groove and is positioned below one end of the rotating arm, which is connected with the bearing piece; under the normal state, the stop lever is downwards abutted against one end of the rotating arm, which is far away from the bearing piece, under the action of self weight, and the air nozzle is blocked by the blocking piece; when the bearing piece is impacted by falling of materials, the rotating arm rotates to be in contact with the top end of the limiting block, and the stop lever moves upwards under the action of the rotating arm, so that the air holes are opposite to the air nozzles, and the air nozzles jet air to the air outlet holes.

5. The meat slicer as claimed in claim 3, wherein said air outlet is located at an upper portion of a vertical range of said discharge slot.

6. The meat cutting device for food processing as claimed in claim 4, wherein when the rotation arm contacts the stopper, the support piece is still higher than the lower edge of the discharge slot.

7. The meat cutting device for food processing as claimed in claim 3, wherein the hitting assembly comprises a proximity sensor, a controller, a hitting rod, a fixed seat, a second spring, a first electromagnet and a first baffle ring;

the proximity sensor is arranged on the inner wall of the first side plate close to the supporting plate; the bottom end of the through pipe is provided with a knocking hole; the knocking hole is positioned on the lower part of the discharging long hole in the vertical range; the fixed seat and the second electromagnet are both arranged in the second accommodating cavity; the knocking rod horizontally slides and penetrates through the fixed seat; the first baffle ring is coaxially sleeved on the knocking rod; the second spring is sleeved on the knocking rod; one end of the second spring is connected to the fixed seat; the other end of the second spring is connected to the first baffle ring; one end of the knocking rod can movably penetrate through the knocking hole and extend into the through pipe; the knocking rod is an iron knocking rod; the other end of the knocking rod is horizontally and rightly opposite to the first electromagnetic molten iron; when the first electromagnet is attracted with the knocking rod, the knocking rod does not penetrate through the knocking hole; the second spring is always in a compressed state, and the first baffle ring is positioned between the fixed seat and the through pipe; the proximity sensor is in communication connection with the controller; the controller is used for controlling the starting and stopping of the first electromagnet.

8. The meat cutting apparatus for food processing as set forth in claim 7, wherein a ring is formed at a lower portion of the blocking lever; the knocking rod movably penetrates through the ring.

9. The meat cutting apparatus for food processing as claimed in claim 1, wherein the cutting assembly further comprises a support post, a flipping motor and a rotating shaft; the support column is arranged on the upper surface of the rack and is positioned on one side of the semicircular groove body, which is far away from the support box; two ends of the rotating shaft are respectively and rotatably connected to the supporting column and the supporting box; the rotating shaft is horizontally arranged; the rotating shaft is fixedly connected to the bottom of the semicircular groove body; the overturning motor is connected to the rotating shaft through a speed reducer in a driving mode.

10. The meat cutting apparatus as recited in claim 9 wherein said cutting assembly further comprises a support frame; the support frame is arranged on the upper surface of the rack; the driving part is a hydraulic cylinder; the base of the hydraulic cylinder is arranged on the support frame.

Technical Field

The invention relates to the technical field of food processing instruments, in particular to a meat cutting device for food processing.

Background

In recent years, the market prospect of leisure food is expanding continuously, wherein the spiced cooked food is more popular among consumers; the primary taste spicy marinated products such as the marinated duck necks, the duck claws, the chicken claws and the like are more primary taste categories of the current marinated cooked food products; the preparation process of these pot-stewed foods generally comprises cutting, soaking in brine, drying and packaging.

In the prior art, the cutting of the raw material of the marinated cooked food is mostly finished manually, and for some long-sized raw materials of the marinated cooked food, for example, when the duck neck is cut into sections, the cutting angle of the duck neck needs to be adjusted manually, so that the cutting workload of workers is large, and the efficiency is low.

Disclosure of Invention

The invention mainly aims to provide a meat cutting device for food processing, and aims to solve the problems that in the prior art, the cutting angle of a duck neck needs to be adjusted manually, so that the cutting workload of workers is large, and the efficiency is low.

In order to achieve the purpose, the technical scheme provided by the invention is as follows:

a meat cutting device for food processing comprises a rack, a supporting frame, a supporting box, a feed hopper, a through pipe, a transfer channel, a blowing component, a beating component, a vibrating component and a cutting component; the supporting box is arranged on the upper surface of the rack; the supporting frame is arranged on the upper surface of the supporting box; the support frame comprises a first side wall which is vertically arranged; the through pipe is vertically embedded in the first side wall;

the outlet of the feed hopper is in a circular hole shape, and the aperture is a preset aperture; the outlet of the feed hopper is communicated with the top end opening of the through pipe through a corrugated pipe; the transfer channel comprises a supporting plate, an upper cover plate, a first side plate and a second side plate which are arranged oppositely and vertically; the first side plate and the second side plate are in a right trapezoid shape; the supporting plate is connected with the upper surface of the supporting box; the first side plate and the second side plate are both connected to the upper surface of the supporting plate; the upper cover plate is obliquely arranged and connected between the top of the first side plate and the top of the second side plate; the transfer channel is formed with an inlet end and an outlet end;

the cutting assembly comprises a semicircular groove body, a cutter and a driving part; the cutter is arranged right above the semicircular groove body; the cutter is semicircular; the driving part is used for driving the cutter to vertically move and is embedded into the semicircular groove body in a matching manner so as to cut the material in the semicircular groove body;

a discharge long hole is vertically formed in the lower part of the through pipe; the inlet end is connected with the through pipe and communicated with the discharge long hole; the semicircular groove body extends along the horizontal direction, is arranged on the upper surface of the rack and is right opposite to the outlet end;

the vibration component is used for vibrating the feed hopper so as to enable materials to enter the through pipe vertically in sequence; the blowing component is used for blowing the materials positioned at the lowest part of the through pipe so as to enable the materials to be poured and enter the transfer channel; the beating assembly is used for beating the poured materials, so that the poured materials enter the semicircular groove body.

Preferably, the vibration assembly comprises a vibration motor, a first sleeve, a first spring, a connecting rod and a lifting rod; the vertical first sleeve is arranged on the upper surface of the supporting frame; the connecting rod is horizontally connected to the outer wall of the feed hopper; the lifting rod is vertically connected to one end, far away from the feed hopper, of the connecting rod; the lifting rod is matched with the first sleeve and is embedded in the first sleeve in a sliding manner; the first spring is sleeved on the lifting rod; one end of the first spring is connected to the connecting rod, and the other end of the first spring is connected to the top of the first sleeve; the vibration motor is arranged on the outer wall of the vibration motor.

Preferably, the blowing component comprises a rotating arm, a bearing piece, a second sleeve, a stop lever, an air nozzle and an air pump; the supporting box is provided with a groove; the supporting frame is provided with an inner cavity; the bottom end of the through pipe is open and is communicated with the groove; the groove is communicated with the inner cavity; the lower edge of the discharge long hole is aligned with the upper surface of the supporting plate;

the middle part of the rotating arm is hinged with the groove; the rotating surface of the rotating arm is a vertical surface; one end of the rotating arm is connected with the bearing sheet; the supporting sheet can be lifted in the through pipe; the second sleeve is vertically arranged in the inner cavity; the stop lever is vertically embedded in the second sleeve in a sliding manner; the air nozzle is arranged in the inner cavity; the through pipe is provided with an air outlet; the air outlet is positioned in the vertical range of the discharging long hole; the air nozzle is right opposite to the air outlet; the air pump is communicated with the air nozzle; the air injection direction of the air injection nozzle is the horizontal direction;

the lower end of the stop lever is movably contacted with the upper surface of one end of the rotating arm far away from the bearing sheet; the upper end of the stop lever can block the air horizontally sprayed to the air outlet by the air nozzle.

Preferably, the blowing assembly further comprises a baffle and a limiting block; the structure that the upper end of pin can block the air that air nozzle level spouts to the venthole does:

the middle part of the baffle plate is provided with an air hole; the baffle plate is vertically arranged at the top end of the baffle rod; the limiting block is arranged in the groove and is positioned below one end of the rotating arm, which is connected with the bearing piece; under the normal state, the stop lever is downwards abutted against one end of the rotating arm, which is far away from the bearing piece, under the action of self weight, and the air nozzle is blocked by the blocking piece; when the bearing piece is impacted by falling of materials, the rotating arm rotates to be in contact with the top end of the limiting block, and the stop lever moves upwards under the action of the rotating arm, so that the air holes are opposite to the air nozzles, and the air nozzles jet air to the air outlet holes.

Preferably, the air outlet is positioned on the upper part of the vertical range of the discharging long hole.

Preferably, when the rotating arm is contacted with the limiting block, the bearing piece is still higher than the lower edge of the discharging long hole.

Preferably, the striking assembly comprises a proximity sensor, a controller, a striking rod, a fixed seat, a second spring, a first electromagnet and a first retaining ring;

the proximity sensor is arranged on the inner wall of the first side plate close to the supporting plate; the bottom end of the through pipe is provided with a knocking hole; the knocking hole is positioned on the lower part of the discharging long hole in the vertical range; the fixed seat and the second electromagnet are both arranged in the second accommodating cavity; the knocking rod horizontally slides and penetrates through the fixed seat; the first baffle ring is coaxially sleeved on the knocking rod; the second spring is sleeved on the knocking rod; one end of the second spring is connected to the fixed seat; the other end of the second spring is connected to the first baffle ring; one end of the knocking rod can movably penetrate through the knocking hole and extend into the through pipe; the knocking rod is an iron knocking rod; the other end of the knocking rod is horizontally and rightly opposite to the first electromagnetic molten iron; when the first electromagnet is attracted with the knocking rod, the knocking rod does not penetrate through the knocking hole; the second spring is always in a compressed state, and the first baffle ring is positioned between the fixed seat and the through pipe; the proximity sensor is in communication connection with the controller; the controller is used for controlling the starting and stopping of the first electromagnet.

Preferably, a ring is formed at the lower part of the stop lever; the knocking rod movably penetrates through the ring.

Preferably, the cutting assembly further comprises a supporting column, a turnover motor and a rotating shaft; the support column is arranged on the upper surface of the rack and is positioned on one side of the semicircular groove body, which is far away from the support box; two ends of the rotating shaft are respectively and rotatably connected to the supporting column and the supporting box; the rotating shaft is horizontally arranged; the rotating shaft is fixedly connected to the bottom of the semicircular groove body; the overturning motor is connected to the rotating shaft through a speed reducer in a driving mode.

Preferably, the cutting assembly further comprises a support frame; the support frame is arranged on the upper surface of the rack; the driving part is a hydraulic cylinder; the base of the hydraulic cylinder is arranged on the support frame.

Compared with the prior art, the invention at least has the following beneficial effects:

the meat cutting device for food processing provided by the invention can more conveniently cut raw materials (such as duck necks) with longer size, and the specific cutting scheme is as follows: placing a plurality of duck necks in a feed hopper, starting a vibrating motor, enabling the duck necks to enter the through pipe vertically in sequence under the vibration effect of the feed hopper, starting a blowing component when the duck necks slide from the through pipe to the bottommost end, blowing the bottommost duck necks by the blowing component, so that the bottommost duck necks are poured and enter a transfer channel, starting a striking component, striking the poured duck necks by the striking component, so that the poured duck necks enter a containing cavity of a semicircular groove body, and starting a driving part to drive a cutter to move downwards so as to cut the duck necks in the semicircular groove body, so that one-time complete cutting operation is completed; in the process, after the duck neck at the bottommost end is hit and enters the semicircular groove body, the duck neck at the upper part sequentially and automatically falls at the bottommost end of the through pipe, and the steps are repeated, so that continuous cutting is realized.

The meat cutting device for food processing can automatically adjust the angle of the duck neck, does not need to manually adjust the cutting angle of the duck neck, greatly reduces the cutting workload of workers and improves the cutting efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an embodiment of a meat cutting device for food processing according to the present invention (a feeding cover is not shown);

FIG. 2 is an enlarged detail view of the internal structure of FIG. 1 at A;

FIG. 3 is a schematic structural view of a semicircular groove of an embodiment of a meat cutting device for food processing according to the present invention;

FIG. 4 is a schematic structural diagram of a transfer channel of an embodiment of a meat cutting device for food processing according to the present invention;

FIG. 5 is a schematic structural diagram of a stop lever and related components of an embodiment of a meat cutting device for food processing according to the present invention;

fig. 6 is an enlarged detail internal structure diagram at B in fig. 2.

Description of reference numerals:

110-rack, 120-supporting box, 130-supporting frame, 140-through pipe, 150-feeding hopper, 160-corrugated pipe, 170-vibrating motor, 180-connecting rod, 190-lifting rod, 210-first spring, 220-first side wall, 230-transferring channel, 240-supporting plate, 250-first side plate, 260-second side plate, 270-upper cover plate, 280-semicircular groove body, 290-blocking wall, 310-supporting frame, 320-lifting plate, 330-cutter, 340-hydraulic cylinder, 350-supporting column, 360-rotating shaft, 370-collecting barrel, 380-first sleeve, 390-proximity sensor, 410-groove, 420-rotating arm, 430-limiting block, 440-bearing piece, 450-connecting column, 460-stop rod, 470-second sleeve, 480-limit plate, 490-stop sheet, 510-breather hole, 520-ring, 530-air nozzle, 540-discharge long hole, 550-knocking hole, 560-knocking rod, 570-second spring, 580-fixed seat, 590-inner cavity, 610-first electromagnet, 620-stop hole, 630-air outlet hole, 640-stop rod, 650-second stop ring, 660-first stop ring, 670-third spring, 680-stop seat, 690-second electromagnet.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," and the like are to be construed broadly, and for example, "secured" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition, the technical solutions in the embodiments of the present invention may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination of technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The invention provides a meat cutting device for food processing.

Referring to fig. 1 to 6, in an embodiment of a meat cutting device for food processing according to the present invention, the meat cutting device for food processing includes a rack 110, a support frame 130, a support box 120, a feed hopper 150, a duct 140, a transfer passage 230, a blowing component, a striking component, a vibrating component, and a cutting component; the support box 120 is disposed on the upper surface of the stage 110; the support frame 130 is disposed on an upper surface of the support case 120; the support frame 130 includes a first sidewall 220 vertically disposed; the through pipe 140 is vertically embedded in the first sidewall 220.

The outlet of the feed hopper 150 is in a circular hole shape, and the aperture is a preset aperture, wherein the preset aperture is set to only accommodate one duck neck to vertically enter, for example, 3cm, and the aperture of the through pipe 140 is also a preset aperture (namely, 3 cm); the outlet of the feed hopper 150 is communicated with the top end opening of the through pipe 140 through a corrugated pipe 160; the transfer passage 230 includes a support plate 240, an upper cover plate 270, and a first side plate 250 and a second side plate 260 disposed opposite to each other and both disposed vertically; the first side plate 250 and the second side plate 260 have a right trapezoid shape; the supporting plate 240 is connected with the upper surface of the supporting box 120, and the supporting plate 240 is horizontally disposed; the first side plate 250 and the second side plate 260 are both connected to the upper surface of the support plate 240; an upper cover plate 270 is obliquely arranged between the top of the first side plate 250 and the top of the second side plate 260; the transfer channel 230 is formed with an inlet end and an outlet end.

The cutting assembly comprises a semicircular groove body 280, a cutter 330 and a driving part; the cutter 330 is arranged right above the semicircular groove 280; the cutter 330 is in a semi-circular shape, where the vertical cross-section of the inner cavity of the semi-circular groove 280 is in a semi-circular shape, so as to accommodate the material to be cut (e.g. duck neck); the driving part is used for driving the cutter 330 to vertically move and is embedded into the semicircular groove 280 in a matching manner so as to cut materials in the semicircular groove 280, specifically, the number of the cutters 330 is multiple, the lower parts of the cutters 330 are semicircular, the cutters 330 are connected to the lower surface of the lifting plate 320 at equal intervals, the driving part is arranged above the lifting plate 320 and is used for driving the lifting plate 320 to lift, so that the cutters 330 are driven to lift, and the cutters 330 can be embedded into the cavities of the semicircular groove 280 in a matching manner.

The lower part of the through pipe 140 is vertically provided with a discharge long hole 540; the inlet end is connected with the through pipe 140 and is communicated with the discharge long hole 540; the semicircular groove 280 extends horizontally, the semicircular groove 280 is disposed on the upper surface of the rack 110 and is opposite to the outlet end to receive the material from the transfer channel 230, and a blocking wall 290 is formed on one side of the semicircular groove 280 far away from the outlet end to limit the material from the transfer channel 230.

The vibration component is used for vibrating the feed hopper 150 so as to enable the materials to enter the through pipe 140 in sequence; the blowing component is used for blowing the material positioned at the lowest part of the through pipe 140 so that the material is poured and enters the transfer channel 230; the striking assembly is used to strike the material that has been poured so that the material that has been poured enters the semi-circular trough 280.

The meat cutting device for food processing provided by the invention can more conveniently cut raw materials (such as duck necks) with longer size, and the specific cutting scheme is as follows: placing a plurality of duck necks in the feed hopper 150, starting the vibration motor 170, enabling the duck necks to enter the through pipe 140 vertically in sequence under the vibration action of the feed hopper 150, starting the blowing component to blow the duck necks at the bottommost end when the duck necks slide from the through pipe 140 to the bottommost end, so that the duck necks at the bottommost end are poured and enter the transfer channel 230, then starting the striking component to strike the poured duck necks, so that the poured duck necks enter the accommodating cavity of the semicircular groove body 280, then starting the driving component to drive the cutter 330 to move downwards to cut the duck necks in the semicircular groove body 280, thereby completing a complete cutting operation, and in the process, after the duck necks at the bottommost end are struck and enter the semicircular groove body 280, the duck necks falling upwards automatically enter the bottommost end of the through pipe 140 in sequence, and repeating the steps, thereby realizing continuous cutting.

The meat cutting device for food processing can automatically adjust the angle of the duck neck, does not need to manually adjust the cutting angle of the duck neck, can automatically cut along the length direction of the duck neck, greatly reduces the cutting workload of workers and improves the cutting efficiency.

In addition, the vibration assembly includes a vibration motor 170, a first bushing 380, a first spring 210, a connection rod 180, and a lifting rod 190; a vertical first bushing 380 is disposed on an upper surface of the support frame 130; the connecting rod 180 is horizontally connected to the outer wall of the feed hopper 150; the lifting rod 190 is vertically connected to one end of the connecting rod 180 far away from the feed hopper 150; the lifting rod 190 is matched and slidably embedded in the first sleeve 380; the first spring 210 is sleeved on the lifting rod 190; one end of the first spring 210 is connected to the connecting rod 180, and the other end of the first spring 210 is connected to the top of the first sleeve 380; the vibration motor 170 is disposed on an outer wall of the vibration motor 170. Through the technical scheme, the structure and the function of the vibration assembly are perfected.

Meanwhile, the blowing assembly includes a rotation arm 420, a support 440, a second sleeve 470, a blocking lever 460, an air nozzle 530, and an air pump; the supporting box 120 is provided with a groove 410; the supporting frame 130 is provided with an inner cavity 590; the bottom end of the through pipe 140 is open and is communicated with the groove 410; the groove 410 is communicated with the inner cavity 590; the lower edge of the discharge long hole 540 is aligned with the upper surface of the support plate 240.

The middle part of the rotating arm 420 is hinged to the groove 410; the rotating surface of the rotating arm 420 is a vertical surface; one end of the rotating arm 420 is connected with a supporting sheet 440 through a connecting column 450; the support piece 440 can be lifted in the through pipe 140; the second cannula 470 is disposed vertically within the lumen 590; the stop lever 460 is vertically and slidably embedded in the second sleeve 470, wherein the cross section of the stop lever 460 is rectangular, and the cross section of the inner cavity 590 of the second sleeve 470 is also rectangular; the air nozzle 530 is disposed in the inner cavity 590; the through pipe 140 is provided with an air outlet 630; the air outlet 630 is positioned in the vertical range of the discharging long hole 540, and the air outlet 630 is positioned on one side of the through pipe 140 close to the support frame 130; the air nozzle 530 is directly opposite to the air outlet 630; the air pump is communicated with the air nozzle 530; the air blowing direction of the air blowing nozzle 530 is a horizontal direction.

The lower end of the stop lever 460 is movably contacted with the upper surface of one end of the rotating arm 420 far away from the bearing sheet 440; the upper end of the blocking bar 460 blocks the air horizontally sprayed from the air nozzle 530 to the air outlet 630. The air outlet 630 is located at the upper part of the vertical range of the discharging long hole 540.

Through above-mentioned technical scheme, perfect the structure and the function of blowing the subassembly, specifically do: when the duck neck slips from the through pipe 140 and abuts against the bearing plate, under the action of the dead weight of the duck neck, the rotating arm 420 rotates to drive the blocking rod 460 to ascend, so that the blocking rod 460 no longer blocks the air nozzle 530, and air sprayed by the air nozzle 530 blows the upper part of the duck neck through the air outlet 630, so that the duck neck falls down and enters the transfer channel 230, and finally contacts with the upper surface of the supporting plate 240.

In addition, the blowing assembly further comprises a blocking piece 490 and a limiting block 430; the structure of the upper end of the blocking bar 460 capable of blocking the air horizontally jetted from the air nozzle 530 to the air outlet 630 is:

the stop lever 460 is further sleeved with a limiting plate 480, and the limiting plate 480 is located above the second sleeve 470; the middle part of the baffle 490 is provided with a vent 510; the blocking piece 490 is vertically arranged at the top end of the blocking rod 460; the limiting block 430 is arranged in the groove 410 and is positioned below one end of the rotating arm 420, which is connected with the bearing sheet 440; under normal conditions, the stop lever 460 abuts against one end of the rotating arm 420 away from the bearing piece 440 downwards under the action of self weight, and the stop piece 490 stops the air nozzle 530; when the support piece 440 is impacted by the falling of the material, the rotation arm 420 rotates to contact with the top end of the limit block 430, and the blocking rod 460 moves upward under the action of the rotation arm 420, so that the air holes 510 are opposite to the air nozzle 530, and the air nozzle 530 sprays air to the air outlet 630. When the rotating arm 420 contacts the limiting block 430, the supporting piece 440 is still higher than the lower edge of the long discharge hole 540, and the specific size of the supporting piece 440 higher than the long discharge hole 540 is set to be 0.5cm, so as to ensure that the materials can normally enter the transfer channel 230.

Specifically, the working principle is as follows: in a normal state (i.e., when no duck neck abuts against the support piece 440), the blocking rod 460 abuts against one end of the rotating arm 420 away from the support piece 440 downwards under the action of the self weight (at this time, the limiting plate 480 abuts against the second sleeve 470, so that the blocking rod 460 is prevented from falling infinitely, and at this time, the support piece 440 is located at the highest position), at this time, the blocking piece 490 blocks the air nozzle 530, and the air holes 510 are located below the air nozzle 530; when the bearing piece 440 is impacted by the falling of the duck neck, the rotating arm 420 rotates to be in contact with the top end of the limiting block 430, the blocking rod 460 moves upwards under the action of the rotating arm 420, so that the air holes 510 are just opposite to the air nozzles 530, the air nozzles 530 spray air to the air outlet holes 630 through the air holes 510, namely, the duck neck in the through pipe 140 is blown, when the duck neck is hit by the hitting component and enters the semicircular groove 280, the duck neck is not in contact with the bearing piece 440 any more, the bearing piece 440 rises again, and the whole hitting component returns to a normal state again.

Meanwhile, the striking assembly includes a proximity sensor 390, a controller, a striking rod, a fixing seat 580, a second spring 570, a first electromagnet 610, and a first retainer ring 660.

The proximity sensor 390 is disposed at an inner wall of the first side plate 250 near the support plate 240; the near bottom end of the through pipe 140 is provided with a knocking hole 560; the knocking hole 560 is positioned at the lower part of the vertical range of the discharging long hole 540; the fixing seat 580 and the second electromagnet 690 are both disposed in the second cavity; the knocking rod horizontally slides through the fixing seat 580; the first baffle ring 660 is coaxially sleeved on the knocking rod; the second spring 570 is sleeved on the knocking rod; one end of the second spring 570 is connected to the fixing seat 580; the other end of the second spring 570 is connected to the first baffle ring 660; one end of the knocking rod can movably penetrate through the knocking hole 560 and extend into the through pipe 140; the knocking rod is an iron knocking rod; the other end of the knocking rod is horizontally and positively opposite to the first electromagnet 610; when the first electromagnet 610 is attracted to the knocking rod, the knocking rod does not penetrate through the knocking hole 560; the second spring 570 is always in a compressed state, and the first baffle ring 660 is positioned between the fixed seat 580 and the through pipe 140; the proximity sensor 390 is in communication with the controller; the controller is used for controlling the start and stop of the first electromagnet 610.

The structure and the function of beating the subassembly have been perfected through above-mentioned technical scheme, and specific theory of operation does: the first electromagnet 610 is always turned on in a normal state, so that the knocking rod and the first electromagnet 610 are attracted, and the knocking rod does not extend into the through pipe 140; when the duck neck falls and enters the transfer channel 230, the proximity sensor 390 detects that the duck neck is close to the transfer channel, after a delay of a first preset time (such as 0.2 second), the duck neck is horizontally positioned on the upper surface of the supporting plate 240, the controller controls the first electromagnet 610 to be powered off for a second preset time (such as 0.5 second), so that the knocking rod rapidly extends into the through pipe 140 under the action of the first spring 210 and hits the fallen pressing plate, the duck neck enters the semicircular groove 280, and after the knocking is completed, the knocking rod is attracted by the first electromagnet 610 again to restore the normal state.

Meanwhile, a ring 520 is formed at the lower portion of the blocking lever 460; the knocking rod is movably arranged through the ring 520, namely, the stop rod 460 can not interfere the work of the knocking component.

In addition, the meat cutting device for food processing further comprises a stopping component; the stopping assembly includes a stopping rod 640, a stopping block 680, a third spring 670, a second electromagnet 690, and a second stopping ring 650.

The upper end of the through pipe 140 is provided with a stop hole 620; the stop hole 620 is higher than the discharge long hole 540; the stopping seat 680 and the third electromagnet are both arranged in the second cavity; the stop rod 640 horizontally slides through the stop seat 680; the second stop ring 650 is coaxially sleeved on the stop rod 640; the third spring 670 is sleeved on the stopping rod 640; one end of the third spring 670 is connected to the stopping seat 680; the other end of the third spring 670 is connected to the second stopper 650; one end of the stopping rod 640 can movably penetrate through the stopping hole 620 and extend into the through pipe 140; the stopping rod 640 is an iron knocking rod; the other end of the stopping lever 640 is horizontally opposed to the second electromagnet 690; when the second electromagnet 690 is attracted to the stopping rod 640, the stopping rod 640 is not inserted into the stopping hole 620; the third spring 670 is always in a compressed state, and the second stop ring 650 is positioned between the stop seat 680 and the through pipe 140; the controller is also used for controlling the start and stop of the second electromagnet 690; the third spring 670 gives the stop lever 640 a tendency to extend into the tube 140.

Through above-mentioned technical scheme, can guarantee that duck neck cuts in an orderly manner, specific theory of operation is: the second electromagnet 690 is always closed in a normal state, so that the stopping rod 640 extends into the through pipe 140 in the normal state to limit the passed duck neck, and the duck neck is prevented from further falling to be contacted with the bearing sheet 440; when the proximity sensor 390 detects that the duck neck is approaching, and after a third preset time (where the third preset time is the sum of the first preset time, the second preset time and the cutting time, for example, 1.5 seconds), the previous duck neck is hit and enters the semicircular groove 280, and the cutting is completed, the controller controls the second electromagnet 690 to start the fourth preset time (for example, 0.5 seconds), so that the stopping rod 640 and the second electromagnet 690 are attracted, the stopping rod 640 does not limit the duck neck in the through pipe 140, the duck neck falls under the action of the self weight and abuts against the bearing sheet 440, and the cutting operation is continued.

In addition, the cutting assembly further includes a support column 350, a turnover motor (not shown), and a rotation shaft 360; the supporting column 350 is arranged on the upper surface of the rack 110 and is positioned on one side of the semicircular groove 280 away from the supporting box 120; both ends of the rotating shaft 360 are rotatably connected to the supporting column 350 and the supporting box 120, respectively; the rotating shaft 360 is horizontally arranged; the rotating shaft 360 is fixedly connected to the bottom of the semicircular groove 280; the turnover motor is connected to the rotating shaft 360 through a reducer. A discharge hole is formed in the rack 110 below the semicircular groove body 280, and a material collecting barrel 370 is arranged below the discharge hole; through above-mentioned technical scheme, can overturn semi-circular cell body 280 to the duck neck shifts after accomplishing the cutting, and the duck neck that will cut is emptyd through the through-hole and is got into in the collecting bucket 370.

Meanwhile, the cutting assembly further includes a support frame 310; the support frame 310 is disposed on the upper surface of the stand 110; the driving parts are hydraulic cylinders 340, and the number of the hydraulic cylinders 340 is 2; the base of the hydraulic cylinder 340 is disposed on the support frame 310.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.