Meat cutting device

The meat cutting device uses a movable blade and air discharge mechanism to automate the removal of unwanted meat parts, enhancing cutting precision and efficiency by integrating with an industrial robot and detection systems.

WO2026141147A1PCT designated stage Publication Date: 2026-07-02MAYEKAWA MFG CO LTD

Patent Information

Authority / Receiving Office
WO · WO
Patent Type
Applications
Current Assignee / Owner
MAYEKAWA MFG CO LTD
Filing Date
2025-12-18
Publication Date
2026-07-02

AI Technical Summary

Technical Problem

Existing meat cutting devices require manual skill to efficiently remove small bone fragments, fat, and other unwanted parts, and often result in incomplete removal of necessary parts like cartilage, leading to complex and inefficient cutting processes.

Method used

A meat cutting device with a movable blade and air blowing mechanism that sandwiches the cutting target between the blade and a case opening, using air to discharge the cut portion outside, facilitated by an industrial robot and detection systems for precise cutting and discharge.

Benefits of technology

Enables easy and stable cutting of desired meat portions with efficient discharge, reducing manual complexity and improving cutting precision and throughput.

✦ Generated by Eureka AI based on patent content.

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Abstract

This meat cutting device comprises a case, a movable blade (13), and an air blowing device (17A). The case has an opening (11). The movable blade (13) is supported by the case and operates so as to intersect the opening (11). The movable blade (13) pinches a part to be cut of meat with the edge of the opening (11) and cuts the part to be cut. The air blowing device (17A) blows the part to be cut, which has been cut by the movable blade (13), from the inside of the case to the outside together with air.
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Description

Meat cutting device

[0001] The present invention relates to a meat cutting device for cutting a part of meat. This application claims priority based on Japanese Patent Application No. 2024-231774 filed on December 27, 2024, and incorporates its content herein by reference.

[0002] Conventionally, various boning devices have been proposed for boneless meat such as chicken drumsticks, which automate the process from tendon insertion to bone removal (see, for example, Patent Document 1).

[0003] Japanese Patent No. 5331244

[0004] Deboning to remove the main bones from meat with bones can be automatically performed by the above-mentioned boning device. However, small bone fragments, fat, etc. may remain in the meat after deboning. Currently, people are removing these unnecessary parts by holding a cutting tool by hand. However, such removal work of unnecessary parts with a cutting tool is very complicated and requires the skill of the operator to perform the work efficiently. In addition, not only when removing unnecessary parts of meat, but also for necessary parts such as cartilage, people may cut that part with a cutting tool. In such cases, the same problems as in the case of removing unnecessary parts occur.

[0005] An aspect of the present invention provides a meat cutting device that can easily cut a desired part of meat and stably discharge the cut part to the outside.

[0006] The meat cutting device according to the present invention employs the following configuration. That is, the meat cutting device according to an aspect of the present invention includes a case having an opening, and a movable blade that is supported by the case and operates so as to cross the opening, and sandwiches a cutting target part of meat between the movable blade and an edge of the opening to cut the cutting target part, and an air blowing device that blows the cutting target part cut by the movable blade to the outside together with air from the inside of the case.

[0007] When using this meat cutting device to cut a portion of meat, the opening of the case is pressed against the area of ​​meat to be cut. Next, in this state, the movable blade is moved across the opening. This movement of the movable blade causes the blade to grip the portion of meat to be cut between the blade and the edge of the opening, thereby cutting the portion. After the portion to be cut is cut by the movable blade, the cut portion (the cut part) is discharged to the outside by air blowing from an air blower. As a result, the cut portion of the meat is less likely to remain inside the case.

[0008] A meat cutting device according to an aspect of the present invention comprises a case having an opening and a movable blade that operates to cross the opening, and can easily cut the portion of meat to be cut by sandwiching it between the movable blade and the edge of the opening. The meat cutting device according to the present invention further comprises an air blow device that blows the cut portion of the meat out of the case along with air, and can discharge the cut portion of the meat to the outside by blowing air from the air blow device. Therefore, when the meat cutting device according to the present invention is used, it becomes possible to easily cut a desired portion of meat and to stably discharge the cut portion to the outside.

[0009] A perspective view of a meat cutting device of an embodiment mounted on the arm of an industrial robot. A perspective view of a meat cutting device of an embodiment. A bottom view of a meat cutting device of an embodiment. A cross-sectional view of a meat cutting device of an embodiment along the line IV-IV in Figure 3. A cross-sectional view of a movable blade of an embodiment. An enlarged cross-sectional view of the portion of the movable blade of an embodiment corresponding to portion VI in Figure 4. An enlarged cross-sectional view similar to Figure 6 showing the movable blade of an embodiment rotated from its initial position. A cross-sectional view similar to Figure 4 showing the movable blade of an embodiment rotated further. A cross-sectional view similar to Figure 4 showing the movable blade of an embodiment rotated further. An enlarged cross-sectional view of the portion of the movable blade of an embodiment corresponding to portion XI in Figure 10.

[0010] One embodiment of the present invention will be described below with reference to the drawings. The materials, shapes, relative arrangements, etc., of the components described in the following embodiments do not limit the scope of the present invention unless otherwise specifically stated.

[0011] Figure 1 is a perspective view showing the meat cutting device 10 of this embodiment attached to the connecting member 2 of the industrial robot 1. In this embodiment, the industrial robot 1 has multiple links 3 connected via joints 4, and the connecting member 2 is connected to the end link 3 via joints 5. Each joint 4 and 5 has an actuator, such as an electric motor (not shown), built in. Each actuator is controlled by a control device (not shown). The industrial robot 1 is positioned to the side of a conveying device (not shown) from which the meat 6 (see Figures 6 and 7), which is the object to be worked on, is transported. The multiple links 3 and connecting member 2 of the industrial robot 1 move the meat cutting device 10 closer to and further away from the target meat 6 in order to cut and remove the part 7 to be cut from the meat 6 that is transported by the conveying device. The meat 6 is, for example, deboned chicken meat. However, the meat 6 is not limited to chicken meat and may be meat from other livestock. In the case of chicken meat that has been deboned, the parts to be cut 7 are, for example, small bone fragments remaining on the meat 6, as well as fat, blood clots, cartilage, etc.

[0012] Furthermore, prior to the cutting of the target portion 7 by the meat cutting device 10, the posture of the meat 6, which has undergone pre-processing such as deboning, and the position of the target portion 7 are detected by a detection device such as a camera (not shown). The posture of the meat 6 and the position of the target portion 7 detected by the detection device are output to a control device for controlling the operation of the industrial robot 1 and the meat cutting device 10. The operation of the industrial robot 1 and the meat cutting device 10 is controlled by the control device based on the detection results from the above-mentioned detection device.

[0013] <Configuration of the Meat Cutting Device> Figure 2 is a perspective view of the meat cutting device 10, and Figure 3 is a bottom view of the meat cutting device 10. Figure 4 is a cross-sectional view of the meat cutting device 10 along the line IV-IV in Figure 3. The meat cutting device 10 comprises a main body case 12 having a circular opening 11 on one surface, a movable blade 13 rotatably supported in the main body case 12, an air cylinder device 14 for driving the movable blade 13, and a rack and pinion mechanism 15. The meat cutting device 10 also comprises a suction device 16 and air blow devices 17A and 17B, as shown in Figure 4. In this embodiment, the main body case 12 constitutes the case of the meat cutting device 10. In the following description, the side of the main body case 12 where the opening 11 is formed will be referred to as "bottom," and the side opposite to the bottom will be referred to as "top." The opening 11 is formed on the bottom surface of the main body case 12.

[0014] The air cylinder device 14 includes a cylinder 14a through which high-pressure air is supplied and discharged, and a rod 14b protruding outward from one end of the cylinder 14a. The rod 14b moves linearly forward and backward relative to the cylinder 14a by controlling the high-pressure air supplied to and discharged from the cylinder 14a. The cylinder 14a is supported by a main body case 12 via a set of stays 18. The main body case 12 is connected to the connecting member 2 of the industrial robot 1 shown in Figure 1. A plate-shaped bracket 19 is also positioned to the side of the cylinder 14a, extending in a long length along the extension direction of the cylinder 14a and the rod 14b. The bracket 19 is connected to the rod 14b of the air cylinder device 14.

[0015] The bracket 19 has a main body portion 19a that extends parallel to the cylinder 14a from the side of the cylinder 14a, a first bent piece 19b connected to one end of the main body portion 19a in the longitudinal direction, and a second bent piece 19c connected to the other end of the main body portion 19a in the longitudinal direction. The tip of the rod 14b of the air cylinder device 14 is connected to the first bent piece 19b. The support rod 21 that supports the cover 20, which will be described later, is held in the second bent piece 19c. In this embodiment, the air cylinder device 14 constitutes a linear actuator. Hereinafter, the direction in which the rod 14b of the air cylinder device 14 extends will be referred to as the "front-rear direction," and the direction perpendicular to the front-rear direction and the vertical direction will be referred to as the "width direction."

[0016] The rack and pinion mechanism 15 comprises a rack 22 fixed to the main body portion 19a of the bracket 19, and a pinion 24 rotatably connected to the support shaft 23 (see Figure 3) of the movable blade 13. The rack 22 is fixed to the bracket 19 such that multiple teeth are arranged along the front-rear direction. The linear motion of the rod 14b of the air cylinder device 14 is transmitted to the movable blade 13 via the rack and pinion mechanism 15. Specifically, when the rod 14b of the air cylinder device 14 moves back and forth in the front-rear direction due to the supply and discharge of high-pressure air, the rack 22 moves in the front-rear direction together with the bracket 19. At this time, the movable blade 13 rotates within the main body case 12 together with the pinion 24 that meshes with the teeth surface of the rack 22.

[0017] In this embodiment, the rack and pinion mechanism 15 constitutes a rotational conversion mechanism that converts the linear motion of the linear actuator (air cylinder device 14) into rotational motion. In this embodiment, the rack and pinion mechanism 15 is used as the rotational conversion mechanism, but the rotational conversion mechanism is not limited to this. Other mechanisms such as a slider-crank mechanism can also be used as the rotational conversion mechanism, as long as they can convert linear motion into rotational motion.

[0018] The suction device 16 (see Figure 4) is a device for applying suction negative pressure to the opening 11 from the inside of the main body case 12. The suction negative pressure applied to the opening 11 causes the area around the portion of the meat 6 to be cut 7 to be attracted to the opening 11 just before the portion of the meat 6 to be cut by the movable blade 13.

[0019] The air blow device 17A (see Figure 4) is a device for blowing the cut portion 7 of the meat 6, which has been cut by the movable blade 13, from the inside of the main body case 12 to the outside. The air blow device 17B is a device that provides auxiliary air to prevent the cut portion 7 from being sucked into the suction device 16 when the cut portion 7 is blown outwards by the air blow device 17A.

[0020] As shown in Figures 2 and 3, the main body case 12 comprises a movable blade housing block 12A in which the movable blade 13 is housed, and a passage block 12B connected to one end of the movable blade housing block 12A in the front-rear direction.

[0021] Figure 5 is a longitudinal cross-sectional view of the movable blade block 25, in which the support shaft 23 is connected to the movable blade 13. Figure 6 is an enlarged cross-sectional view of the portion of the movable blade 13 (movable blade block 25) corresponding to part VI in Figure 4. Figure 6 shows the opening 11 of the main body case 12 pressed against the area 7 of the meat 6 to be cut. The movable blade housing block 12A is formed in a rectangular shape with a narrow vertical width. As shown in Figure 6, the lower surface of the movable blade housing block 12A is provided with an annular raised portion 26 that rises downward. An annular fixed blade 27 is fixed inside (radially inward) of the raised portion 26. The fixed blade 27 has an edge portion 27e that converges radially inward, and this edge portion 27e is the cutting edge of the fixed blade 27. The circular opening 11 formed on the lower surface of the movable blade housing block 12A is formed by the space inside the raised portion 26 and the fixed blade 27.

[0022] Inside the movable blade housing block 12A, a concave spherical housing section 28 is formed to rotatably house the movable blade 13. Also, as shown in Figures 4 and 6, inside the passage block 12B, a discharge passage 29 is formed for discharging the cut portion 7 of the meat 6 cut by the movable blade 13 to the outside. One end of the discharge passage 29 communicates with the housing section 28 of the movable blade housing block 12A. The movable blade housing block 12A has a second opening 30 that connects the discharge passage 29 and the housing section 28. At the end of the discharge passage 29 opposite to the second opening 30, a third opening 31 is formed that opens to the outside of the passage block 12B. The third opening 31 can be opened and closed by a lid 20. The lid 20 is moved forward and backward by an air cylinder device 14.

[0023] As shown in Figure 4, a relay pipe 32 is connected to the upper part of the passage block 12B. The relay pipe 32 branches into a suction pipe 32a connected to the suction device 16 and an auxiliary blow pipe 32b connected to the air blow device 17B. A filter 90 is interposed in the middle of the suction pipe 32a to prevent foreign objects such as the part of the meat 6 to be cut 7 and meat pieces from being sucked into the suction device 16. The relay pipe 32 is connected to the middle of the discharge passage 29 in the passage block 12B. As a result, the relay pipe 32 and a part of the discharge passage 29 (shared passage section 29a) form a suction passage 33 that connects the suction device 16 and the second opening 30. The suction passage 33 connects the suction device 16 and the second opening 30 by sharing a part of the discharge passage 29 (shared passage section 29a).

[0024] Furthermore, as shown in Figures 4 and 6, a blow pipe 34 is connected to the upper part of the movable blade housing block 12A. The blow pipe 34 forms a blow passage 35 that connects the air blow device 17A and the housing section 28 inside the movable blade housing block 12A. The movable blade housing block 12A has an air blow opening 36 that connects the blow passage 35 and the housing section 28.

[0025] As shown in Figures 5 and 6, the movable blade 13 comprises a spherical support block 37 that is rotatably supported by the movable blade housing block 12A (main body case 12), and a movable blade body 38 that is detachably attached to the support block 37.

[0026] A circular mounting hole 39 is formed in a part of the spherical outer surface of the support block 37, recessed toward the center of the support block 37. A support shaft 23 is also provided protruding from the outer surface of the support block 37. The support shaft 23 protrudes in opposite directions from two positions on the outer surface of the support block 37 such that its axis o1 intersects with the depth direction of the mounting hole 39 and passes through the spherical center of the support block 37. The support shaft 23, together with the movable blade 13 as described above, constitutes the movable blade block 25.

[0027] Furthermore, the portions of the support shaft 23 that protrude in opposite directions from the outer surface of the support block 37 penetrate the side walls on both sides in the width direction of the movable blade housing block 12A (main body case 12), and are rotatably supported by the side walls on both sides in this state. A pinion 24, which constitutes the rack and pinion mechanism 15, is fixed to the end of the support shaft 23 that penetrates one of the side walls.

[0028] The movable blade body 38 comprises a cylindrical tubular wall 40 that fits into a mounting hole 39 of the support block 37, and a bottom wall 41 that is connected to one end of the tubular wall 40 in the axial direction. A circular through hole 47 is formed in the center of the bottom wall 41, penetrating the bottom wall 41 in the thickness direction. The end face on the other end of the tubular wall 40 in the axial direction protrudes outward from the mounting hole 39 when the tubular wall 40 is mounted in the mounting hole 39. This end face of the tubular wall 40 is curved so as to form a spherical shape that is continuous with the spherical outer surface of the support block 37 when the tubular wall 40 is mounted in the mounting hole 39.

[0029] Here, the opening on the inner circumference of the cylindrical wall 40 is referred to as the "main body opening 40a." The end face of the other end of the cylindrical wall 40 forms a spherical shape from the radially outer side to the inner side, and at the intersection with the main body opening 40a, it forms an acute-angled edge portion 40e. This edge portion 40e is connected in an annular shape along the main body opening 40a, forming an annular cutting edge. Hereinafter, this edge portion 40e of the cylindrical wall 40 will be referred to as the "cutting edge 40e." The spherical outer surface of the support block 37 and the aforementioned end face (including the cutting edge 40e) of the cylindrical wall 40 that is continuous with that outer surface move in sliding contact with or close proximity to the fixed blade 27 that forms the edge of the opening 11 when the movable blade 13 rotates around the axis o1.

[0030] Figure 7 is an enlarged cross-sectional view similar to Figure 6, showing the movable blade 13 after it has rotated in one direction from the initial position shown in Figure 6. In this embodiment, when the movable blade 13 cuts the portion of meat 6 to be cut 7, it rotates in a counterclockwise direction as shown in Figure 7. In the initial position shown in Figure 6, the cutting edge 40e of the movable blade body 38 is recessed inside the raised portion 26 of the movable blade housing block 12A (main body case 12) (it does not protrude outside the raised portion 26). When the entire movable blade 13 rotates in one direction around the axis o1 from this state, the cutting edge 40e of the movable blade body 38 moves in an arc across the opening 11, as shown in Figure 7, and approaches the edge portion 27e of the fixed blade 27 (a part of the edge of the opening 11). As the rotation of the movable blade 13 progresses further, the cutting edge 40e of the movable blade body 38 slides against or approaches the edge portion 27e of the fixed blade 27 positioned in the opening 11. At this time, as shown in Figure 7, if the opening 11 is pressed against the area 7 of the meat 6 to be cut, the area 7 will be caught between the cutting edge 40e of the movable blade 13 and the edge portion 27e of the fixed blade 27, and will be cut away from the main body of the meat 6.

[0031] Incidentally, the movable blade body 38, which is fitted into the mounting hole 39 of the support block 37, is detachably fixed to the bottom of the mounting hole 39 by a plurality of bolts 42, which are fastening members, as shown in Figures 5 and 6. Inside the body opening 40a of the movable blade body 38, a predetermined number of plate-shaped spacers 43 are housed to adjust the depth width within the body opening 40a of the movable blade body 38. The spacers 43, together with the bottom wall 41 of the movable blade body 38, are fastened and fixed to the bottom of the mounting hole 39 by a plurality of bolts 42. When arranging a plurality of spacers 43 inside the cylindrical wall 40, the plurality of spacers 43 overlapping in the thickness direction are placed on the bottom wall 41 of the movable blade body 38 and fixed to the bottom of the mounting hole 39 by bolts 42. The number of spacers 43 arranged inside the cylindrical wall 40 can be appropriately increased or decreased according to the depth width within the body opening 40a required by the movable blade body 38. Furthermore, if the number of spacers 43 placed inside the cylindrical wall 40 is increased to narrow the depth of the opening 40a of the main body (making the depth shallower), the cutting position of the part of the meat 6 to be cut 7 can be made shallower. Conversely, if the number of spacers 43 placed inside the cylindrical wall 40 is decreased to widen the depth of the opening 40a of the main body (making the depth deeper), the cutting position of the part of the meat 6 to be cut 7 can be made deeper.

[0032] As shown in Figures 5 and 6, the support block 37 has an air passage 44 formed therein, one end of which opens into a part of the spherical outer surface of the support block 37, and the other end which communicates with the inside of the cylindrical wall 40 of the movable blade body 38 (body opening 40a). The air passage 44 has a flow groove 44a formed at the bottom of the mounting hole 39 of the support block 37, and a supply and discharge hole 44d connected to the flow groove 44a. The supply and discharge hole 44d extends linearly from the end of the flow groove 44a in a direction perpendicular to the depth direction of the mounting hole 39, and its extended end opens into the outer surface of the support block 37. Reference numeral 45 in Figure 6 indicates the opening of the supply and discharge hole 44d that opens into the outer surface of the support block 37. In addition, a circular air supply and discharge hole 48 is formed in the center of each spacer 43 placed in the mounting hole 39. The air supply and exhaust holes 48 communicate with the air passage 44 on the support block 37 side through the through-hole 47 of the bottom wall 41 when the spacer 43 is fixed to the bottom wall 41 of the mounting hole 39. The air passage 44 communicates with the opening 11 side through the through-hole 47 and the air supply and exhaust holes 48.

[0033] In the following explanation, the rotation direction of the movable blade 13 when cutting the portion 7 of the meat 6 will be referred to as the "forward rotation direction." Here, as shown in Figure 6, the opening 45 of the air passage 44 formed on the outer circumferential surface of the support block 37 is located approximately 270° away from the body opening 40a of the movable blade body 38 in the forward rotation direction of the movable blade 13 (counterclockwise direction in Figure 6). Conversely, if we consider the body opening 40a of the movable blade body 38 as the center, the body opening 40a is located approximately 90° away from the opening 45 of the air passage 44 in the forward rotation direction of the movable blade 13 (counterclockwise direction in Figure 6).

[0034] In contrast, the second opening 30 formed in the movable blade housing block 12A (main body case 12) is positioned approximately 270° away from the opening 11 on the lower surface of the movable blade housing block 12A in the forward rotation direction of the movable blade 13 (counterclockwise direction in Figure 6). Therefore, as shown in Figure 6, when the cutting edge 40e of the movable blade 13 is facing the meat 6 (the cutting edge 40e of the movable blade 13 is facing downwards), the air passage 44 formed in the support block 37 of the movable blade 13 connects the second opening 30 to the opening 11 on the lower surface of the movable blade housing block 12A. At this time, as shown in Figure 4, if the second opening 30 is airtightly connected to the suction passage 33, the suction negative pressure of the suction device 16 acts on the opening 11 from the inside of the movable blade housing block 12A (main body case 12). Therefore, as shown in Figure 6, if the opening 11 of the movable blade housing block 12A is pressed against the periphery of the portion of meat 6 to be cut 7, the suction negative pressure acting inside the opening 11 will draw the portion of meat 7 and its periphery towards the opening 11.

[0035] Figures 8, 9, and 10 are cross-sectional views similar to Figure 4, sequentially showing the state of each part when the movable blade 13 rotates in the forward direction from the initial state shown in Figure 4. Figure 11 is an enlarged cross-sectional view of the part corresponding to section XI in Figure 10. As shown in Figure 11, the second opening 30 in the movable blade housing block 12A is located at a position approximately 90° away from the air blowing opening 36 on the upper surface of the movable blade housing block 12A in the forward rotation direction of the movable blade 13 (counterclockwise direction in Figure 11). Therefore, as shown in Figure 11, when the cutting edge 40e of the movable blade 13 is facing the second opening 30, the air passage 44 formed in the support block 37 of the movable blade 13 connects the air blowing opening 36 to the second opening 30 in the movable blade housing block 12A. At this time, as shown in Figures 10 and 11, the air supplied from the air blow device 17A is blown out towards the second opening 30 through the air blowing opening 36 and the air passage 44. The air flowing from the air passage 44 toward the second opening 30 is blown onto the cutting edge 40e of the movable blade 13 and its surrounding area. Therefore, if the part of the meat 6 to be cut 7 or pieces of meat are attached to the cutting edge 40e of the movable blade 13 or its surrounding area, the part of the meat to be cut 7 or pieces of meat will be blown out by the air toward the discharge passage 29.

[0036] In this embodiment, the opening 11 communicating with the housing section 28 within the movable blade housing block 12A, the air blowing opening 36, and the second opening 30 are positioned as follows around the axis o1 of the rotating movable blade 13. The air blowing opening 36 is positioned approximately 180° away from the opening 11 in the forward rotation direction of the movable blade 13. The second opening 30 is positioned approximately 90° away from the air blowing opening 36 in the forward rotation direction of the movable blade 13, and approximately 270° away from the opening 11 in the forward rotation direction of the movable blade 13.

[0037] Furthermore, the aforementioned air cylinder device 14 and rack-and-pinion mechanism 15 constitute an interlocking drive unit 50 (see Figures 2 and 3) that drives the rotational movement of the movable blade 13 and the opening and closing movement of the lid 20 relative to the third opening 31 in conjunction. The interlocking drive unit 50 moves the lid 20 to open and close in synchronization with the rotational movement of the movable blade 13. However, due to the function of the coil spring 51 described later, the interlocking drive unit 50 is set so that the rotational movement of the movable blade 13 and the movement of the lid 20 are not synchronized from the initial position for a certain operating stroke.

[0038] The cover 20 is connected to the support rod 21. The support rod 21 is supported by the second bent piece 19c of the bracket 19. A rod holding portion 72 is connected to the second bent piece 19c, which slidably holds the support rod 21 (slidably in the axial direction). The cover 20 is connected to one end of the support rod 21 held by the rod holding portion 72, which faces the end face (third opening 31) of the passage block 12B. A stopper flange 73 is provided at the other end of the support rod 21, which protrudes radially outward from the support rod 21. The end face of the rod holding portion 72 comes into contact with the stopper flange 73 when the rod holding portion 72 moves a predetermined distance or more from the initial position shown in Figure 4 toward the side away from the passage block 12B together with the bracket 19. As the rod holder 72 moves in the same direction after the end face of the rod holder 72 comes into contact with the stopper flange 73, the support rod 21 is pushed by the rod holder 72 and moves away from the passage block 12B (third opening 31), as shown in Figure 8.

[0039] Furthermore, a coil spring 51 is interposed between the rod holding portion 72 and the lid 20, biasing the lid 20 together with the support rod 21 toward the end face of the passage block 12B (third opening 31). The coil spring 51 constitutes a biasing portion that biases the lid 20 toward the closing direction (the direction that closes the third opening 31).

[0040] Here, the coil spring 51 continues to bias the lid 20 in the closing direction (the direction in which the third opening 31 is closed) until the rod holding portion 72 moves a predetermined distance or more away from the passage block 12B from the initial position shown in Figure 4. For this reason, until the rod holding portion 72 moves a predetermined distance or more away from the passage block 12B from the initial position, the lid 20 continues to maintain the closed state of the third opening 31 without being linked to the operation of the air cylinder device 14. Therefore, in the interlocking drive unit 50 of this embodiment, the rotational operation of the movable blade 13 and the operation of the lid 20 are not synchronized for a certain operating stroke from the initial position.

[0041] The movable blade 13 is linked to the air cylinder device 14 (linear actuator) via a rack and pinion mechanism 15, which is a rotational conversion mechanism. In contrast, the lid 20 is linked to the air cylinder device 14 (linear actuator) without going through the rack and pinion mechanism 15, which is a rotational conversion mechanism.

[0042] When the movable blade 13 cuts the portion of the meat 6 to be cut, the interlocking drive unit 50 switches the open / closed state of the lid 20 and the communication state of the air passage 44 as follows: (1) When the movable blade 13 is facing the meat in its initial position, the lid 20 closes the third opening 31, and the air passage 44 of the movable blade 13 allows communication between the suction passage 33 and the opening 11 via the second opening 30. (2) After the movable blade 13 has cut the portion of the meat 6 to be cut 7, the lid 20 opens the third opening 31, and the air passage 44 allows communication between the air blowing opening 36 and the discharge passage 29 via the second opening 30.

[0043] <Operation of the meat cutting device> Next, the operation of the meat cutting device 10 will be described. When the meat 6 that has undergone pre-treatment such as boning is conveyed by the conveying device, the industrial robot 1 operates to bring the meat cutting device 10 close to the meat 6. At this time, as shown in FIG. 6, the movable blade 13 is in the initial state where the blade tip 40e faces downward, and the air flow passage 44 of the movable blade 13 communicates with the opening 11 on the lower surface of the main body case 12 through the second opening 30 and the main body opening 40a of the movable blade main body 38. Also, at this time, the air cylinder device 14 projects the rod 14b to the front end portion, and presses the lid body 20 against the third opening 31 via the bracket 19, the rod holding portion 72, and the coil spring 51. At this time, the coil spring 51 interposed between the rod holding portion 72 and the lid body 20 is compressed. As a result, the end portion of the discharge passage 29 in the passage block 12B is sealed by the lid body 20. In this state, as shown in FIG. 4, when the suction device 16 operates, the suction negative pressure of the suction device 16 acts on the opening 11 on the lower surface of the main body case 12 through the suction passage 33 and the air flow passage 44 in the movable blade 13.

[0044] In this state, by further operation of the industrial robot 1, as shown in FIG. 6, the opening 11 on the lower surface of the main body case 12 is pressed against the periphery of the cutting target portion 7 of the meat 6. At this time, since the negative pressure by the suction device 16 acts inside the opening 11, the cutting target portion 7 of the meat 6 and its periphery are sucked inside the opening 11. As a result, the cutting target portion 7 of the meat 6 bulges into the opening 11.

[0045] Next, the rod 14b of the air cylinder device 14 moves in the retraction direction (towards being housed in the cylinder 14a). As a result, the bracket 19 retracts together with the rod 14b, and the movable blade 13 rotates in one direction via the rack and pinion mechanism 15. At this time, when the bracket 19 and the rod holder 72 move beyond a predetermined distance from their initial positions, the rod holder 72 comes into contact with the stopper flange 73 of the support rod 21, and as shown in Figure 8, the cover 20 begins to open the third opening 31. As a result, the pressure in the common passage portion 29a of the discharge passage 29 rapidly approaches atmospheric pressure. Note that until the bracket 19 and the rod holder 72 move beyond a predetermined distance from their initial positions, the common passage portion 29a remains sealed, and the suction negative pressure from the suction device 16 acts through the common passage portion 29a towards the movable blade 13.

[0046] Thus, when the movable blade 13 begins to rotate from the initial position shown in Figure 6, the cutting edge 40e of the movable blade 13 moves in an arc shape across the opening 11 and comes into contact with the vicinity of the base of the part of the meat 6 to be cut 7. As the rotation of the movable blade 13 progresses, as shown in Figure 7, the cutting edge 40e of the movable blade 13 sandwiches the part of the meat 7 between itself and the edge 27e of the fixed blade 27, and cuts the part of the meat 7 from the main body of the meat 6. At this time, the cut part of the meat 7 remains inside the opening 40a of the movable blade body 38 of the movable blade 13.

[0047] Subsequently, as the rod 14b of the air cylinder device 14 moves further in the retraction direction, the movable blade 13 rotates further as shown in Figures 8 and 9, and the lid 20 moves further away from the third opening 31. In this way, as the retraction of the rod 14b progresses further, and as shown in Figures 10 and 11, the cutting edge 40e of the movable blade 13 faces the second opening 30, the air blowing opening 36 on the upper surface of the main body case 12 comes into communication with the second opening 30 via the air passage 44 of the movable blade 13.

[0048] At this time, as shown in FIG. 10, the air blow devices 17A and 17B start operating. The high-pressure air supplied from the air blow device 17A is blown onto the cutting edge 40e of the movable blade 13 and the vicinity thereof through the air flow passage 44 in the movable blade 13. As a result, foreign matters such as the cutting target portion 7 and pieces of meat remaining on the cutting edge 40e of the movable blade 13 and around it are discharged to the outside from the third opening 31 through the discharge passage 29 by the blowing of the air. At this time, the lid 20 is sufficiently separated from the third opening 31 toward the rear side so as not to prevent the discharge of foreign matters from the third opening 31. Further, the high-pressure air supplied from the air blow device 17B at this time is blown out to the confluence portion with the discharge passage 29 through the auxiliary blow pipe 32b. Thereby, it is possible to suppress the foreign matters blown in the direction of the third opening 31 through the second opening 30 from being sucked by the suction device 16.

[0049] After that, the rod 14b of the air cylinder device 14 operates in the protruding direction, and the rod 14b is returned to the initial position. At this time, the bracket 19 moves in the protruding direction together with the rod 14b, and the movable blade 13 rotates in the reverse direction via the rack and pinion mechanism 15. As a result, the movable blade 13 is returned to the initial position. Further, the lid 20 closes the third opening 31 as the bracket 19 operates in the protruding direction.

[0050] <Effect of the meat cutting device according to the embodiment> The meat cutting device 10 according to the present embodiment includes a main body case 12 (case) having an opening 11 and a movable blade 13 that operates so as to cross the opening 11, and sandwiches the cutting target portion 7 of the meat 6 between the movable blade 13 and the fixed blade 27 (the edge of the opening 11), whereby the cutting target portion 7 can be easily cut. Further, the meat cutting device 10 according to the present embodiment further includes an air blow device 17A that blows out the cut portion (the cutting target portion 7, pieces of meat, etc.) of the meat 6 from the inside of the main body case 12 to the outside together with air, and the cut portion of the meat 6 can be discharged to the outside by the blowing of the air by the air blow device 17A. Therefore, when the meat cutting device 10 according to the present embodiment is adopted, it is possible to easily cut a desired portion of the meat 6 and stably discharge the cut portion to the outside.

[0051] Furthermore, in this embodiment of the meat cutting device 10, the movable blade 13 is rotatable around an axis o1 perpendicular to the depth direction of the opening 11, and the main body case 12 (case) is provided with a housing 28 for the movable blade 13, an opening 11, an air blowing opening 36, and a second opening 30. The air blowing opening 36 is connected to a blowing passage 35, and the movable blade 13 is provided with an air flow passage 44 that allows the flow of blown air through the cutting edge 40e of the movable blade 13. Therefore, when the movable blade 13 rotates to a predetermined position after the movable blade 13 has cut the part of the meat 6 to be cut 7, air can be blown to the cutting edge 40e of the movable blade 13 through the air flow passage 44 inside the movable blade 13. Therefore, when the meat cutting device 10 of this embodiment is used, the cutting target portion 7 (cut portion) attached to the movable blade 13 and its surroundings can be suitably discharged by air blown from inside the movable blade 13.

[0052] Furthermore, in the meat cutting device 10 of this embodiment, a second opening 30 is provided that communicates with a discharge passage 29, separate from the opening 11 that cuts the part to be cut 7 in cooperation with the movable blade 13. When the cutting edge 40e of the movable blade 13 is facing the second opening 30, air is allowed to flow from the air blowing opening 36 to the second opening 30 via the cutting edge 40e of the movable blade 13. As a result, the part to be cut 7 and meat pieces can be discharged to the outside through the second opening 30 and the discharge passage 29 without having to move the meat cutting device 10 to a discharge-only position far away from the meat cutting position 6. Therefore, if the meat cutting device 10 of this embodiment is adopted, it becomes possible to shorten the cycle time of the meat processing work.

[0053] Furthermore, the meat cutting device 10 of this embodiment further comprises a suction device 16, a suction passage 33, a third opening 31, a lid 20, and an interlocking drive unit 50. The suction passage 33 connects the suction device 16 and the second opening 30 by sharing a part of the discharge passage 29, and the third opening 31 is formed at the end of the discharge passage 29 opposite to the second opening 30. The interlocking drive unit 50 opens and closes the lid 20 in synchronization with the operation of the movable blade 13. When the movable blade 13 is facing the meat 6, the lid 20 closes the third opening 31, and the air flow passage 44 allows communication between the suction passage 33 and the opening 11 via the second opening 30. After the movable blade 13 has cut the portion to be cut 7, the lid 20 opens the third opening 31, and the air flow passage 44 allows communication between the air blowing opening 36 via the second opening 30 and the discharge passage 29. Therefore, in the meat cutting device 10 of this embodiment, the operations from suction of the meat 6 to be cut 7 and its surroundings at the opening 11, cutting of the meat 6 to be cut 7 by the movable blade 13, blowing away foreign matter from the movable blade 13, and discharging foreign matter from the main body case 12 can be smoothly performed by the function of the interlocking drive unit 50.

[0054] Furthermore, in the meat cutting device 10 of this embodiment, the movable blade 13 comprises a support block 37 having a mounting hole 39 on its outer surface, and a movable blade body 38 that is detachably attached to the support block 37. The movable blade body 38 has a cylindrical wall 40 that is fitted into the mounting hole 39, and a cutting edge 40e is formed at the end of the cylindrical wall 40 that protrudes to the outside of the mounting hole 39. The support block 37 is provided with an air passage 44, one end of which opens to a part of the outer surface of the support block 37, and the other end which communicates with the inside of the cylindrical wall 40 of the movable blade body 38. In the meat cutting device 10 of this embodiment, since the movable blade body 38 with the cutting edge 40e is detachably attached to a separate support block 37, an air passage 44 can be easily formed between the movable blade body 38 and the separate support block. Furthermore, since the meat cutting device 10 of this embodiment has a structure in which the movable blade body 38 is detachably attached to the support block 37, the movable blade body 38 can be removed from the support block 37 and replaced with another movable blade body 38 during maintenance. Also, during maintenance, the movable blade body 38 can be removed from the support block 37 and the cutting edge 40e of the movable blade body 38 can be cleaned.

[0055] It should be noted that the present invention is not limited to the embodiments described above, and various design modifications are possible without departing from the spirit of the invention. For example, in the above embodiment, the movable blade 13 is configured to include a support block 37 having a mounting hole 39 and a movable blade body 38 that is detachably attached to the mounting hole 39, but the movable blade may be constructed as a single, integrated block.

[0056] Furthermore, in the above embodiment, the main body case 12 (case) is provided with a second opening 30 separate from the opening 11 used for cutting the target portion 7 in cooperation with the movable blade 13, and the second opening 30 is in communication with the discharge passage 29. However, the main body case 12 (case) may be provided without the second opening 30, and air may be blown from inside the movable blade to the cutting edge of the movable blade, thereby discharging the cut target portion 7, etc., to the outside through the same opening 11.

[0057] Furthermore, in the above embodiment, a movable blade 13 (support block 37) with a spherical outer surface is used, but the shape of the outer surface of the movable blade 13 is not limited to a spherical shape. The outer surface shape of the movable blade may be, for example, cylindrical. In this case, the movable blade will rotate about the central axis of the cylinder.

[0058] Furthermore, in the above embodiment, the air blowing opening 36 is positioned approximately 180° away from the opening 11 in the forward rotation direction of the movable blade 13, and the second opening 30 is positioned approximately 90° away from the air blowing opening 36 in the forward rotation direction of the movable blade 13. However, the arrangement of the air blowing opening 36 and the second opening 30 is not limited to this. The air blowing opening 36 and the second opening 30 can be positioned at any position as long as they are spaced apart from the opening 11 in the rotation direction of the movable blade 13.

[0059] Furthermore, in the above embodiment, a portion of the discharge passage 29 (shared passage portion 29a) is shared with the suction passage 33. However, the configuration of the discharge passage 29 and the suction passage 33 is not limited to this. The discharge passage 29 and the suction passage 33 may each be independent passages. However, when a portion of the discharge passage 29 (shared passage portion 29a) is shared with the suction passage 33, as in this embodiment, the volume occupied by the passage within the main body case 12 can be reduced, and the main body case 12 can be made smaller.

[0060] Furthermore, in the above embodiment, the operation of the movable blade 13 and the opening and closing operation of the lid 20 are linked by the interlocking drive unit 50. However, the movable blade 13 and the lid 20 may be operated by different actuators.

[0061] Furthermore, in the above embodiment, the lid 20 that opens and closes the third opening 31 is structured to open and close linearly in front of the third opening 31, but the structure of the lid is not limited to this. The lid may, for example, be structured to rotate by a hinge.

[0062] Furthermore, in the above embodiment, the movable blade 13 is configured to be rotated around the axis o1, but the movable blade may also be configured to move linearly along the bottom surface of the case so as to cross the opening of the case.

[0063] 6...Meat 7...Part to be cut 10...Meat cutting device 11...Opening 12...Main body case (case) 13...Movable blade 14...Air cylinder device (linear actuator) 16...Suction device 17A...Air blow device 20...Lid 28...Storage section 29...Discharge passage 30...Second opening 31...Third opening 33...Suction passage 35...Blow-out passage 36...Opening for air blow-out 37...Support block 38...Movable blade body 39...Mounting hole 40...Cylindrical wall 40e...Blade tip 44...Air flow passage 50...Interlocking drive unit o1...Axis

Claims

1. A meat cutting device comprising: a case having an opening; a movable blade supported by the case and moving across the opening, which sandwiches the portion of meat to be cut between itself and the edge of the opening and cuts the portion to be cut; and an air blow device that blows out the portion to be cut by the movable blade from the inside of the case along with air to the outside.

2. The meat cutting device according to claim 1, characterized in that the movable blade is rotatable about an axis perpendicular to the depth direction of the opening, the case comprises a housing portion for rotatably housing the movable blade, the opening communicating with the housing portion, and an air blowing opening communicating with the housing portion at a position spaced apart from the opening about the axis, the air blowing opening is connected to a blowing passage communicating with the air blowing device, and the movable blade is provided with an air passage that allows air to flow from the air blowing opening through the cutting edge of the movable blade.

3. The meat cutting device according to claim 2, wherein the case further comprises a second opening communicating with the housing at a position spaced apart from the opening and the air blowing opening around the axis, and a discharge passage for discharging the portion to be cut by the movable blade to the outside, the second opening being connected to the discharge passage, and the air passage allowing air to flow from the air blowing opening to the second opening via the cutting edge when the cutting edge of the movable blade is facing the second opening.

4. The meat cutting apparatus according to claim 3, further comprising: a suction device that generates suction negative pressure; a suction passage that connects the suction device and the second opening by sharing a part of the discharge passage; a third opening provided at the end of the discharge passage opposite to the second opening; and a lid that can open and close the third opening.

5. The meat cutting device according to claim 4, further comprising an interlocking drive unit that opens and closes the lid in synchronization with the movement of the movable blade, wherein the interlocking drive unit, when the movable blade is facing the meat, closes the lid and allows the air passage to communicate with the suction passage via the second opening and the opening, and after the movable blade has cut the part to be cut, opens the lid and allows the air passage to communicate with the air blowing opening via the second opening and the discharge passage.

6. The meat cutting device according to claim 2, wherein the movable blade comprises a support block having a mounting hole on its outer surface and being rotatably supported by the case, and a movable blade body having a cylindrical wall that is mounted in the mounting hole, and a cutting edge formed at the end of the cylindrical wall that protrudes outward from the mounting hole, the movable blade body being detachably attached to the support block, and the support block being provided with the air passage such that one end opens to a part of the outer surface of the support block and the other end communicates with the inside of the cylindrical wall of the movable blade body.