阅读说明：本技术 一种生产线物品自动装箱机 (Automatic container loader for production line articles ) 是由 吴海波 崔禹 王晨 熊彬州 刘亮 魏顺祥 周光勋 于 2020-06-17 设计创作，主要内容包括：本发明公开了一种生产线物品自动装箱机,包括：包装箱输入辊筒线Ⅰ用于将包装箱输入至包装箱定位转向装置；产品输出辊筒线Ⅱ用于将装箱后物品输出；设备框架用于固定三自由度安装架；三自由度安装架用于带动安装在其上的装箱机械手进行六个方向的直线运动；装箱机械手用于抓取循环倍速链上的待装箱物品,用于将待装箱物品放至包装箱；托盘换向装置用于将循环倍速链上层输送来的空托盘传至循环倍速链下层；包装箱定位转向装置用于接收包装箱输入辊筒线Ⅰ输入的包装箱,用于将装箱后物品输送至产品输出辊筒线Ⅱ；循环倍速链用于待装箱物品的输送和空托盘的回收。本发明通过机械控制的方式实现了物品的装箱,并进一步在装箱的同时实现了空托盘的回收。(The invention discloses an automatic container loader for production line articles, which comprises: the packing box input roller line I is used for inputting the packing box to the packing box positioning and steering device; the product output roller line II is used for outputting the boxed articles; the equipment frame is used for fixing the three-degree-of-freedom mounting rack; the three-degree-of-freedom mounting rack is used for driving the boxing manipulator arranged on the three-degree-of-freedom mounting rack to perform linear motion in six directions; the boxing manipulator is used for grabbing objects to be boxed on the circulating speed multiplying chain and placing the objects to be boxed into a packaging box; the tray reversing device is used for transferring the empty trays conveyed from the upper layer of the circulating speed multiplying chain to the lower layer of the circulating speed multiplying chain; the packing box positioning and steering device is used for receiving a packing box input by the packing box input roller line I and conveying packed articles to the product output roller line II; the circulating speed multiplication chain is used for conveying the objects to be boxed and recovering empty pallets. The invention realizes the boxing of the articles in a mechanical control mode, and further realizes the recovery of the empty trays while boxing.)

1. The utility model provides an automatic case packer of production line article which characterized in that: the packaging box automatic loading and unloading device comprises a packaging box input roller line I (1-1), a product output roller line II (1-2), an equipment frame (2), a three-degree-of-freedom mounting rack (3), a packaging box manipulator (4), a tray reversing device (5), a packaging box positioning and steering device (6) and a circulating speed-multiplying chain (7);

the packing box input roller line I (1-1) is used for inputting the packing box (135) to the packing box positioning and steering device (6);

the product output roller line II (1-2) is used for outputting the packed articles input by the packing box positioning and steering device (6);

the equipment frame (2) is used for fixing the three-degree-of-freedom mounting rack (3);

the three-degree-of-freedom mounting rack (3) is used for driving the boxing manipulator (4) mounted on the three-degree-of-freedom mounting rack to perform linear motion in six directions;

the boxing manipulator (4) is used for grabbing the articles (133) to be boxed on the circulating speed-multiplying chain (7) and placing the articles (133) to be boxed into the packing boxes (135) on the packing box positioning and steering device (6);

the tray reversing device (5) is used for transferring the empty trays (134) conveyed from the upper layer of the circulating speed-multiplying chain (7) to the lower layer of the circulating speed-multiplying chain (7);

the packing box positioning and steering device (6) is used for receiving a packing box (135) input by the packing box input roller line I (1-1) and conveying packed articles to the product output roller line II (1-2);

the circulating speed multiplication chain (7) is used for conveying the objects (133) to be boxed and recovering the empty trays (134).

2. The automatic case packer of production line articles as claimed in claim 1, wherein: the packing box input roller line I (1-1) and the product output roller line II (1-2) are identical in structure and respectively comprise a chain wheel roller (8), a welding plate (9), a driving chain wheel (10), a chain (11), a speed reducing motor I (12), a motor mounting seat I (13), a line body cross beam (14), a ground foot I (15), a roller mounting support (16), an upright column connecting beam I (17), an upright column I (18), a driven chain wheel (19) and a bearing (20); wherein the welding plate (9) is fixed on the end ports of a line body cross beam (14), an upright post connecting beam I (17) and an upright post I (18), the line body cross beam (14) and the upright post connecting beam I (17) are combined into a roller line body, one end of the upright post I (18) is respectively fixed with a foot margin I (15), 2 roller installation supports (16) are fixed on the other end of the upright post I (18) and are arranged in parallel with the 2 roller installation supports (16), a plurality of chain wheel rollers (8) are installed among the 2 roller installation supports (16) and have the axes vertical to the roller installation supports (16), one end of the chain wheel roller (8) is provided with a driven chain wheel (19) through a bearing (20), the driven chain wheel (19) on the chain wheel roller (8) are connected through a chain (11), a speed reducing motor I (12) is fixed on the line body cross beam (14) through a motor, the driving chain wheel (10) is arranged on an output shaft of the speed reducing motor I (12), and the driving chain wheel (10) transmits power to a driven chain wheel (19) of the chain wheel roller (8) through a chain (11).

3. The automatic case packer of production line articles as claimed in claim 1, wherein: the three-degree-of-freedom mounting rack (3) is used for providing power to drive gears on two output shafts of the double-output-shaft speed reducer (44) to be meshed with racks on the corresponding parallel beam (39) through the servo motor I (41-1), so that a boxing manipulator (4) mounted on the three-degree-of-freedom mounting rack (3) moves along the parallel beam (39); the servo motor III (41-3) provides power to drive a gear on an output shaft of the servo motor III to be meshed with a rack on a corresponding cross beam (34), so that the boxing manipulator (4) moves along the cross beam (34); the servo motor II (41-2) is used for providing power to drive a gear on an output shaft of the servo motor II to be meshed with a rack on a corresponding vertical beam (46), so that the boxing manipulator (4) moves along the vertical beam (46).

4. The automatic case packer of production line articles as claimed in claim 1, wherein: the three-degree-of-freedom mounting rack (3) comprises a vertical beam sliding block protective cover (30), a guide rail I (31-1), a guide rail II (31-2), a guide rail III (31-3), a guide rail mounting plate I (32-1), a guide rail mounting plate II (32-2), a guide rail mounting plate III (32-3), a vertical beam interface plate (33), a cross beam (34), a cross beam mounting support (35), a sliding block I (36-1), a sliding block II (36-2), a sliding block III (36-3), a rack I (37-1), a rack II (37-2), a rack III (37-3), a rack mounting plate I (38-1), a rack mounting plate II (38-2), a rack mounting plate III (38-3), a parallel beam (39), a motor mounting seat II (40), a servo motor I (41-1), The device comprises a servo motor II (41-2), a servo motor III (41-3), a mounting base I (42) with a bearing, a gear I (43-1), a gear II (43-2), a gear III (43-3), a gear IV (43-4), a speed reducer with double output shafts (44), a coupler I (45-1), a coupler II (45-2), a vertical beam (46), a cylinder bearing plate (47), a transmission shaft I (48), a shaft mounting plate (49), a vertical beam slider mounting plate I (50-1), a vertical beam slider mounting plate II (50-2), a beam slider mounting plate I (51-1) and a beam slider mounting plate II (51-2); the two parallel beams (39) are arranged in parallel, the lower surfaces of the two parallel beams (39) are fixed with an equipment frame (2), the upper surface of each parallel beam (39) is connected with a guide rail mounting plate I (32-1), a guide rail I (31-1) is fixed on the guide rail mounting plate I (32-1), a sliding block I (36-1) is mounted on each guide rail I (31-1), the inner side surfaces of the two parallel beams (39) are respectively fixed with a rack mounting plate I (38-1), the rack mounting plate I (38-1) is perpendicular to the bottom surface of the guide rail mounting plate I (32-1), the rack I (37-1) is fixed on the rack mounting plate I (38-1), and the tooth surface of the rack I (37-1) faces downwards; the beam mounting supports (35) are fixed at two ends of the beam (34), the beam (34) arranged between the two parallel beams (39) is perpendicular to the two parallel beams (39), and the beam (34) is respectively fixed on the sliding block I (36-1) through the beam mounting supports (35) at the two ends; two guide rail mounting plates III (32-3) are respectively fixed on the upper surface and the lower surface of a cross beam (34), each guide rail mounting plate III (32-3) is provided with a guide rail III (31-3), each guide rail III (31-3) is respectively provided with a slide block III (36-3), a rack III (37-3) is arranged on one side surface of the cross beam (34) through a rack mounting plate III (38-3) and has a downward tooth surface, a motor mounting seat II (40) is fixed on the other side surface of the cross beam (34) and is positioned at one end of the cross beam (34), a belt bearing mounting seat I (42) is fixed at the other end of the cross beam (34) through a shaft mounting plate (49), a servo motor I (41-1) and a double output shaft speed reducer (44) are fixed on the motor mounting seat II (40), an output shaft of the servo motor I (41-1) is matched with the double output shaft speed reducer (, the gear I (43-1) is arranged on one output shaft of the double-output-shaft speed reducer (44), the gear I (43-1) is meshed with the rack I (37-1) on one parallel beam (39), one end of the transmission shaft I (48) is connected with the other output shaft of the double-output-shaft speed reducer (44) through the coupler I (45-1), the other end of the transmission shaft I (48) is connected with the gear II (43-2) through the coupler II (45-2), the gear II (43-2) is fixed on the bearing mounting seat I (42), and the gear II (43-2) is meshed with the rack I (37-1) on the other parallel beam; a sliding block III (36-3) which is matched and arranged with the two guide rails (31-3) is respectively fixed on a beam sliding block mounting plate I (51-1) and a beam sliding block mounting plate II (51-2), the beam sliding block mounting plate I (51-1) and the beam sliding block mounting plate II (51-2) are vertically fixed on one side of a vertical beam interface plate (33), a servo motor III (41-3) is arranged on the other side of the vertical beam interface plate (33), an output shaft of the servo motor III (41-3) penetrates through the vertical beam interface plate (33), the gear III (43-3) is arranged on an output shaft of the servo motor III (41-3), and the gear III (43-3) is meshed with a rack III (37-3) on the cross beam (34); a vertical beam (46) is arranged on the other side of the vertical beam interface board (33) and is vertical to the cross beam (34), two guide rail mounting plates II (32-2) are respectively fixed on two side surfaces of the vertical beam (46) and are symmetrically arranged, a rack II (37-2) is arranged on the other side surface of the vertical beam (46) through a rack mounting plate II (38-2), slide blocks II (36-2) are respectively arranged on the guide rails II (31-2) arranged on the guide rail mounting plates II (32-2) on the two symmetrical side surfaces of the vertical beam (46), the slide blocks II (36-2) on the two sides are respectively fixed on the vertical beam slide block mounting plate I (50-1) and the vertical beam slide block mounting plate II (50-2), the vertical beam slide block mounting plate I (50-1) and the vertical beam slide block mounting plate II (50-2) are fixed on the vertical beam interface board (33), and is not at the same side with the beam slide block mounting plate I (51-1) and the beam slide block mounting plate II (51-2), the servo motor II (41-2) is arranged on the vertical beam interface plate (33), and is installed opposite to the servo motor III (41-3), the output shaft of the servo motor II (41-2) passes through the vertical beam interface board (33), the gear IV (43-4) is installed on the servo motor II (41-2), and the cylinder bearing plate (47) is welded at the tail end of the vertical beam (46) and is used for being connected with a manipulator mounting seat (52) of the boxing manipulator (4), and the vertical beam slider protective cover (30) is fixed on the vertical beam slider mounting plate I (50-1) and the vertical beam slider mounting plate II (50-2) and is positioned on the same side with the servo motor III (41-3).

5. The automatic case packer of production line articles as claimed in claim 1, wherein: the boxing manipulator (4) is used for providing power to drive the optical axis I (64) to move up and down through the cylinder (53) with the mounting seat, the up-and-down movement of the optical axis I (64) drives the two linear bearings I (67) to move in an opening and closing mode, and the movement of the linear bearings I (67) drives the opening and closing movement of the gripper (60).

6. The automatic case packer of production line articles as claimed in claim 1, wherein: the boxing manipulator (4) comprises a manipulator mounting seat (52), a cylinder (53) with a mounting seat, a gripper mounting frame (54), a linear bearing mounting seat (55), a guide rail IV (56-1), a guide rail V (56-2), a slide block IV (57-1), a slide block V (57-2), an optical axis supporting seat I (58), a connecting rod I (59-1) with a bearing, a connecting rod II (59-2) with a bearing, a gripper (60), a clamping plate (61) with a rubber mat, a roller (62) with a bearing, a cylinder joint (63), an optical axis I (64), a gripper fixing ring (65), a slide block connecting plate I (66-1), a slide block connecting plate II (66-2) and a linear bearing I (67); wherein the manipulator mounting seat (52) and the cylinder (53) with the mounting seat are fixed on the upper surface of the gripper mounting frame (54), the cylinder (53) with the mounting seat is vertically arranged in the manipulator mounting seat (52) and a piston rod with the cylinder (53) with the mounting seat penetrates out of the gripper mounting frame (54), a cylinder joint (63) is fixed at the tail end of the piston rod with the cylinder (53) with the mounting seat and fixes an optical axis I (64) on the cylinder joint (63), two ends of the optical axis I (64) are respectively fixed on an optical axis supporting seat I (58), the optical axis supporting seat I (58) is fixed on a sliding block IV (57-1) through a sliding block connecting plate II (66-2), the sliding block IV (57-1) is matched and installed with a guide rail IV (56-1) on the gripper mounting frame (54), two linear bearing mounting seats (55) are installed on two ends of the optical axis I (64) through linear bearings I (67, one end of a connecting rod I (59-1) with a bearing and one end of a connecting rod II (59-2) with a bearing are fixed on two sides of a linear bearing mounting seat (55), the other end of the connecting rod I (59-1) with a bearing is fixed on a gripper mounting frame (54), the other end of the connecting rod II (59-2) with a bearing is connected with a gripper (60) through a gripper fixing ring (65), one end of the gripper (60) is fixed on a slider V (57-2) through a slider connecting plate I (66-1), the slider V (57-2) is installed on a guide rail V (56-2), the guide rail V (56-2) is fixed on the gripper mounting frame (54) and is parallel to the horizontal plane, a clamping plate (61) with a rubber mat is fixed on the other end of the gripper (60), and a roller (62) with a bearing is installed on the clamping plate (61) with a rubber mat.

7. The automatic case packer of production line articles as claimed in claim 1, wherein: the tray reversing device (5) provides power through a linear cylinder (78), drives the L-shaped inner frame to move up and down, and is used for realizing superposition with the working surface of the circulating speed-multiplying chain (7); the servo motor IV (89) provides power to drive the conveying belt I (88) on the L-shaped inner frame to move; the empty tray (134) conveyed from the upper layer of the circulating speed-multiplying chain (7) is transferred to the lower layer of the circulating speed-multiplying chain (7).

8. The automatic case packer of production line articles as claimed in claim 1, wherein: the tray reversing device (5) comprises a connecting beam I (68-1), a connecting beam II (68-2), a connecting beam III (68-3), a connecting beam IV (68-4), a guide rail VI (69), an upright post III (70), a slider VI (71), a slider connecting plate III (72), a welding plate I (73-1), a welding plate II (73-2), a welding plate III (73-3), an inner frame beam I (74-1), an inner frame beam II (74-2), a T-shaped air cylinder joint plate (75), an inner frame upright post (76), an air cylinder fixing plate I (77-1), an air cylinder fixing plate II (77-2), a linear air cylinder (78), an anchor II (79), a rubber cushion (80), a driving pulley (81), a bearing mounting seat II (82) with a bearing, a synchronous belt I (83), a driven pulley (84), a synchronous belt I and a synchronous belt I, The device comprises a transmission shaft II (85), a belt wheel mounting support (86), an air cylinder mounting plate (87), a conveying belt I (88), a servo motor IV (89), a motor mounting seat III (90), an upright post connecting plate (91), a conveying belt wheel I (92), a baffle plate (93), a baffle plate fixing frame (94), a bottom plate I (95), a tensioning plate I (96), an inner frame support (97), an inner frame connecting beam (98), an inner frame short beam (99), an inner frame cross beam (100) and a driving wheel I (101); the lower ends of 2 upright posts III (70) are respectively fixed with one end of another connecting beam I (68-1) and one end of a connecting beam IV (68-4) through upright post connecting plates (91); the rectangular outer frame is formed by 2 upright posts III (70) and 2 connecting beams I (68-1), welding plates I (73-1) at two ends of each connecting beam III (68-3) are fixed at the middle positions of the 2 upright posts III (70), the rectangular outer frame is changed into a reversed-Y-shaped outer frame, and connecting beams II (68-2) are fixed at the other ends of the IV (68-4) of the 2 connecting beams and form an L-shaped outer frame together with the reversed-Y-shaped outer frame; the inner frame support (97) is fixed in the middle of two upright post connecting beams IV (68-4) of the L-shaped outer frame and is perpendicular to the upright post connecting beams IV (68-4), and the rubber buffer cushion (80) is fixed on the inner frame support (97); feet II (79) are respectively fixed on four corners of the base of the L-shaped outer frame; 2 inner frame columns (76), 2 inner frame connecting beams (98), 2 inner frame short beams (99), an inner frame cross beam (100), an inner frame beam I (74-1) and an inner frame beam II (74-2) form an L-shaped inner frame; the guide rail VI (69) is fixed on a welding plate III (73-3) on the inner side of the upright post III (70), the welding plate III (73-3) is fixed on the inner side of the upright post III (70), and the sliding block VI (71) is arranged on the guide rail VI (69); the L-shaped inner frame is connected with a sliding block VI (71) on an L-shaped outer frame upright post (70) through a sliding block connecting plate III (72); the L-shaped inner frame base is in contact with a rubber buffer (80) on an inner frame support (97); the linear air cylinder (78) is installed in parallel to the upright post III (70), the base of the linear air cylinder (78) is fixed on a connecting beam I (68-1) on the L-shaped outer frame base through an air cylinder fixing plate II (77-2), the upper end of the linear air cylinder (78) is fixed on an air cylinder mounting plate (87) through an air cylinder fixing plate I (77-1), the air cylinder mounting plate (87) is fixed on the connecting beam III (68-3), a piston rod of the linear air cylinder (78) is connected with a T-shaped air cylinder joint plate (75), and the T-shaped air cylinder joint plate (75) is fixed on an inner frame beam I (74-1) on the upper portion of the L-shaped inner frame; the base plate I (95) is fixed on a welding plate II (73-2) on the base of the L-shaped inner frame; the two baffle fixing frames (94) are fixed on the edge of the bottom plate I (95) and are symmetrically arranged, and the two baffles (93) are respectively fixed on the baffle fixing frames (94); the two belt wheel mounting supports (86) are symmetrically fixed on a base plate I (95) and are arranged between two baffle fixing frames (94), a plurality of conveying belt wheels I (92) are respectively arranged on the two belt wheel mounting supports (86), a transmission shaft II (85) is fixed on the two belt wheel mounting supports (86) through two belt bearing mounting seats II (82), two driving belt wheels (81) are arranged at two ends of the transmission shaft II (85), the plurality of conveying belt wheels I (92) and 2 driving belt wheels (81) are respectively connected together through two conveying belts I (88), a bolt on a tensioning plate I (96) is fixed on one conveying belt wheel I (92) at the tail end, and the tensioning plate I (96) is perpendicular to the base plate I (95) and is arranged on the side surface of each belt wheel mounting support (86); a servo motor IV (89) is fixed on a base plate I (95) through a motor mounting seat III (90) and is installed between two belt wheel mounting supports (86), a driving wheel I (101) is installed on an output shaft of the servo motor IV (89), and power is transmitted to a driven wheel (84) on a transmission shaft II (85) through a synchronous belt I (83).

9. The automatic case packer of production line articles as claimed in claim 1, wherein: the packing box positioning and steering device (6) is used for providing power through a speed reducing motor II (124) to drive the conveying belt II (105) to move; the servo motor V (118) provides power to drive the left and right rotating lead screws (116) to realize the opening and closing movement of the side baffles (110); the rotation cylinder (127) provides power to drive the packed articles to rotate, and the packed articles are conveyed to the product output roller line II (1-2) by matching with the opening motion of the baffle plate (110) and the motion of the conveying belt II (105).

10. The automatic case packer of production line articles as claimed in claim 1, wherein: the packing box positioning and steering device (6) comprises a tensioning plate II (102), a linear bearing II (103), an optical axis II (104), a conveying belt II (105), an optical axis supporting seat II (106), a lead screw supporting seat (107), a lead screw nut (108), a supporting bending piece (109), a side baffle (110), a conveying belt wheel II (111), a supporting shaft supporting seat (112), a transmission shaft III (113), a driven wheel (114), a driving wheel II (115), a left-right rotating lead screw (116), a coupler III (117), a servo motor V (118), a motor mounting seat IV (119), a cylinder supporting bearing (120), a synchronous belt II (121), a rear baffle (122), a bottom plate II (123), a speed reducing motor II (124), a motor mounting seat V (125), a rotating cylinder mounting seat (126), a rotating cylinder (127), an anchor foot III (128), a welding plate IV (129), a crossbeam II (130), a beam, The vertical columns IV (131) and the connecting beams V (132); the welding plate IV (129) is fixed at the end openings of the beam II (130) and the upright post IV (131), the beam II (130), the upright post IV (131) and the connecting beam V (132) form a frame, and the anchor III (128) is fixed at one end of the upright post IV (131) and is in contact with the ground; the rotary cylinder (127) is fixed in the frame through a rotary cylinder mounting seat (126), an output shaft of the rotary cylinder (127) faces upwards, the rotary cylinder mounting seat (126) is fixed below the two beams II (130), the output shaft of the rotary cylinder (127) is fixed on a cylinder supporting bearing (120), one end of the cylinder supporting bearing (120) is fixed on the two beams II (130), and the other end of the cylinder supporting bearing (120) is fixed on a bottom plate II (123); the two support bending pieces (109) are fixed on a base plate II (123) in parallel, a plurality of conveying belt wheels II (111) are mounted on each support bending piece (109), the conveying belt wheels II (111) are connected together through a conveying belt II (105), a bolt on a tensioning plate II (102) is fixed on one conveying belt wheel II (111) at the tail end, and the tensioning plate II (102) is perpendicular to the base plate II (123) and mounted on the side face of each support bending piece (109); the speed reducing motor II (124) is fixed on the bottom surface of the bottom plate II (123) through a motor mounting seat V (125), and is not positioned on the same surface as the supporting bending piece (109); a driving wheel II (115) is arranged on an output shaft of a speed reducing motor II (124), power is transmitted to a driven wheel (114) on a transmission shaft III (113) through a synchronous belt II (121), the transmission shaft III (113) is fixed on two supporting bending pieces (109) through a supporting bearing seat (112), two ends of the transmission shaft III (113) are respectively connected with a conveying belt wheel II (111) at the head end of each supporting bending piece (109), and a rear baffle (122) is fixed at the tail ends of the two supporting bending pieces (109); the two optical axes II (104) fix the two side baffles (110) through the linear bearing II (103), the two side baffles (110) are placed in parallel, and the two optical axes II (104) are fixed on the two support bending pieces (109) through the optical axis supporting seat II (106); the left and right rotating lead screws (116) are fixed on the two side baffles (110) through lead screw nuts (108), and the left and right rotating lead screws (116) are fixed on the two supporting bending pieces (109) through two lead screw supporting seats (107); one end of a left-right rotating lead screw (116) is connected with a servo motor V (118) through a coupler III (117), the servo motor V (118) is installed on a motor installation seat IV (119), and the motor installation seat IV (119) is fixed on a bottom plate II (123).

Technical Field

The invention relates to an automatic container loader for articles in a production line, and belongs to the field of production machinery.

Background

The box filler is a mechanical device for filling articles into a packaging box, and is an indispensable component of a modern production line. In enterprise production, a case packer is required for a plurality of products. The traditional boxing manual work is mainly.

For example, a display is an I/O device belonging to a computer, i.e., an input/output device. It can be classified into CRT, LCD, PDP, OLED, etc. The electronic document display tool is a display tool which displays a certain electronic document on a screen through a specific transmission device and reflects the electronic document to human eyes. With the advent of the information age, the range of displays has become more and more extensive, and the number of displays used has increased substantially. At present, the boxing of the liquid crystal display is mainly based on the traditional manual work, and the packaging process mainly comprises the following steps: unpacking, boxing, sealing and stacking, wherein only boxing occupies about 65 percent of the whole packaging time.

In the mass production process, the boxing of the liquid crystal display with low labor intensity, low production cost and high working efficiency becomes a technical problem which is urgently needed to be solved at present. In recent two years, some box filling machines in the market have limited application range, complex control and low working efficiency. The automatic container loader for the liquid crystal production line has great significance for saving labor cost, reducing labor intensity and improving container loading efficiency and developing efficient, quick and portable research on automatic container loaders for liquid crystal production line articles.

Disclosure of Invention

The invention provides an automatic container loader for articles in a production line, which is used for realizing the container loading of the articles in a mechanical control mode and further realizing the recovery of empty trays while the containers are loaded.

The technical scheme of the invention is as follows: an automatic container loader for production line articles comprises a packaging box input roller line I1-1, a product output roller line II 1-2, an equipment frame 2, a three-degree-of-freedom mounting rack 3, a container loader manipulator 4, a tray reversing device 5, a packaging box positioning and steering device 6 and a circulating speed multiplying chain 7; the packing box input roller line I1-1 is used for inputting the packing box 135 to the packing box positioning and steering device 6; the product output roller line II 1-2 is used for outputting the packed articles input by the packing box positioning and steering device 6; the equipment frame 2 is used for fixing the three-degree-of-freedom mounting rack 3; the three-degree-of-freedom mounting rack 3 is used for driving the boxing manipulator 4 mounted on the three-degree-of-freedom mounting rack to perform linear motion in six directions; the boxing manipulator 4 is used for grabbing the articles 133 to be boxed on the circulating speed multiplying chain 7 and placing the articles 133 to be boxed into the packing boxes 135 on the packing box positioning and steering device 6; the tray reversing device 5 is used for transferring the empty trays 134 conveyed from the upper layer of the circulating speed-multiplying chain 7 to the lower layer of the circulating speed-multiplying chain 7; the packing box positioning and steering device 6 is used for receiving the packing boxes 135 input by the packing box input roller line I1-1 and conveying the packed articles to the product output roller line II 1-2; the endless multiple speed chain 7 is used for the transport of articles 133 to be boxed and the recovery of empty pallets 134.

The packaging box input roller line I1-1 and the product output roller line II 1-2 are identical in structure and respectively comprise a chain wheel roller 8, a welding plate 9, a driving chain wheel 10, a chain 11, a speed reducing motor I12, a motor mounting seat I13, a line body cross beam 14, a ground foot I15, a roller mounting support 16, an upright column connecting beam I17, an upright column I18, a driven chain wheel 19 and a bearing 20; wherein the welding plate 9 is fixed on the ports of the wire body cross beam 14, the upright post connecting beam I17 and the upright post I18, the combination of line body crossbeam 14 and stand tie-beam I17 makes up into the cylinder line body, I15 of a lower margin is fixed respectively to the one end of stand I18, 2 cylinder erection supports 16 are fixed on the other end of stand I18 and 2 cylinder erection supports 16 parallel arrangement, many sprocket rollers 8 are installed between 2 cylinder erection supports 16 and the axis is perpendicular with cylinder erection supports 16, bearing 20 installation driven sprocket 19 is passed through to sprocket roller 8's one end, driven sprocket 19 on the sprocket roller 8 passes through chain 11 and connects, gear motor I12 passes through motor mount pad I13 and fixes on line body crossbeam 14, drive sprocket 10 is installed on gear motor I12's output shaft, drive sprocket 10 passes through chain 11 with power transmission to sprocket roller 8 on driven sprocket 19.

The three-degree-of-freedom mounting rack 3 is used for providing power through the servo motor I41-1 to drive gears on two output shafts of the double-output-shaft speed reducer 44 to be meshed with racks on the corresponding parallel beam 39, so that the box filling manipulator 4 mounted on the three-degree-of-freedom mounting rack 3 moves along the parallel beam 39; the servo motor III 41-3 provides power to drive a gear on an output shaft of the servo motor to be meshed with a rack on the corresponding cross beam 34, so that the box filling manipulator 4 moves along the cross beam 34; the servo motor II 41-2 is used for providing power to drive a gear on an output shaft of the servo motor II to be meshed with a rack on the corresponding vertical beam 46, so that the box filling manipulator 4 moves along the vertical beam 46.

The three-degree-of-freedom mounting rack 3 comprises a vertical beam sliding block protective cover 30, a guide rail I31-1, a guide rail II 31-2, a guide rail III 31-3, a guide rail mounting plate I32-1, a guide rail mounting plate II 32-2, a guide rail mounting plate III 32-3, a vertical beam interface plate 33, a cross beam 34, a cross beam mounting support 35, a slide block I36-1, a slide block II 36-2, a slide block III 36-3, a rack I37-1, a rack II 37-2, a rack III 37-3, a rack mounting plate I38-1, a rack mounting plate II 38-2, a rack mounting plate III 38-3, a parallel beam 39, a motor mounting seat II 40, a servo motor I41-1, a servo motor II 41-2, a servo motor III 41-3, a bearing mounting seat I42 with a bearing, a gear I43, The device comprises a gear II 43-2, a gear III 43-3, a gear IV 43-4, a double-output-shaft speed reducer 44, a coupler I45-1, a coupler II 45-2, a vertical beam 46, a cylinder bearing plate 47, a transmission shaft I48, a shaft mounting plate 49, a vertical beam slider mounting plate I50-1, a vertical beam slider mounting plate II 50-2, a beam slider mounting plate I51-1 and a beam slider mounting plate II 51-2; the two parallel beams 39 are arranged in parallel, the lower surfaces of the two parallel beams 39 are fixed with the equipment frame 2, the upper surface of each parallel beam 39 is connected with a guide rail mounting plate I32-1, the guide rail I31-1 is fixed on the guide rail mounting plate I32-1, a sliding block I36-1 is mounted on each guide rail I31-1, the inner side surfaces of the two parallel beams 39 are fixed with a rack mounting plate I38-1 respectively, the rack mounting plate I38-1 is perpendicular to the bottom surface of the guide rail mounting plate I32-1, a rack I37-1 is fixed on the rack mounting plate I38-1, and the tooth surface of the rack I37-1 faces downwards; the beam mounting supports 35 are fixed at two ends of the beam 34, the beam 34 arranged between the two parallel beams 39 is perpendicular to the two parallel beams 39, and the beam 34 is respectively fixed on the sliding block I36-1 through the beam mounting supports 35 at the two ends; two guide rail mounting plates III 32-3 are respectively fixed on the upper surface and the lower surface of a cross beam 34, a guide rail III 31-3 is mounted on each guide rail mounting plate III 32-3, a sliding block III 36-3 is respectively mounted on each guide rail III 31-3, a rack III 37-3 is mounted on one side surface of the cross beam 34 through a rack mounting plate III 38-3, the tooth surface of the rack is downward, a motor mounting seat II 40 is fixed on the other side surface of the cross beam 34 and is positioned at one end of the cross beam 34, a belt bearing mounting seat I42 is fixed at the other end of the cross beam 34 through a shaft mounting plate 49, a servo motor I41-1 and a double-output shaft reducer 44 are fixed on the motor mounting seat II 40, an output shaft of the servo motor I41-1 is matched with the double-output shaft reducer 44, a gear I43-1 is, the gear I43-1 is meshed with a rack I37-1 on one parallel beam 39, one end of a transmission shaft I48 is connected with the other output shaft of the double-output-shaft speed reducer 44 through a coupler I45-1, the other end of the transmission shaft I48 is connected with a gear II 43-2 through a coupler II 45-2, the gear II 43-2 is fixed on a bearing mounting seat I42, and the gear II 43-2 is meshed with the rack I37-1 on the other parallel beam; the sliding block III 36-3 matched with the two guide rails 31-3 is respectively fixed on a beam sliding block mounting plate I51-1 and a beam sliding block mounting plate II 51-2, the beam sliding block mounting plate I51-1 and the beam sliding block mounting plate II 51-2 are vertically fixed on one side of a vertical beam interface plate 33, the servo motor III 41-3 is arranged on the other side of the vertical beam interface plate 33, an output shaft of the servo motor III 41-3 penetrates through the vertical beam interface plate 33 and is positioned between the beam sliding block mounting plate I51-1 and the beam sliding block mounting plate II 51-2, a gear III 43-3 is arranged on an output shaft of the servo motor III 41-3, and the gear III 43-3 is meshed with a rack III 37-3 on the beam 34; the vertical beam 46 is arranged on the other side of the vertical beam interface board 33 and is vertical to the cross beam 34, two guide rail mounting plates II 32-2 are respectively fixed on two side surfaces of the vertical beam 46 and are symmetrically arranged, a rack II 37-2 is arranged on the other side surface of the vertical beam 46 through a rack mounting plate II 38-2, sliders II 36-2 are respectively arranged on the guide rails II 31-2 arranged on the guide rail mounting plates II 32-2 on the two symmetrical side surfaces of the vertical beam 46, the sliders II 36-2 on the two sides are respectively fixed on the vertical beam slider mounting plate I50-1 and the vertical beam slider mounting plate II 50-2, the vertical beam slider mounting plate I50-1 and the vertical beam slider mounting plate II 50-2 are fixed on the vertical beam interface board 33 and are not on the same side with the cross beam slider mounting plate I51-1 and the cross beam slider mounting plate, the servo motor II 41-2 is arranged on the vertical beam interface board 33 and is arranged opposite to the servo motor III 41-3, the output shaft of the servo motor II 41-2 penetrates through the vertical beam interface board 33, the gear IV 43-4 is arranged on the servo motor II 41-2 and is meshed with the rack II 37-2 on the vertical beam 46, the cylinder bearing plate 47 is welded at the tail end of the vertical beam 46 and is used for being connected with the manipulator mounting seat 52 of the boxing manipulator 4, and the vertical beam slider protective cover 30 is fixed on the vertical beam slider mounting plate I50-1 and the vertical beam slider mounting plate II 50-2 and is on the same side as the servo motor III 41-3.

The boxing manipulator 4 is used for providing power to drive the optical axis I64 to move up and down through the cylinder 53 with the mounting seat, drives the two linear bearings I67 to move in an opening and closing mode through the up-and-down movement of the optical axis I64, and drives the gripper 60 to move in an opening and closing mode through the movement of the linear bearings I67.

The boxing manipulator 4 comprises a manipulator mounting seat 52, a cylinder 53 with a mounting seat, a gripper mounting frame 54, a linear bearing mounting seat 55, a guide rail IV 56-1, a guide rail V56-2, a slide block IV 57-1, a slide block V57-2, an optical axis supporting seat I58, a connecting rod I59-1 with a bearing, a connecting rod II 59-2 with a bearing, a gripper 60, a clamping plate 61 with a rubber gasket, a roller 62 with a bearing, a cylinder joint 63, an optical axis I64, a gripper fixing ring 65, a slide block connecting plate I66-1, a slide block connecting plate II 66-2 and a linear bearing I67; the manipulator mounting seat 52 and the cylinder with the mounting seat 53 are fixed on the upper surface of the gripper mounting frame 54, the cylinder with the mounting seat 53 is vertically arranged inside the manipulator mounting seat 52, the piston rod of the cylinder with the mounting seat 53 penetrates out of the gripper mounting frame 54, the cylinder joint 63 is fixed at the tail end of the piston rod of the cylinder with the mounting seat 53, the optical axis I64 is fixed on the cylinder joint 63, two ends of the optical axis I64 are respectively fixed on an optical axis supporting seat I58, the optical axis supporting seat I58 is fixed on a slide block IV 57-1 through a slide block connecting plate II 66-2, the slide block IV 57-1 is matched and arranged with a guide rail IV 56-1 on the gripper mounting frame 54, two linear bearing mounting seats 55 are arranged at two ends of the optical axis I64 through a linear bearing I67, and one end of a connecting rod with a bearing I59-1 and a connecting rod with a, the other end of the bearing-provided connecting rod I59-1 is fixed on the hand grip mounting frame 54, the other end of the bearing-provided connecting rod II 59-2 is connected with the hand grip 60 through the hand grip fixing ring 65, one end of the hand grip 60 is fixed on the sliding block V57-2 through the sliding block connecting plate I66-1, the sliding block V57-2 is installed on the guide rail V56-2, the guide rail V56-2 is fixed on the hand grip mounting frame 54 and is parallel to the horizontal plane, the rubber mat clamping plate 61 is fixed at the other end of the hand grip 60, and the bearing-provided roller 62 is installed on the rubber mat clamping plate 61.

The tray reversing device 5 provides power through a linear cylinder 78, drives the L-shaped inner frame to move up and down, and is used for realizing superposition with the working surface of the circulating speed-multiplying chain 7; the conveying belt I88 on the L-shaped inner frame is driven to move by the power provided by the servo motor IV 89; the empty tray 134 conveyed from the upper layer of the circulating speed-multiplying chain 7 is transferred to the lower layer of the circulating speed-multiplying chain 7.

The tray reversing device 5 comprises a connecting beam I68-1, a connecting beam II 68-2, a connecting beam III 68-3, a connecting beam IV 68-4, a guide rail VI 69, an upright post III 70, a slide block VI 71, a slide block connecting plate III 72, a welding plate I73-1, a welding plate II 73-2, a welding plate III 73-3, an inner frame beam I74-1, an inner frame beam II 74-2, a T-shaped cylinder joint plate 75, an inner frame upright post 76, a cylinder fixing plate I77-1, a cylinder fixing plate II 77-2, a linear cylinder 78, a foundation II 79, a rubber buffer 80, a driving pulley 81, a belt bearing mounting seat II 82, a synchronous belt I83, a driven pulley 84, a transmission shaft II 85, a pulley mounting support 86, a cylinder mounting plate 87, a conveying belt I88, a servo motor IV 89, a motor mounting seat III 90, an upright post connecting plate 91 and a conveying pulley I92, The device comprises a baffle plate 93, a baffle plate fixing frame 94, a bottom plate I95, a tensioning plate I96, an inner frame support 97, an inner frame connecting beam 98, an inner frame short beam 99, an inner frame cross beam 100 and a driving wheel I101; the lower ends of the 2 upright posts III 70 are respectively fixed with one end of another connecting beam I68-1 and one end of a connecting beam IV 68-4 through upright post connecting plates 91; 2 upright posts III 70 and 2 connecting beams I68-1 form a rectangular outer frame, welding plates I73-1 at two ends of the connecting beams III 68-3 are fixed at the middle positions of the 2 upright posts III 70, the rectangular frame becomes a reversed-Y-shaped outer frame, and connecting beams II 68-2 are fixed at the other ends of the 68-4 parts of the IV of the 2 connecting beams and form an L-shaped outer frame together with the reversed-Y-shaped outer frame; the inner frame support 97 is fixed in the middle of two upright post connecting beams IV 68-4 of the L-shaped outer frame and is vertical to the upright post connecting beams IV 68-4, and the rubber buffer cushion 80 is fixed on the inner frame support 97; feet II 79 are respectively fixed on four corners of the base of the L-shaped outer frame; 2 inner frame upright posts 76, 2 inner frame connecting beams 98, 2 inner frame short beams 99, an inner frame cross beam 100, an inner frame beam I74-1 and an inner frame beam II 74-2 form an L-shaped inner frame; the guide rail VI 69 is fixed on a welding plate III 73-3 on the inner side of the upright post III 70, the welding plate III 73-3 is fixed on the inner side of the upright post III 70, and the sliding block VI 71 is arranged on the guide rail VI 69; the L-shaped inner frame is connected with a sliding block VI 71 on an upright post III 70 of the L-shaped outer frame through a sliding block connecting plate III 72; the L-shaped inner frame base contacts the rubber bumper 80 on the inner frame support 97; the linear air cylinder 78 is arranged in parallel to the upright post III 70, the base of the linear air cylinder 78 is fixed on a connecting beam I68-1 on the L-shaped outer frame base through an air cylinder fixing plate II 77-2, the upper end of the linear air cylinder 78 is fixed on an air cylinder mounting plate 87 through an air cylinder fixing plate I77-1, the air cylinder mounting plate 87 is fixed on a connecting beam III 68-3, the piston rod of the linear air cylinder 78 is connected with a T-shaped air cylinder joint plate 75, and the T-shaped air cylinder joint plate 75 is fixed on an inner frame beam I74-1 on the upper portion of the L-; the base plate I95 is fixed on a welding plate II 73-2 on the base of the L-shaped inner frame; the two baffle fixing frames 94 are fixed on the edge of the bottom plate I95 and are symmetrically arranged, and the two baffles 93 are respectively fixed on the baffle fixing frames 94; the two belt wheel mounting supports 86 are symmetrically fixed on a base plate I95 and are arranged between two baffle fixing frames 94, a plurality of conveying belt wheels I92 are respectively arranged on the two belt wheel mounting supports 86, a transmission shaft II 85 is fixed on the two belt wheel mounting supports 86 through two belt bearing mounting seats II 82, two driving belt wheels 81 are arranged at two ends of the transmission shaft II 85, the plurality of conveying belt wheels I92 and 2 driving belt wheels 81 are respectively connected together through two conveying belts I88, a bolt on a tensioning plate I96 is fixed on one conveying belt wheel I92 at the tail end, and the tensioning plate I96 is perpendicular to the base plate I95 and is arranged on the side surface of the belt wheel mounting supports 86; servo motor IV 89 passes through motor mount pad III 90 to be fixed on bottom plate I95, and installs between two band pulley installation supports 86, and action wheel I101 is installed on servo motor IV 89's output shaft, transmits power for the driven wheel 84 on transmission shaft II 85 through hold-in range I83.

The packing box positioning and steering device 6 is used for providing power through a speed reducing motor II 124 and driving a conveying belt II 105 to move; the servo motor V118 provides power to drive the left and right rotating screw rods 116 to realize the opening and closing movement of the side baffles 110; the rotation cylinder 127 provides power to drive the packed articles to rotate, and the packed articles are conveyed to the product output roller line II 1-2 in cooperation with the opening movement of the baffle 110 and the movement of the conveying belt II 105.

The packing box positioning and steering device 6 comprises a tensioning plate II 102, a linear bearing II 103, an optical axis II 104, a conveying belt II 105, an optical axis supporting seat II 106, a screw rod supporting seat 107, a screw rod nut 108, a supporting bending piece 109, a side baffle 110, a conveying belt wheel II 111, a supporting bearing seat 112, a transmission shaft III 113, a driven wheel 114, a driving wheel II 115, a left-right rotating screw rod 116, a coupling III 117, a servo motor V118, a motor mounting seat IV 119, a cylinder supporting bearing 120, a synchronous belt II 121, a rear baffle 122, a bottom plate II 123, a speed reducing motor II 124, a motor mounting seat V125, a rotating cylinder mounting seat 126, a rotating cylinder 127, a ground foot III 128, a welding plate IV 129, a beam II 130, an upright post IV 131 and a connecting beam V; the welding plate IV 129 is fixed at the end openings of the beam II 130 and the upright post IV 131, the beam II 130, the upright post IV 131 and the connecting beam V132 form a frame, and the anchor III 128 is fixed at one end of the upright post IV 131 and is in contact with the ground; the rotary cylinder 127 is fixed inside the frame through a rotary cylinder mounting seat 126, an output shaft of the rotary cylinder 127 faces upwards, the rotary cylinder mounting seat 126 is fixed below the two beams II 130, the output shaft of the rotary cylinder 127 is fixed on the cylinder supporting bearing 120, one end of the cylinder supporting bearing 120 is fixed on the two beams II 130, and the other end of the cylinder supporting bearing 120 is fixed on the bottom plate II 123; the two support bending pieces 109 are fixed on a base plate II 123 in parallel, a plurality of conveying belt wheels II 111 are mounted on each support bending piece 109, the conveying belt wheels II 111 are connected together through a conveying belt II 105, a bolt on a tensioning plate II 102 is fixed on one conveying belt wheel II 111 at the tail end, and the tensioning plate II 102 is perpendicular to the base plate II 123 and mounted on the side face of each support bending piece 109; the speed reducing motor II 124 is fixed on the bottom surface of the bottom plate II 123 through a motor mounting seat V125 and is not positioned on the same surface as the supporting bending piece 109; the driving wheel II 115 is arranged on an output shaft of the speed reducing motor II 124, power is transmitted to the driven wheel 114 on the transmission shaft III 113 through the synchronous belt II 121, the transmission shaft III 113 is fixed on the two supporting bending pieces 109 through the supporting bearing block 112, two ends of the transmission shaft III 113 are respectively connected with the conveying belt wheel II 111 at the head ends of the supporting bending pieces 109, and the rear baffle 122 is fixed at the tail ends of the two supporting bending pieces 109; the two optical axes II 104 fix the two side baffles 110 through the linear bearings II 103, the two side baffles 110 are placed in parallel, and the two optical axes II 104 are fixed on the two support bending pieces 109 through the optical axis support bases II 106; the left-right rotating lead screw 116 is fixed on the two side baffles 110 through a lead screw nut 108, and the left-right rotating lead screw 116 is fixed on the two supporting bending pieces 109 through two lead screw supporting seats 107; one end of the left-right rotating screw rod 116 is connected with a servo motor V118 through a coupler III 117, the servo motor V118 is installed on a motor installation seat IV 119, and the motor installation seat IV 119 is fixed on a bottom plate II 123.

The invention has the beneficial effects that:

1. the invention adopts the structures of a circulating speed-multiplying chain, a tray reversing device, a three-degree-of-freedom mounting rack, a boxing manipulator, a packing box positioning and steering device and the like. The display to be boxed enters a working area of a boxing manipulator through a recyclable speed multiplication chain, the boxing manipulator is used for grabbing the display and placing the display in a positioned and clamped packaging box, and the packaging box is unpacked by an unpacking machine and then enters a positioning and turning device through a packaging box input roller line I to be positioned and clamped; the boxing manipulator places the display into a packaging box, and the boxed display is conveyed to an output roller line II through a positioning steering device; and the empty tray to be recovered enters the lower layer of the circulating speed multiplying chain through the tray recovery device. The whole boxing process realizes circular boxing through the linkage of each mechanism, and the scheme is suitable for multiple types of objects to be boxed, such as: the display is compared in artifical vanning of tradition, and vanning efficiency is also higher, has reduced manufacturing cost, also makes whole production line more intelligent.

2. The invention adopts the cooperation of the circulating speed-multiplying chain and the tray reversing device, can realize the recovery of empty trays without influencing boxing, and can ensure the continuity of a production line in the operation process.

3. The three-degree-of-freedom mounting frame is matched with the boxing manipulator, so that the automatic adjustment and sensitivity of the boxing manipulator can be ensured. The three-degree-of-freedom mounting frame and the boxing manipulator are driven in a pneumatic and electric matching mode in the working process, mechanical transmission chains are reduced, the structure is simpler and more compact, and the machine body is flexible and light. The mechanical clamping jaw is driven in a pneumatic mode, the range of the clamping jaw can be automatically adjusted, the universality of the equipment is improved, and the boxing efficiency is higher.

4. The invention adopts the close fit of the packing box positioning and steering device, the packing box input roller line I and the packing box output roller line II, can realize the input, positioning, fixing, boxing, steering and output of the packing box, improves the boxing efficiency of boxing equipment and saves the boxing time.

Drawings

FIG. 1 is an isometric overall view of the present invention;

FIG. 2 is an isometric view of the frame of the apparatus of the present invention with portions broken away;

FIG. 3 is an overall top view of the present invention;

figure 4 is an isometric view of the input/output roll line i/ii of the package of the present invention;

FIG. 5 is a left and right isometric view of the input/output roll line I/II of the package of the present invention;

FIG. 6 is a schematic structural view of the sprocket roller of the present invention;

FIG. 7 is an isometric view of the apparatus frame of the present invention;

FIG. 8 is an isometric view of a three degree of freedom mounting bracket of the present invention;

FIG. 9 is a block diagram of the parallel beams of the three degree-of-freedom mount of the present invention;

FIG. 10 is an enlarged side view of the parallel beams of the three-degree-of-freedom mount of the present invention;

FIG. 11 is a cross-beam structure of the three degree-of-freedom mounting bracket of the present invention;

FIG. 12 is a first installation structure diagram of the cross beam and the vertical beam in the three-degree-of-freedom installation frame of the present invention;

FIG. 13 is a three degree of freedom mounting block vertical beam structure of the present invention;

FIG. 14 is a second installation structure diagram of the cross beam and the vertical beam in the three-degree-of-freedom installation frame of the present invention;

FIG. 15 is a third installation structure diagram of the cross beam and the vertical beam in the three-degree-of-freedom installation frame of the present invention;

FIG. 16 is a front view of the boxing robot of the present invention;

figure 17 is an isometric view of a boxing robot of the present invention;

FIG. 18 is a front view of the tray diverter of the present invention;

FIG. 19 is an isometric view of the tray reversing device of the present invention;

FIG. 20 is an isometric view of the L-shaped outer frame and the L-shaped inner frame of the pallet reversing device of the present invention;

FIG. 21 is an isometric view of an L-shaped inner frame in the pallet reversing device of the present invention;

FIG. 22 is an enlarged fragmentary view of the tray diverter of the present invention;

figure 23 is an isometric view of the package positioning and turning device of the present invention;

FIG. 24 is a first partial view of the package positioning and turning device of the present invention;

FIG. 25 is a front view of the container positioning and turning device of the present invention;

FIG. 26 is a second view of the positioning and steering device for the packing case of the present invention;

FIG. 27 is a fragmentary view III of the package positioning and turning device of the present invention;

the reference numbers in the figures are: 1-1-a packing box input roller line I, 1-2-a product output roller line II, 2-an equipment frame, a 3-three-degree-of-freedom mounting rack, a 4-a packing manipulator, a 5-a pallet reversing device, a 6-a packing box positioning and steering device, a 7-a circulating speed-multiplying chain, an 8-chain wheel roller, a 9-welding plate, a 10-driving chain wheel, an 11-chain, a 12-a speed-reducing motor I, a 13-a motor mounting seat I, a 14-a line body cross beam, a 15-a ground foot I, a 16-a roller mounting support, a 17-an upright column connecting beam I, an 18-an upright column I, a 19-driven chain wheel, a 20-bearing, a 21-an upright column bottom plate, a 22-an equipment front protection plate, a 23-1-an equipment side protection plate I, a, 24-top longitudinal protection plate, 25-top transverse protection plate, 26-equipment rear protection plate, 27-column connecting beam II, 28-connecting plate, 29-column II, 30-vertical beam slide block protective cover, 31-1-guide rail I, 31-2-guide rail II, 31-3-guide rail III, 32-1-guide rail mounting plate I, 32-2-guide rail mounting plate II, 32-3-guide rail mounting plate III, 33-vertical beam interface plate, 34-beam I, 35-beam mounting support, 36-1-slide block I, 36-2-slide block II, 36-3-slide block III, 37-1-rack I, 37-2-rack II, 37-3-rack III, 38-1-rack mounting plate I, 38-2-rack mounting plate II, 38-3-rack mounting plate III, 39-parallel beam, 40-motor mounting base II, 41-1-servo motor I, 41-2-servo motor II, 41-3-servo motor III, 42-belt bearing mounting base I, 43-1-gear I, 43-2-gear II, 43-3-gear III, 44-double output shaft reducer, 45-1-coupler I, 45-2-coupler II, 46-vertical beam, 47-cylinder bearing plate, 48-transmission shaft I, 49-transmission shaft mounting plate, 50-1-vertical beam sliding block mounting plate I, 50-2-vertical beam sliding block mounting plate II, 51-1-crossbeam slide block mounting plate I, 51-2-crossbeam slide block mounting plate II, 52-manipulator mounting base, 53-cylinder with mounting base, 54-gripper mounting base, 55-linear bearing mounting base, 56-1-guide rail IV, 56-2-guide rail V, 57-1-slide block IV, 57-2-slide block V, 58-optical axis bearing base I, 59-1-connecting rod with bearing I, 59-2-connecting rod with bearing II, 60-gripper, 61-clamping plate with rubber pad, 62-roller with bearing, 63-cylinder joint, 64-optical axis I, 65-gripper fixing ring, 66-1-slide block connecting plate I, 66-2-slide block connecting plate II, 67-linear bearing I, 68-1-connecting beam I, 68-2-connecting beam II, 68-3-connecting beam III, 68-4-connecting beam IV, 69-guide rail VI, 70-upright post III, 71-slide block VI, 72-slide block connecting plate III, 73-1-welding plate I, 73-2-welding plate II, 73-3-welding plate III, 74-1-inner frame beam I, 74-2-inner frame beam II, 75-T-shaped cylinder joint plate, 76-inner frame upright post, 77-1-cylinder fixing plate I, 77-2-cylinder fixing plate II, 78-linear cylinder, 79-anchor II, 80-rubber buffer cushion, 81-driving pulley, 82-belt bearing mounting seat II, 83-synchronous belt I, 84-driven belt pulley, 85-transmission shaft II, 86-belt pulley mounting support, 87-air cylinder mounting plate, 88-conveying belt I, 89-servo motor IV, 90-motor mounting seat III, 91-upright column connecting plate, 92-conveying belt pulley I, 93-baffle plate, 94-baffle plate fixing frame, 95-bottom plate I, 96-tensioning plate I, 97-inner frame support, 98-inner frame connecting beam, 99-inner frame short beam, 100-inner frame cross beam, 101-driving wheel I, 102-tensioning plate II, 103-linear bearing II, 104-optical axis II, 105-conveying belt II, 106-optical axis supporting seat II, 107-screw rod supporting seat, 108-screw rod nut, 109-supporting bending member and 110-side baffle plate, 111-conveying belt wheels II, 112-supporting bearing seats, 113-transmission shafts III, 114-driven wheels, 115-driving wheels II, 116-left and right rotating screw rods, 117-couplings III, 118-servo motors V, 119-motor mounting seats IV, 120-cylinder supporting bearings, 121-synchronous belts II, 122-rear baffle plates, 123-bottom plates II, 124-speed reducing motors II, 125-motor mounting seats V, 126-rotating cylinder mounting seats, 127-rotating cylinders, 128-ground feet III, 129-welding plates IV, 130-cross beams II, 131-upright columns IV, 132-connecting beams V, 133-articles to be boxed, 134-trays and 135-packaging boxes.

Detailed Description

The invention will be further described with reference to the following figures and examples, without however restricting the scope of the invention thereto.