JP6655502B2 - Packaging system - Google Patents

Description

  The present invention is a first transport device that sequentially transports a plurality of articles in a state of being arranged, a second transport device that sequentially transports the articles transported by the first transport device, and transported by the second transport device. And a packaging device for sequentially packaging the articles.

  The packaging device sequentially packages articles. A finger conveyor is used in the supply device in order to periodically supply the articles to such a packaging apparatus in order and to synchronize the supply cycle of the articles with the packaging cycle by the packaging apparatus. The finger conveyor includes an endless member such as an endless belt, an endless chain, or an endless wire, a pushing finger attached to the endless member at regular intervals, and a motor for rotating the endless member (for example, see Patent Document 1). When the endless member is rotated by the motor, the articles are pushed by the pushing fingers.Since the pushing fingers are arranged at equal intervals, the articles can be periodically supplied to the packaging device, and the supply cycle of the articles is reduced. It can be synchronized with the packaging cycle by the packaging device. In addition, a belt conveyor provided with a row reduction function and an alignment function is used for supplying articles to the finger conveyor (for example, see Patent Document 1).

Japanese Patent Publication No. 48-22744

However, the intervals of the article rows conveyed by the belt conveyor are not constant. If the interval between the rows of articles is widened, the rows of articles conveyed by the finger conveyor may be missing, and this causes an empty package to be produced by the packaging apparatus.
It is conceivable to temporarily stop the packaging device when the missing portion reaches the packaging device so that an empty package is not created. However, the packaging film is wrinkled due to inertial force or the like at the time of stoppage, and therefore, it is not preferable to temporarily stop the packaging device.

  Therefore, the present invention has been made in view of the above circumstances. The problem to be solved by the present invention is to prevent an empty package from being produced by a downstream packaging device even if a row of articles transported by a transport device such as a finger conveyor is missing. .

  The present invention for solving the above problems, a first transporting device that sequentially transports and supplies a plurality of articles to a first delivery point in a state where a plurality of articles are arranged, and the article transported by the first transporting device A second transport device that sequentially transports and supplies along the transport path from the first delivery point to the second delivery point, and wraps the article transported by the second transport device in a film at the second delivery point, and Conveying with the film, by sealing a portion between the articles in the film, a packaging device for sequentially packaging the articles, a detection unit that detects the articles passing through the first delivery point, the first A transport device, a control unit that controls the second transport device and the packaging device, the second transport device is formed in a closed path shape, a part thereof along the transport path And a plurality of moving bodies guided along the guides by the guides, and the moving body provided on the moving body and moving a portion of the guides along the conveying path. A pushing member that pushes out an article by pushing the moving body, and the moving body that individually circulates the moving body along the guide in a direction from the first delivery point toward the second delivery point along the transport path. A linear motor that drives a linear motor that drives the linear motor, wherein the linear motor is arranged at a position behind the first delivery point among the movable bodies each time the detection unit detects an article. An operation process of controlling the linear motor so as to start moving toward the second delivery point and decelerate the moving body that has started moving to catch up with the preceding moving body; Executing a counting process of counting the number of times the detection unit detects an article during the predetermined period, and a shifting process of controlling a supply speed of the first transport device based on a count value of the counting process. It is a packaging system characterized by doing.

  In addition, the present invention for solving the above-described problems includes a first transporting device that sequentially transports and supplies a plurality of articles to a first delivery point in a state where a plurality of articles are arranged, and the article transported by the first transporting device. A second transport device that sequentially transports and supplies the first transport location along the transport path from the first delivery location to the second delivery location, and wraps the article transported by the second transport device in a film at the second delivery location. Conveying with the film, by sealing the portion of the film between the articles, a packaging device for sequentially packaging the articles, a detection unit that detects the articles passing through the first delivery point, A control unit configured to control the first transport device, the second transport device, and the packaging device, wherein the second transport device is formed in a closed path, and a part of the second transport apparatus is along the transport path. A plurality of moving bodies guided along the guide by the guide, and a plurality of moving bodies provided on the moving body and moving a portion of the guide along the transport path. A pushing member which pushes out an article by projecting into a transport path, and the moving so as to individually circulate the moving bodies along the guide in a direction from the first delivery point to the second delivery point along the transport path. A linear motor for driving a body, wherein the control unit is configured such that each time the detection unit detects an article, the moving unit includes the linear motor arranged behind the first delivery point among the moving units. An operation process of controlling the linear motor to start moving the head of the linear motor toward the second delivery point and to reduce the speed of the moving object that has started moving after catching up with the preceding moving object; A counting process for counting the number of moving objects moving toward the second delivery point in a state where the speed is reduced by the linear motor, and supplying the first transport device based on a count value of the counting process. And a speed change process for controlling a speed.

  In addition, the present invention for solving the above-described problems includes a first transporting device that sequentially transports and supplies a plurality of articles to a first delivery point in a state where a plurality of articles are arranged, and the article transported by the first transporting device. A second transport device that sequentially transports and supplies the first transport location along the transport path from the first delivery location to the second delivery location, and wraps the article transported by the second transport device in a film at the second delivery location. Conveying with the film, by sealing the portion of the film between the articles, a packaging device for sequentially packaging the articles, a detection unit that detects the articles passing through the first delivery point, A control unit that controls the first transport device, the second transport device, and the packaging device, and the second transport device is formed in a closed path shape, and a part of the second transport apparatus is in the transport path. And a plurality of moving bodies guided along the guide by the guide, and a moving body provided on the moving body and moving a portion of the guide along the transport path. A pushing member that pushes out the article by pushing into the transport path, and the moving body is individually circulated along the guide in a direction from the first delivery point to the second delivery point along the transport path. A linear motor that drives a moving body, wherein the control unit is configured to move the linear motor after the first delivery point in the moving body every time the detecting unit detects an article. An operation process of controlling the linear motor so as to start moving the head of the body toward the second delivery point and decelerate the moving body that has started moving after catching up with the preceding moving body; For each period, a counting process of counting the number of times the detection unit detects an article during the predetermined period, and a shifting process of controlling a packaging speed of the packaging device based on a count value of the counting process, A packaging system characterized by being executed.

  In addition, the present invention for solving the above-described problems includes a first transporting device that sequentially transports and supplies a plurality of articles to a first delivery point in a state where a plurality of articles are arranged, and the article transported by the first transporting device. A second transport device that sequentially transports and supplies the first transport location along the transport path from the first delivery location to the second delivery location, and wraps the article transported by the second transport device in a film at the second delivery location. Conveying with the film, by sealing the portion of the film between the articles, a packaging device for sequentially packaging the articles, a detection unit that detects the articles passing through the first delivery point, A control unit that controls the first transport device, the second transport device, and the packaging device, and the second transport device is formed in a closed path shape, and a part of the second transport apparatus is in the transport path. And a plurality of moving bodies guided along the guide by the guide, and a moving body provided on the moving body and moving a portion of the guide along the transport path. A pushing member that pushes out the article by pushing into the transport path, and the moving body is individually circulated along the guide in a direction from the first delivery point to the second delivery point along the transport path. A linear motor that drives a moving body, wherein the control unit is configured to move the linear motor after the first delivery point in the moving body every time the detecting unit detects an article. An operation process of controlling the linear motor so as to start moving the head of the body toward the second delivery point and decelerate the moving body that has started moving after catching up with the preceding moving body; A counting process for counting the number of moving objects moving toward the second delivery point in a state where the speed is reduced by the linear motor, and a packaging speed of the packaging device based on the count value of the counting process. And a shift process for controlling the speed control.

  Other features of the present invention will be apparent from the description in the specification and the drawings described below.

According to the present invention, the linear motor individually drives the moving bodies, and the moving bodies are sequentially started from the top each time an article is sent to the first delivery point, and the second delivery is performed from the first delivery point. It is moved along the guide toward the point, catching up with the preceding moving body. Then, even if a row of articles conveyed by the first conveying apparatus is missing, articles can be packed by the second conveying apparatus and supplied to the packaging apparatus by the amount of the missing.
Also, the number of moving bodies that move toward the second delivery point based on the number of articles supplied from the first transport apparatus to the second transport apparatus during the predetermined cycle or in a state where the speed is reduced by the linear motor. , The supply speed of the first transport device or the packaging speed of the packaging device is controlled, so that the number of moving bodies and articles on the upstream side of the packaging device can be made appropriate. For this reason, even when the packaging system is operated for a long time, the supply of articles from the second transport device to the packaging device does not drop.

FIG. 1 is a side view of the packaging system. FIG. 2 is a plan view of the packaging system. FIG. 3 is a block diagram of the packaging system. FIG. 4 is a plan view of the package. FIG. 5 is a side view of the supply device and the first transport device. FIG. 6 is a plan view of the supply device and the first transport device. FIG. 7 is a side view of the second transfer device. FIG. 8 is a plan view of the second transfer device. FIG. 9 is a side view of the packaging device. FIG. 10 is a plan view of the packaging device. FIG. 11 is a flowchart illustrating a flow of a count process executed by the control unit. FIG. 12 is a flowchart illustrating the flow of the comparison / shift processing executed by the control unit. FIG. 13 is a truth table showing the input from the sensor to the control unit and the details of the shift performed by the input. FIG. 12 is a flowchart illustrating the flow of the comparison / shift processing executed by the control unit. FIG. 15 is a truth table showing the input from the sensor to the control unit and the details of the shift performed by the input. FIG. 16 is a plan view of the packaging system of the second embodiment. FIG. 17 is a plan view of the packaging system according to the third embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiments described below are provided with various technically preferable limits for carrying out the present invention, and thus the scope of the present invention is not limited to the following embodiments and illustrated examples.

[First Embodiment]
1. 1 is a side view of the packaging system 1, FIG. 2 is a plan view of the packaging system 1, and FIG. 3 is a block diagram of the packaging system 1. In FIGS. 1 and 2, the X axis, the Y axis, and the Z axis are illustrated as auxiliary lines indicating directions, but the X axis, the Y axis, and the Z axis are orthogonal to each other, and the X axis direction and the Y axis direction are This is a horizontal direction, and the Z-axis direction is a vertical direction.

  As shown in FIGS. 1 and 2, the packaging system 1 is an apparatus for sequentially wrapping an article 2 with a film 6 to produce a package 5 (see FIG. 4). The article 2 is, for example, a thin plate food (eg, rice cracker, molded potato chips, biscuit, cream sand biscuit), PTP package (blister package), strip package, card, printed circuit board, paperboard, medal, coin, hard Sheet or electronic component. As shown in FIG. 4, the package 5 is a pillow package, and the packaging film 6 of the package 5 is in a state of being rolled into a flat cylindrical shape. The overlapped portions are sealed in the longitudinal direction of the packaging film 6, so that the folded fin-shaped vertical stitches (center seal portions) 7 are formed on the packaging film 6. In addition, the horizontal binding seam (end seal portion) 8 is formed by sealing the end of the packaging film 6. Here, the length of the packaging film 6 (the length from the edge of one horizontal stitch 8 to the edge of the other horizontal stitch 8) is L5 [mm].

  As shown in FIGS. 1 to 3, the packaging system 1 sequentially arranges a transport table 10 and an article row 3 (a row 3 including a plurality of articles 2 arranged in a row in the X-axis direction) on the transport table 10 one by one. A supply device 20 for supplying, and a first transport device 30 for sequentially supplying the articles 2 one by one by transporting the article rows 3 supplied on the transport table 10 by the supply device 20 on the transport table 10 in the X-axis direction. A second transporting device 40 that transports the articles 2 in the X-axis direction while adjusting an interval between the articles 2 supplied by the first transporting device 30, and a packaging that sequentially packages the articles 2 transported by the second transporting device 40 A device 50, an article sensor 61 for detecting the article 2 passing through the downstream portion of the first transport device 30, an article sensor 62, 63 for detecting the presence or absence of the article 2 in the middle stream portion of the second transport device 40, It includes an article sensor 64 for detecting the presence or absence of an article 2 on the downstream side portion of the second feeding device 40, a control unit 70.

  The second transporting device 40 supplies the articles 2 individually and sequentially from the first transporting device 30 to the packaging device 50, but adjusts the transporting speed of the articles 2 being transported to change the article supply cycle of the packaging device 50. Match the packaging cycle. Here, the article supply cycle refers to a time from when the article 2 is supplied to the packaging apparatus 50 by the second transport device 40 to when the next article 2 is supplied, and the packaging cycle refers to the packaging apparatus 50. Means the time from when the article 2 is wrapped to when the next article 2 is wrapped. The reciprocal of the article supply cycle is the article supply speed (the number of articles 2 supplied per unit time), and the reciprocal of the packaging cycle is the packaging speed (the number of articles 2 packed per unit time).

2. Control Unit The control unit 70 is configured by a control circuit having, for example, a programmable logic controller (PLC). The control unit 70 controls the supply device 20, the first transport device 30, the second transport device 40, and the packaging device 50.

3. Transport Table As shown in FIGS. 1 and 2, the portion 11 on the upstream side in the X-axis direction of the transport table 10 is higher than the portion 13 on the downstream side, and the portion 12 between the upstream portion 11 and the downstream portion 13 is the downstream portion 13. Incline down towards. A slit 14 is formed to extend in the X-axis direction from the intermediate portion 12 to the end of the downstream portion 13. The intermediate portion 12 is a first delivery point P4 where the article 2 is delivered from the first transport device 30 to the second transport device 40. The downstream end in the X-axis direction of the transport table 10 is a second delivery point P5 where the article 2 is delivered from the second transport device 40 to the packaging device 50. The transport path of the article 2 overlaps the slit 14 when viewed from above, and extends linearly from the slit 14 to the upstream side in the X-axis direction and the downstream side in the X-axis direction. The range on the upstream side of the intermediate portion 12 (first delivery point P4) in the transport path of the article 2 is a section in which the article 2 is transported by the first transport device 30. The range up to the downstream end of the X-axis direction (the second delivery point P5) is a section in which the article 2 is transported by the second transport device 40, and the downstream end of the transport table 10 in the X-axis direction (second The range on the downstream side from the delivery point P5) is a section where the article 2 is transported by the packaging device 50.

4. Article Sensor The article sensor 61 is disposed above the intermediate portion 12 of the transport table 10, particularly above the X-axis upstream end of the slit 14. The article sensor 62 is arranged above an intermediate portion of the downstream portion 13 of the transport table 10. The article sensor 63 is disposed downstream of the article sensor 62 in the X-axis direction and upstream of the packaging device 50, and is particularly disposed above the slit 14. The article sensor 64 is located downstream of the article sensor 63 in the X-axis direction and slightly upstream of the second delivery point P5, and is particularly located above the slit 14.

The article sensor 61 is a reflection-type optical sensor that emits light downward from a light emitter and receives light reflected from below by a light receiver. When the article 2 is located below the article sensor 61 and the light is blocked by the article 2, the article 2 is detected by the article sensor 61. The article sensor 61 outputs a detection signal (for example, a high-level signal) to that effect to the controller 70 when the article 2 is detected, and a signal to that effect (for example, a low-level signal) when the article 2 is not detected. Is output to the control unit 70.
The article sensors 62 and 63 are also reflection type optical sensors like the article sensor 61.

5. Supply Device FIG. 5 is a side view of the supply device 20 and the first transfer device 30, and FIG. 6 is a plan view of the supply device 20 and the first transfer device 30. As shown in FIGS. 5 and 6, the articles 2 are arranged in a plurality of rows in the Y-axis direction above the transport table 10 and on the upstream side in the Y-axis direction. A row 4 of the arranged articles 2 is referred to as a column 4. These columns 4 are transported above the transport table 10 to the downstream side in the Y-axis direction by a vibration feeder or the like. A supply device 20 is provided at the head of the column 4 and above the transport table 10. The supply device 20 simultaneously picks up the leading articles 2 in each column 4 in the X-axis direction (the row of the picked-up articles 2 in the X-axis direction is the article row 3), and maintains the article row 3. In this state, the articles 2 in the article row 3 are turned over, and the articles 3 are released to supply the row 3 of these articles 2 onto the upstream portion 11 of the transport table 10.

  The supply device 20 includes a rotating drum 21, a rotating motor 22, a plurality of suction nozzles 23, and the like. The rotating drum 21 is disposed above the upstream portion 11 of the transport table 10 and at the front of the top of the column 4. The rotating shaft of the rotating drum 21 extends in the X-axis direction, and the rotating drum 21 is provided rotatable about the rotating axis. A plurality of suction nozzles 23 are provided on the outer peripheral surface of the rotary motor 22 so as to be arranged at regular intervals in the circumferential direction and the axial direction.

  The suction nozzle 23 rotates by the rotation of the rotary drum 21 driven by the rotary motor 22. When the suction nozzle 23 faces the upstream side in the Y-axis direction, the suction nozzle 23 suctions the leading article 2 in the column 4 by negative pressure, When facing downward, the article 2 is released by positive pressure.

  During the steady operation of the packaging system 1, the rotation speed of the rotary motor 22 is controlled by the control unit 70, so that the supply cycle and the supply speed of the article row 3 are controlled (operation processing). The supply cycle of the article row 3 refers to the time from when the article row 3 is supplied to the transport table 10 by the supply device 20 to when the next article row 3 is supplied. Speed. The rotational speed of the rotary drum 21 is n [1 / sec], the supply speed of the article row 3 is N0 [1 / sec], the supply cycle of the article row 3 is T0 [sec], and the suction arranged in the circumferential direction. Assuming that the number of nozzles 23 is K0, N0 = 1 / T0 = n × K0.

  Here, there is a case where the suction error of the article 2 by the suction nozzle 23 occurs. Further, the back surface of the article 2 sucked by the suction nozzle 23 (the surface opposite to the surface in contact with the suction nozzle 23) is inspected by the inspection device (for example, an electronic camera) 65, but when the back surface of the article 2 is defective. The article 2 is blown off by the suction nozzle 23, and the blown-off article 2 falls out of the article row 3. Therefore, the article row 3 supplied to the upstream portion 11 of the transport table 10 by the supply device 20 may be partially missing, and the interval between the articles 2 adjacent to each other with the missing portion therebetween is missing. It is wider than the interval between adjacent articles 2 without the mark. Here, the inspection device 65 is provided along the generatrix of the rotating drum 21 around the outer peripheral surface of the rotating drum 21.

6. First transfer device The first transfer device 30 is a side finger conveyor provided on the upstream portion 11 of the transfer table 10. The first transport device 30 includes a first pulley 31, a second pulley 32, an endless belt 33, a plurality of pushing fingers 34, a transport motor 35, and the like.

The first pulley 31 is rotatably provided at an end of the transport table 10 on the upstream side in the X-axis direction. The second pulley 32 is rotatably provided at the intermediate portion 12 of the transport table 10. The rotation axes of the pulleys 31 and 32 are vertical. The endless belt 33 is stretched over the first pulley 31 and the second pulley 32 above the transport table 10. The endless belt 33 is folded back by the first pulley 31 and the second pulley 32, so that the endless belt 33 is formed in a rounded rectangular shape (oval type) when viewed from above. The two parallel line portions of the endless belt 33 having the same length extend in the X-axis direction and are longer than the length of the rotary drum 21 in the X-axis direction. A transport motor 35 is connected to the first pulley 31, and the first pulley 31 is driven to rotate by the transport motor 35, whereby the endless belt 33 rotates.
Note that the endless belt 33 may be changed to an endless chain, and the pulleys 31 and 32 may be changed to sprockets.

  A plurality of pushing fingers 34 are attached to the endless belt 33 at predetermined intervals. More specifically, the pitch of the arrangement of the pushing fingers 34 is equal to the pitch of the arrangement of the suction nozzles 23 arranged in the X-axis direction. These pushing fingers 34 extend outward from the outer peripheral surface of the endless belt 33. The row of the pushing fingers 34 attached to one of the parallel lines is arranged in the X-axis direction immediately below the rotation axis of the rotary drum 21, and the slit 14 is arranged in the X-axis downstream from the X-axis downstream in the row. Extending to

  When the downwardly directed suction nozzle 23 releases the article 2 as described above, the article 2 falls between the pushing fingers 34 in the row immediately below the rotating shaft of the rotating drum 21. Further, as the endless belt 33 is rotated by the transport motor 35, the pushing fingers 34 in the row immediately below the rotating shaft of the rotating drum 21 move toward the slit 14 on the downstream side in the X-axis direction. The article 2 that has fallen on the transport table 10 is pushed from the upstream side by the pushing finger 34 and sent. Then, the article 2 pushed by the pushing finger 34 reaches the intermediate portion 12 of the carrying table 10 and is supplied to the second carrying device 40.

  During the steady operation of the packaging system 1, the rotation speed of the transport motor 35 is controlled by the control unit 70 (see FIG. 3), so that the transport speed, the supply cycle, and the supply speed of the article 2 by the first transport device 30 are changed. It is controlled (driving process). The transport speed of the article 2 by the first transport device 30 is V1 [mm / sec], the supply cycle of the article 2 by the first transport device 30 is T1 [sec], and the supply speed of the article 2 by the first transport device 30 is Assuming that N1 [1 / sec] and the pitch of the pushing fingers 34 (the pitch of the suction nozzles 23 arranged in the X-axis direction) is L1 [mm], V1 = L1 / T1 = L1 × N1. Since the pitch of the pushing fingers 34 is fixed to L1, the pitch of the articles 2 transported by the first transport device 30 is also fixed to L1. That is, the first transport device 30 cannot adjust and control the pitch of the articles 2 during operation. Note that, as described above, the row of the articles 2 transported by the first transport apparatus 30 may be missing, and, of course, the interval between the articles 2 adjacent to each other across the missing portion is wider than L1.

  Here, the pushing finger 34 for pushing the article 2 on the most upstream side (but may be missing as described above) in the row 3 of the articles 2 dropped from the suction nozzle 23 is provided by the suction nozzle 23 in the X-axis direction. The timing of passing below the head 23a (the most downstream side in the X-axis direction) of the row is synchronized with the timing at which the suction nozzles 23 in the row adjacent to the row in the circumferential direction face downward and release the article 2. That is, assuming that the number of suction nozzles 23 arranged in the X-axis direction is J0, T1 = T0 / J0 and N1 = N0 × J0. Therefore, during the steady operation of the packaging system 1, the transport motor 35 and the rotary motor 22 are tuned by the control unit 70 so that the supply cycle T1 of the first transport device 30 and the supply cycle T0 of the supply device 20 satisfy this relationship. It is controlled (driving process).

When the article 2 pushed by the pushing finger 34 reaches the intermediate portion 12 of the transport table 10, the article 2 passes below the article sensor 61, and the article 2 is detected by the article sensor 61.
In addition, the surface of the article 2 pushed by the pushing finger 34 is inspected by an inspector (for example, an electronic camera) 66. Removed. Therefore, the row of the articles 2 transported by the first transport device 30 is missing. The defective article exclusion mechanism 67 is a blower that blows out the defective article 2, an air cylinder (or solenoid) that projects the defective article 2, or a pickup mechanism that picks up the defective article 2. Here, the inspection device 66 is provided downstream of the supply device 20 in the X-axis direction, and the defective product exclusion mechanism 67 is provided downstream of the inspection device 66 in the X-axis direction.

7. Second transport device FIG. 7 is a side view of the second transport device 40, and FIG. 8 is a plan view of the second transport device 40. As shown in FIGS. 7 and 8, the second transfer device 40 includes a rounded rectangular (oval) guide 41 provided below the intermediate portion 12 and the downstream portion 13 of the transfer table 10, and a guide 41. A plurality of moving bodies (running bodies) 42 attached and provided movably along the guides 41, pushing fingers 43 provided on each moving body 42, and these moving bodies 42 are independently guided by the guides 41. And a linear motor 46 for individually driving these moving bodies 42 so as to move the moving bodies 42 along.

  The guide 41 includes an upper outward path portion 41a formed linearly so as to extend in the X-axis direction, a downstream descending orbit portion 41b formed in a convex arc shape downstream in the X-axis direction, and an X-axis direction. And a lower return path portion 41c formed linearly so as to extend in the X-axis direction, and an upstream rising track portion 41d formed in a convex arc shape toward the upstream side in the X-axis direction.

  The outward path portion 41a extends horizontally along the slit 14 from below the upstream portion of the slit 14 of the transport table 10. The ascending track portion 41d is arranged below the upstream portion of the slit 14, and extends downward in a semicircular shape from the upstream end portion of the outward route portion 41a. The descending track portion 41b is disposed below the downstream portion of the slit 14, and extends downward in a semicircular shape from the downstream end of the outward route portion 41a. The return path section 41c is provided below the forward path section 41a in parallel with the forward path section 41a, and is provided so as to connect the lower ends of the upward track section 41d and the downward track section 41b.

  The moving body 42 is formed in a gate shape or a U-shape (U-shape), and is supported by the guide 41 so as to straddle the outer peripheral surface of the guide 41 horizontally. A traveling roller is rotatably provided inside the moving body 42. When the running roller rolls with respect to the guide 41, the moving body 42 moves smoothly along the guide 41.

  The moving body 42 is provided with a pushing finger 43. A pushing finger 43 provided on the moving body 42 guided by the outward path 41 a of the guide 41 projects upward from the slit 14. Here, the pushing finger 43 is provided so as to be swingable on the moving body 42, the pushing finger 43 is provided with a cam follower, the groove cam is provided along the guide 41, and the cam follower is guided by the groove cam. Good. In this case, when the moving body 42 moves along the rising orbit part 41d or the descending orbit part 41b of the guide 41, the pushing finger 43 swings with respect to the moving body 42 by the cam follower and the groove cam, so that the pushing is performed. The finger 43 maintains a posture standing upright with respect to the horizontal plane.

  The linear motor 46 has a stator 44 attached to the inner peripheral side of the guide 41 so as to extend along the guide 41, and a mover 45 provided on the moving body 42, respectively. The stator 44 is provided in a rounded rectangle smaller than the guide 41, and the upper straight portion 44 a and the lower straight portion 44 c of the stator 44 are arranged in parallel with the forward path 41 a and the backward path 41 c of the guide 41, respectively. The arc portion 44b and the arc portion 44d are arranged concentrically with the descending orbit portion 41b and the ascending orbit portion 41d of the guide 41, respectively. A mover 45 is provided inside the moving body 42 and faces the stator 44 in the Y-axis direction. Either the mover 45 or the stator 44 has an armature, and the other has a field system such as a permanent magnet.

  Since the movable element 45 is provided on each of the movable bodies 42, these movable bodies 42 are driven by the linear motor 46 independently of each other. By controlling the sequence of the linear motor 46 by the control unit 70, the position and the moving speed of each moving body 42 are controlled, and the moving body 42 is propelled along the guide 41 by the linear motor 46. Here, the control unit 70 recognizes the position and the moving speed for each moving body 42 by mutual communication between the linear motor 46 and the control unit 70.

  The moving direction of the moving body 42 by the linear motor 46 is clockwise when viewed from the side as shown in FIG. That is, the moving body 42 moves the forward path 41a of the guide 41 downstream in the X-axis direction, moves the descending track 41b downward, moves the return path 41c upstream in the X direction, and moves the upward track 41d upward. Moving.

  During the steady operation of the packaging system 1, the plurality of moving bodies 42 are on standby in a state of being arranged along the upstream portion of the return path 41c and the ascending track 41d, and the upper part of the ascending track 41d (position P1). Is moved around the guide 41 by the linear motor 46 in the following manner.

  That is, when the article 2 pushed by the pushing finger 43 is detected by the article sensor 61 (hereinafter, the detected article 2 is referred to as the specific article 2), the specific moving body 42 is moved from the upper part of the ascending orbit part 41d to the forward path part. The pushing finger 43 of the specific moving body 42 (hereinafter, this pushing finger 43 is referred to as the specific finger 43) moves upward from the slit 14 on the upstream side of the specific article 2 at that time. Stick out. At this time, the specific article 2 slides down from the intermediate section 12 to the upstream end of the downstream section 13 due to the inclination of the intermediate section 12, and the pushing finger 34 that has pushed the specific article 2 moves in the circumferential direction of the second pulley 32. Then, the specific article 2 and the pushing finger 34 that pushed it are separated. Thereby, the specific article 2 is supplied from the first transport device 30 to the second transport device 40. When the specific moving body 42 moves from the upper part of the ascending orbit portion 41d to the upstream end (position P2) in the X-axis direction of the outward path portion 41a, the following moving body 42 has a distance corresponding to the integral length of the moving body 42. Only after moving forward (clockwise direction in FIG. 7).

  Then, since the specific moving body 42 moves downstream from the position P2 in the X-axis direction, the specific article 2 is pushed from behind by the specific finger 43 and sent. At this time, the specific moving body 42 catches up with the preceding moving body 42, so that the space between the specific article 2 and the article 2 to be transported earlier than the specific article 2 is reduced. If the moving speed of the specific moving body 42 at this time is V2 [mm / sec], then V2> V1.

  Thereafter, when the distance between the specific moving body 42 and the preceding moving body 42 reaches a predetermined value L3 [mm], the specific moving body 42 has a speed V3 [mm / sec] equal to the moving speed of the preceding moving body 42. Slow down. Therefore, the specific moving body 42 follows the preceding moving body 42 at the moving speed V3 while maintaining the distance from the preceding moving body 42 at the predetermined value L3. Note that V3 <V2.

  After that, the specific moving body 42 descends along the descending orbit portion 41b after reaching the downstream end (position P3) in the X-axis direction of the outward path portion 41a. Pull down. At this time, the specific article 2 is separated from the specific finger 43 of the specific moving body 42 and is supplied from the transport table 10 to the packaging device 50 (specifically, a former 52 described later).

  Then, after reaching the descending orbit portion 41b, the specific moving body 42 moves along the return route portion 41c at a speed higher than the speed V3. Then, when the specific moving body 42 reaches the rear of the rear end of the moving bodies 42 arranged in the return path section 41c, the specific moving body 42 stands by in the line.

  The above is the operation of one cycle of the specific moving body 42 during the steady operation of the packaging system 1, and the control section 70 controls the linear motor 46 to rotate the specific moving body 42 as described above (operating processing). In addition, the control unit 70 controls the linear motor 46 so that the moving body 42 subsequent to the specific moving body 42 also moves in a similar manner one by one, so that each time the article 2 is detected by the article sensor 61, The head of the moving body 42 arranged after P1 starts (moves) and goes around the guide 41 via the positions P2 and P3 (driving process). Therefore, during the steady operation of the packaging system 1, the articles 2 supplied from the first transport device 30 to the second transport device 40 are sequentially transported one by one to the downstream end of the transport table 10 in the X-axis direction, and the packaging is performed. It is supplied to the device 50.

  Here, when a drop occurs in the row of the articles 2 being conveyed by the first conveyance device 30 and the articles 2 do not exist between the adjacent pushing fingers 34, the articles 2 are not detected by the article sensor 61. , The head moving body 42 located at the position P1 waits without departure from the position P1. Thereafter, when the article 2 is detected by the article sensor 61, the moving body 42 moves as described above, and the article 2 is pushed by the pushing finger 43 of the moving body 42. Therefore, even if an article is missing in the first transporting device 30, a plurality of items are located on the upstream side of the packaging device 50 (specifically, in the section S in which the moving bodies 42 are arranged while moving at the moving speed V3). The articles 2 are always conveyed in a state of being arranged at equal intervals and supplied to the packaging apparatus 50. By the second transport device 40, the articles 2 can be packed and supplied to the packaging device 50 by the missing amount. Therefore, even if a row of the articles 2 being transported by the first transport device 30 is missing, the occurrence of empty packages 5 can be suppressed without temporarily stopping the packaging device 50.

  Here, since the conveying speed of the article 2 is equal to the moving speed V3 of the moving body 42 and the pitch of the article 2 is also equal to the pitch L3 of the moving body 42, the supply cycle of the article 2 by the second conveying device 40 is T3 [sec]. Assuming that the supply speed of the article 2 is N3 [1 / sec], V3 = L3 / T3 = L3 × N3.

  When a drop occurs in the row of the articles 2 being conveyed by the first conveyance device 30, the moving body 42 does not start moving from the position P1, and therefore the articles 2 and the moving body 42 in the section S decrease every time a drop occurs. I do. Therefore, if the operation time of the packaging system 1 is long, the article 2 and the moving body 42 may not be present in the section S, and the supply of the article to the packaging apparatus 50 may be lost, and the empty packaged product may be lost. 5 may be produced. However, in the present embodiment, the numbers of the articles 2 and the moving bodies 42 in the section S do not become zero. This will be described in detail later (“9. Speed control / cycle control (first example)”, “10. Speed control / cycle control (second example)”, “11. Speed control / cycle control (third example)”. Example) "," 12. Speed control / cycle control (fourth example) "," 13. Speed control / cycle control (fifth example) ", and" 14. Speed control / cycle control (sixth example) ") .

  The article sensors 62, 63, and 64 detect the presence or absence of the article 2 thereunder. The article sensors 62, 63, 64 perform detection periodically, and the detection cycle of the article sensors 62, 63, 64 is equal to the supply cycle T3 and the packaging cycle T4 of the second transport device 40. Accordingly, if the row of the articles 2 in the section S exceeds the article sensors 62 to the upstream side in the X-axis direction even though the moving body 42 and the articles 2 sequentially pass below the article sensors 62, the article sensors 62 The articles 2 are detected, but the articles 2 are not detected by the article sensors 62 unless the row of the articles 2 exceeds the article sensor 62 on the upstream side in the X-axis direction. The same applies to the article sensors 63 and 64.

8. Packaging Device FIG. 9 is a side view of the packaging device 50, and FIG. 10 is a plan view of the packaging device 50. The packaging device 50 includes a film supply machine 51, a former (bag making machine) 52, a receiving plate 53, a vertical sealing machine (center sealing machine) 54, a horizontal sealing machine (end sealing machine) 55, an unloading machine 56, and the like. .

The plurality of articles 2 are sequentially supplied to the former 52 by the second transport device 40 as described above. Further, the belt-shaped film 6 is continuously supplied to the former 52 by the film feeder 51, and is conveyed from the former 52 to the horizontal sealing machine 54 via the vertical sealing machine 54. When the film 6 is continuously rounded into a flat cylindrical shape by the former 52, the vertical stitches 7 on both sides of the film 6 overlap and the article 2 is wrapped in the film 6. On the downstream side of the former 52, the vertical stitches 7 of the rolled film 6 are continuously sealed by the vertical sealing machine 54 and hermetically closed. Thereafter, a portion between the articles 2 is sealed by the horizontal sealing machine 55 and cut. As a result, the horizontal stitch 8 is formed at a portion between the articles 2. The package 5 thus produced is transported downstream by the unloader 56.
Hereinafter, each component of the packaging device 50 will be described in detail.

  A pair of horizontal receiving plates 53 are provided on the downstream side of the transfer table 10 in the X-axis direction so that the heights thereof are aligned with the upper surface of the downstream portion 13 of the transfer table 10. The pair of receiving plates 53 are arranged in the Y-axis direction, and a slit (gap) is formed between these receiving plates 53. A former 52 is provided between the transport table 10 and the receiving plate 53, and the former 52 is disposed at the second delivery point P2, that is, at the downstream end of the transport table 10 in the X-axis direction. Therefore, the article 2 pushed to the downstream end in the X-axis direction of the transport table 10 by the pushing finger 43 is supplied to the former 52.

  The film feeder 51 is provided with a pinch roll 51b that turns the belt-shaped film 6 fed from the raw roll 51a and guides the folded film 6 to the former 52, and a feed motor 51c that rotates the pinch roll 51b. When the pinch roll 51b is driven to rotate by the feed motor 51c, the film 6 is fed out from the raw roll 51a and supplied to the former 52. Then, the film 6 passes through the former 52 and is transported downstream in the X-axis direction.

  When the band-shaped film 6 passes through the former 52 downstream in the X-axis direction, both side portions (hereinafter, referred to as vertical stitches 7) of the film 6 are bent downward by the former 52 and overlapped, and the overlapped portions are formed. The vertical binding 7 passes between the pair of receiving plates 53 and protrudes below the receiving plates 53. As a result, the film 6 is rounded into a flat cylindrical shape by the former 52, and the article 2 pushed to the former 52 by the pushing finger 43 enters the inside of the cylindrically rounded film 6. On the downstream side of the former 52 in the X-axis direction, a plurality of articles 2 sequentially supplied by the second transport device 40 are arranged on the receiving plate 53 in the longitudinal direction (X-axis direction) of the tubular film 6. The film 6 is conveyed downstream by following the film 6. Here, the transport speed of the film 6 and the article 2 inside the film 6 is controlled by controlling the rotation speed of the feed motor 51c by the control unit 70. Assuming that the transport speed of the film 6 and the article 2 inside the film 6 is V4 [mm / sec], V4 <V2. If the transport speed V4 is equal to the moving speed V3 of the moving body 42 in the section S, the pitch of the articles 2 inside the film 6 is equal to the pitch L3 of the moving body 42 in the section S. Note that the transport speed V4 and the moving speed V3 do not have to be equal.

  The vertical sealing machine 54 is provided on the downstream side of the former 52 and below the receiving plate 53. This vertical sealing machine 54 seals by heating while vertically sandwiching the vertical stitches 7 projecting downward from between the pair of receiving plates 53 from both sides. In the illustrated example, the vertical sealing machine 54 includes a pair of left and right rod heaters 54a provided below the receiving plate 53, and a pair of press rollers 54b provided downstream of the rod heater 54a. The vertical binding 7 is heated by passing through the gap between the pair of rod-shaped heaters 54a. The heated vertical stitch 7 is sandwiched by the press roller 54b at a predetermined pressure, whereby the vertical stitch 7 is sealed. When the sealed vertical stitches 7 are conveyed from the vertical sealing machine 54 to the horizontal sealing machine 55, they are folded so as to contact the lower surface of the cylindrical film 6. A pinch roll sandwiching the vertical stitch 7 is provided below the receiving plate 53 and upstream or downstream of the vertical sealing machine 54, and the pinch roll is rotated by the feed motor 51c. The film 6 may be conveyed.

  A horizontal sealing machine 55 is provided downstream of the vertical sealing machine 54 in the X-axis direction, and the film 6 and the articles 2 inside the film 6 pass through the horizontal sealing machine 55 downstream in the X-axis direction. The horizontal sealing machine 55 performs intermittent thermocompression bonding on the cylindrical film 6. The timing at which the horizontal sealing machine 55 thermocompression-bonds the tubular film 6 is between the time when the article 2 passes through the horizontal sealing machine 55 and the time when the next article 2 passes through the horizontal sealing machine 55.

  The horizontal sealing machine 55 is a rotary sealing machine. That is, the horizontal sealing machine 55 includes rotating shafts 55a and 55b rotatably provided on the upper and lower sides of the transport path of the film 6, and pressing portions 55c and 55d provided on the rotating shafts 55a and 55b, respectively. A drive motor 55g for rotating and driving the rotating shafts 55a and 55b, a heater built in each of the press contact portions 55c and 55d, and cutting blades 55e and 55f provided in the press contact portions 55c and 55d, respectively, are provided. When the rotating shafts 55a and 55b are driven to rotate by the drive motor 55g, the press contact portions 55c and 55d move up and down from each other. Specifically, after the article 2 has passed downstream between the rotating shafts 55a and 55b, before the next article 2 has passed downstream between the rotating shafts 55a and 55b, the press contact portions 55c and 55d The film 6 is sandwiched between them. As a result, the cylindrical film 6 at the portion between the article 2 before passing through the press-contact portions 55c and 55d and the article 2 after passing through the press-contact portions 55c and 55d is pressed and heated by the press-contact portions 55c and 55d to form the horizontal stitches 8. Further, the horizontal stitch 8 is cut by the cutting blades 55e and 55f. Thereby, the package 5 is completed and is separated from the film 6 on the upstream side of the horizontal sealing machine 55.

  Note that the horizontal sealing machine 55 may be a box motion type sealing machine instead of a rotary sealing machine in which the press contact portions 55c and 55d rotate around the rotation shafts 55a and 55b. When the horizontal sealing machine 55 is a box motion type sealing machine, the power of the drive motor 55g is converted by the transmission mechanism into the power of the periodic contact / separation movement of the press contact portions 55c and 55d. Thereby, the pressing portions 55c and 55d move downstream in the X-axis direction at the same speed as the film 6 with the film 6 sandwiched therebetween, and the X-axis while the pressing portions 55c and 55d are separated from each other. The movement to the upstream side in the direction is alternately repeated. When the transverse sealing machine 55 is a box motion type sealing machine, the cutting blade 55f is not provided, and when the press contact portions 55c and 55d sandwich the film 6, the cutting blade 55e is moved by the direct drive mechanism to the press contact portion 55c. The film 6 is lowered by protruding into the press contact portion 55d from the inside thereof to cut the film 6, and when the press contact portions 55c and 55d are separated from each other, the cutting blade 55e is drawn into the press contact portion 55c.

  Here, the packaging cycle of the packaging apparatus 50 refers to an intermittent thermocompression cycle of the horizontal sealing machine 55. In other words, the time from when the pressure contact portions 55c and 55d approach each other and hit each other is the packaging cycle of the packaging device 50. Assuming that the packaging cycle of the packaging device 50 is T4 [sec] and the packaging speed is N4 [1 / sec], N4 = 1 / T4, and L5 / T4 = L5 × N4 = V4. By controlling the rotation speed of the drive motor 55g by the control unit 70, the packaging cycle T4 and the packaging speed N4 are controlled. The packaging cycle T4 is equal to the supply cycle T3 [sec] of the article 2 by the second transport device 40, and the packaging speed N4 is equal to the supply speed N3 of the article 2 by the second transport device 40. The drive unit 55g and the feed motor 51c are tuned and controlled by the control unit 70 so that the lengths L5 of all the completed packages 5 are equal (operation process).

  On the downstream side of the horizontal sealing machine 55, a belt conveyor type unloader 56 is provided. The package 5 separated by the horizontal sealing machine 55 is conveyed by the unloader 56 to the downstream side in the X-axis direction. The transport speed of the unloader 56 is controlled by the controller 70 to be equal to or higher than the transport speed V4 of the film 6.

9. Speed / cycle control (first example)
During the steady operation of the packaging system 1, the supply device 20, the first transport device 30, the second transport device 40, and the packaging device 50 are controlled by the control unit 70 as follows.

9-1. Constant speed control The packaging device 50 is operated at a constant speed by the control unit 70. In other words, the control unit 70 controls the feed motor 51c and the drive motor 55g at a constant speed, so that the transport speed V4 of the film 6 and the article 2 inside the film 6 is kept constant, and the packaging cycle T4 and the packaging speed N4 are kept constant. Is maintained. Therefore, the tension of the film 6 is appropriately maintained, and the occurrence of wrinkles can be prevented. Further, it is possible to prevent the article 2 from slipping in the transport direction with respect to the film 6 (if the transport speed V4 of the film 6 changes, the article 2 may slip on the film 6 due to inertial force).

  When the control unit 70 controls the linear motor 46 of the second transport device 40, the moving speed V3, the supply cycle T3, and the supply speed N3 of the moving body 42 in the section S are kept constant. Here, as described above, the control unit 70 controls the linear motor 46, the feed motor 51c, and the drive motor 55g such that the supply cycle T3 and the packaging cycle T4 are equal, and the supply speed N3 and the packaging speed N4 are equal.

  When the control unit 70 controls the linear motor 46, the timing at which the moving body 42 descends from the downstream end (position P3) of the forward path 41a in the X-axis direction is a predetermined phase of the rotation cycle of the feed motor 51c and the drive motor 55g. Sync to. Therefore, the timing at which the article 2 is supplied from the second transport device 40 (in particular, the transport table 10) to the packaging device 50 (in particular, the former 52) is synchronized with a predetermined phase of the packaging cycle T4. Thereby, the article 2 is not bitten by the press contact portions 55c and 55d of the horizontal sealing machine 55.

9-2. Shift Control As described above, the transport motor 35 and the rotary motor 22 are tuned and controlled by the control unit 70, and the supply speed N1 of the first transport device 30 and the supply speed N0 of the supply device 20 satisfy “N1 = N0 × J0”. . Here, the control unit 70 executes the following count processing and comparison / shift processing at every predetermined cycle T [sec], so that the supply speed N1 and the supply speed N0 change at every predetermined cycle T as follows. I do. This predetermined period T is sufficiently longer than the supply period T1 of the first transport device 30. For example, if the packaging speed N4 is 7.5 [1 / sec], the supply period T1 is set to about 2 to 20 seconds.

  When the predetermined period T starts, the control unit 70 performs a counting process until the end of the predetermined period T (see FIG. 11). That is, the control unit 70 resets the count value (count value) A to zero at the start of the predetermined cycle T (step S1), and until the end of the predetermined cycle T (step S4: YES), the article sensor 61 Each time a detection signal is input from (step S2: YES), 1 is added to the count value A (step S3). Therefore, each time the article 2 passes under the article sensor 61, the count value A increases by one, and the number of articles 2 passing under the article sensor 61 during the predetermined period T is counted. The control unit 70 repeatedly executes such a counting process.

  When the predetermined period T ends, the control unit 70 executes a comparison / shift process (see FIG. 12). That is, the control unit 70 compares the count value A counted in the count process with the predetermined upper threshold A1 and lower threshold A2 (steps S11 and S12). Here, A1> N4 × T> A2> 0.

  As a result of the comparison, when the count value A exceeds the upper threshold value A1 (step S11: YES), the control unit 70 reduces the rotation speeds of the transport motor 35 and the rotation motor 22 by a predetermined difference. Then, the supply speed N1 of the first transport device 30 decreases by the predetermined difference ΔN1, and the supply speed N0 of the supply device 20 decreases by the predetermined difference ΔN0 (step S13). That is, if the supply speed N1 of the first transport device 30 before the speed change is higher than the packaging speed N4 of the packaging device 50, or if there is almost no loss in the row of articles being transported by the first transport device 30, Since the article 2 is excessively supplied from the first transport device 30 to the second transport device 40 (step S11: YES), the operation speeds of the supply device 20 and the first transport device 30 are reduced (step S13).

  On the other hand, as a result of the comparison, when the count value A is less than the lower threshold value A2 (step S12: YES), the control unit 70 increases the rotation speeds of the transport motor 35 and the rotation motor 22 by a predetermined difference. Then, the supply speed N1 of the first transport device 30 increases by the predetermined difference ΔN1, and the supply speed N0 of the supply device 20 increases by the predetermined difference ΔN0 (step S14). That is, if the supply speed N1 of the first transport device 30 before the speed change is lower than the packaging speed N4 of the packaging device 50, or if there are many missing items in the row of articles being transported by the first transport device 30, Since the supply of articles from one transport device 30 to the second transport device 40 is insufficient (step S12: YES), the operating speeds of the supply device 20 and the first transport device 30 are increased (step S14).

  On the other hand, as a result of the comparison, when the count value A is equal to or more than the lower threshold value A2 and equal to or less than the upper threshold value A1 (steps S11 and S12: NO), the control unit 70 maintains the rotation speed of the transport motor 35 and the rotation motor 22. Then, the supply speed N1 of the first transport device 30 and the supply speed N0 of the supply device 20 are maintained (Step S15). That is, regardless of the supply speed N1 of the first transport device 30 or the packaging speed N4 of the packaging device 50 before step S15, regardless of whether or not the row of articles being transported by the first transport device 30 is missing, If the number of articles 2 supplied from one transport device 30 to the second transport device 40 is appropriate for the packaging speed N4 of the packaging device 50 (steps S11, S12: NO), the supply device 20 and the first transport device 30 The operation speed is maintained (Step S15).

  The control unit 70 executes the above-described comparison / shift process each time one count process is completed.

  As described above, the number of articles 2 actually supplied per unit time from the first transport apparatus 30 to the second transport apparatus 40 due to lack of the article row being transported by the first transport apparatus 30 is reduced. Even if it is not stable, a stable number of articles 2 are arranged and pooled on the upstream side of the packaging device 50. Therefore, even if the packaging system 1 is operated for a long period of time, the supply of articles from the second transport device 40 to the packaging device 50 does not drop out, and an empty package 5 is not produced. That is, the yield of the production of the package 5 is very high.

When the control unit 70 repeatedly executes the count process and the comparison / shift process, even if the count value A is less than the lower threshold value A2 (step S12: YES), the first transport device before the speed increase in step S14. When the supply speed N1 of the motor 30 is a predetermined maximum value _N1max [1 / sec], the control unit 70 maintains the rotation speed of the transport motor 35 and the rotation motor 22. If this state is continued, the articles 2 and the moving bodies 42 in the section S decrease. Then, since the article 2 is no longer detected by the article sensor 64, the control unit 70 executes the on-demand operation processing. The on-demand operation process means that the control unit 70 temporarily stops the feed motor 51c and the drive motor 55g of the packaging device 50 each time the article sensor 64 stops detecting the article 2 and the article sensor 64 detects the article 2. Then, the control unit 70 drives the feed motor 51c and the drive motor 55g for a time equal to the packaging cycle T4. That is, during the on-demand operation process, every time the article sensor 64 detects the article 2, the packaging device 50 performs an operation only for producing the integrated package 5.

10. Speed / cycle control (second example)
During the steady operation of the packaging system 1, the supply device 20, the first transport device 30, the second transport device 40, and the packaging device 50 are controlled by the control unit 70 as follows.

10-1. Constant Speed Control The control unit 70 performs the same control as “9-1. Constant Speed Control”.

10-2. Shift Control As described above, the transport motor 35 and the rotary motor 22 are tuned and controlled by the control unit 70, and the supply speed N1 of the first transport device 30 and the supply speed N0 of the supply device 20 satisfy “N1 = N0 × J0”. . Here, the control unit 70 counts the number of the moving bodies 42 arrayed while moving at the moving speed V3 in the section S on the upstream side of the packaging device 50 for each supply cycle T3 or an integral multiple thereof. The rotation speed of the transport motor 35 and the rotation motor 22 is controlled based on the count value B. Therefore, the supply speed N1 and the supply speed N0 change in the supply cycle T3 or every integral multiple thereof as follows. Since the control unit 70 recognizes the position and the moving speed for each moving body 42 as described above, the control unit 70 can count the number of the moving bodies 42 in the section S.

  Specifically, control unit 70 compares count value B with predetermined upper threshold value B1 and lower threshold value B2. Here, B1> B2> 0, B1 is equal to the number of moving bodies 42 arranged at the pitch L3 from the position P3 to below the article sensor 62, and B2 is below the article sensor 63 from the position P3. Up to the number of moving bodies 42 arranged at the pitch L3.

  As a result of the comparison, when the count value B exceeds the upper threshold value B1, the control unit 70 reduces the rotation speeds of the transport motor 35 and the rotation motor 22 by a predetermined difference. Then, the supply speed N1 of the first transport device 30 decreases by the predetermined difference ΔN1, and the supply speed N0 of the supply device 20 decreases by the predetermined difference ΔN0. That is, since the articles 2 are long arranged in the section S on the upstream side of the packaging device 50 before the gear shifting, the operating speed of the supply device 20 and the first transport device 30 is reduced. As a result, the row of the articles 2 in the section S thereafter does not become longer or gradually becomes shorter.

  On the other hand, as a result of the comparison, when the count value B is less than the lower threshold B2, the control unit 70 increases the rotation speeds of the transport motor 35 and the rotation motor 22 by a predetermined difference. Then, the supply speed N1 of the first transport device 30 increases by the predetermined difference ΔN1, and the supply speed N0 of the supply device 20 increases by the predetermined difference ΔN0. That is, since the articles 2 are arranged short in the section S on the upstream side of the packaging device 50 before the gear shifting, the operating speeds of the supply device 20 and the first transport device 30 are increased. Thereby, the row of the articles 2 in the section S thereafter does not become shorter any longer or gradually becomes longer.

  On the other hand, as a result of the comparison, when the count value B is equal to or larger than the lower threshold B2 and equal to or smaller than the threshold B1, the control unit 70 maintains the rotation speeds of the transport motor 35 and the rotation motor 22. Then, the supply speed N1 of the first transport device 30 and the supply speed N0 of the supply device 20 are maintained. That is, since the arrangement of the articles 2 in the section S on the upstream side of the packaging device 50 has an appropriate length, the operation speed of the supply device 20 and the first transport device 30 is maintained.

  Therefore, the row of the articles 2 being transported by the first transport apparatus 30 is missing, and the number of articles 2 actually supplied per unit time from the first transport apparatus 30 to the second transport apparatus 40 is stable. Even if this is not done, a stable number of articles 2 are arranged upstream of the packaging device 50 and kept in a pooled state. Therefore, no omission occurs in the supply of the articles from the second transport apparatus 40 to the packaging apparatus 50, and the package 5 having no articles is not produced. That is, the yield of the production of the package 5 is very high.

In addition, when the above-mentioned shift control is continued, even if the count value B is less than the lower threshold value B2, the supply speed N1 of the first transport device 30 before the speed increase is set to the predetermined maximum value N1 _max [1 / [sec], the control unit 70 maintains the rotation speed of the transport motor 35 and the rotation motor 22. If this state is continued, the articles 2 and the moving bodies 42 in the section S decrease. Then, since the article 2 is no longer detected by the article sensor 64, the control unit 70 executes the on-demand operation processing. The on-demand operation processing is as described above.

11. Speed / cycle control (third example)
During the steady operation of the packaging system 1, the supply device 20, the first transport device 30, the second transport device 40, and the packaging device 50 are controlled by the control unit 70 as follows.

11-1. Constant Speed Control The control unit 70 performs the same control as “9-1. Constant Speed Control”.

11-2. Shift Control As described above, the transport motor 35 and the rotary motor 22 are tuned and controlled by the control unit 70, and the supply speed N1 of the first transport device 30 and the supply speed N0 of the supply device 20 satisfy “N1 = N0 × J0”. . Here, the control unit 70 monitors the outputs of the article sensors 62 and 63 at every supply cycle T3 or an integer multiple thereof, and based on the outputs of the article sensors 62 and 63, controls the rotation speeds of the transport motor 35 and the rotation motor 22. Control. Therefore, the supply speed N1 and the supply speed N0 change in the supply cycle T3 or every integral multiple thereof as follows.

  Specifically, as shown in the truth table of FIG. 13, when the article 2 is detected by both of the article sensors 62 and 63 and the detection signal is input to the control unit 70, the control unit 70 And the rotation speed of the rotation motor 22 is reduced by a predetermined difference. Then, the supply speed N1 of the first transport device 30 decreases by the predetermined difference ΔN1, and the supply speed N0 of the supply device 20 decreases by the predetermined difference ΔN0. That is, since the articles 2 are long arranged in the section S on the upstream side of the packaging device 50 before the gear shifting, the operating speed of the supply device 20 and the first transport device 30 is reduced. Thereby, whether the row of the articles 2 in the section S thereafter becomes longer or gradually shorter.

  On the other hand, since the article 2 is not detected by both of the article sensors 62 and 63 and the detection signal is not input to the control unit 70, the control unit 70 increases the rotation speeds of the transport motor 35 and the rotation motor 22 by a predetermined difference. . Then, the supply speed N1 of the first transport device 30 increases by the predetermined difference ΔN1, and the supply speed N0 of the supply device 20 increases by the predetermined difference ΔN0. That is, since the articles 2 are arranged short in the section S on the upstream side of the packaging device 50 before the gear shifting, the operating speeds of the supply device 20 and the first transport device 30 are increased. Thereby, the row of the articles 2 in the section S thereafter does not become shorter any longer or gradually becomes longer.

  On the other hand, when the article 2 is detected by the article sensor 62 on the upstream side and the article 2 is detected by the article sensor 63 on the downstream side, a detection signal is input from the article sensor 63 to the control unit 70. Is not input to the control unit 70 from the control unit 70, the control unit 70 maintains the rotation speed of the transport motor 35 and the rotation motor 22. Then, the supply speed N1 of the first transport device 30 and the supply speed N0 of the supply device 20 are maintained. That is, since the arrangement of the articles 2 in the section S on the upstream side of the packaging device 50 has an appropriate length, the operation speed of the supply device 20 and the first transport device 30 is maintained.

  Therefore, the row of the articles 2 being transported by the first transport apparatus 30 is missing, and the number of articles 2 actually supplied per unit time from the first transport apparatus 30 to the second transport apparatus 40 is stable. Even if this is not done, a stable number of articles 2 are arranged upstream of the packaging device 50 and kept in a pooled state. Therefore, no omission occurs in the supply of the articles from the second transport apparatus 40 to the packaging apparatus 50, and the package 5 having no articles is not produced. That is, the yield of the production of the package 5 is very high.

It should be noted that even when the article 2 is not detected by both of the article sensors 62 and 63 while the above-described shift control is continued, the supply speed N1 of the first transport device 30 before the speed increase is increased to a predetermined maximum. When the value is N1 _max [1 / sec], the control unit 70 maintains the rotation speed of the transport motor 35 and the rotation motor 22. If this state is continued, the articles 2 and the moving bodies 42 in the section S decrease. Then, since the article 2 is no longer detected by the article sensor 64, the control unit 70 executes the on-demand operation processing. The on-demand operation processing is as described above.

12. Speed / cycle control (fourth example)
During the steady operation of the packaging system 1, the supply device 20, the first transport device 30, the second transport device 40, and the packaging device 50 are controlled by the control unit 70 as follows.

12-1. Constant speed control The supply device 20 and the first transfer device 30 are operated at a constant speed. That is, the control unit 70 controls the rotation motor 22 and the conveyance motor 35 at a constant speed, so that the rotation speed n of the rotation drum 21 of the supply device 20 and the conveyance speed V1 of the first conveyance device 30 are maintained constant. The supply speed N0 and the supply period T0 of the supply device 20 and the supply speed N1 and the supply period T1 of the first transport device 30 are kept constant. Here, as described above, the transport motor 35 and the rotary motor 22 are tuned and controlled by the control unit 70, and the supply speed N1 of the first transport device 30 and the supply speed N0 of the supply device 20 are set to “N1 = N0 × J0”. Fulfill.

12-2. Shift control As described above, the control unit 70 controls the linear motor 46, the feed motor 51c, and the drive motor 55g such that the supply cycle T3 and the packaging cycle T4 are equal, and the supply speed N3 and the packaging speed N4 are equal. Further, when the control unit 70 controls the linear motor 46, the timing at which the moving body 42 descends from the downstream end (position P3) in the X-axis direction of the forward path 41a is determined by the rotation cycle of the feed motor 51c and the drive motor 55g. Synchronize with a predetermined phase. Therefore, the timing at which the article 2 is supplied from the second transport device 40 (in particular, the transport table 10) to the packaging device 50 (in particular, the former 52) is synchronized with a predetermined phase of the packaging cycle T4. Thereby, the article 2 is not bitten by the press contact portions 55c and 55d of the horizontal sealing machine 55.

  Here, the control unit 70 executes the following count processing and comparison / shift processing at every predetermined cycle T [sec], so that the supply speed N3 and the packaging speed N4 change at every predetermined cycle T as follows. I do. The predetermined cycle T is sufficiently longer than the supply cycle T1 of the first transport device 30.

  When the predetermined period T starts, the control unit 70 performs a counting process until the end of the predetermined period T (see FIG. 11). This counting process is the same as the counting process described in the section “9-2.

  When the predetermined period T ends, the control unit 70 executes a comparison / shift process (see FIG. 15). That is, the control unit 70 compares the count value A counted in the count process with the predetermined upper threshold value A3 and lower threshold value A4 (steps S21 and S22). Here, A3> N4 × T> A4> 0, but the packaging speed N4 is a value before changing as follows.

  As a result of the comparison, when the count value A exceeds the upper threshold value A3 (step S21: YES), the control unit 70 increases the rotation speeds of the drive motor 55g and the feed motor 51c by a predetermined difference, and the linear motor 46 The moving speed V3 of the moving body 42 is increased by a predetermined difference. Then, the packaging speed N4 of the packaging device increases by the predetermined difference ΔN4, and the supply speed N3 of the second transport device 40 increases by the predetermined difference ΔN3 (step S23). That is, if the packaging speed N4 of the packaging device 50 before the shift is lower than the supply speed N1 of the first transport device 30, or if there is almost no loss in the row of articles being transported by the first transport device 30, Since the article 2 is excessively supplied from the first transport device 30 to the second transport device 40 (step S21: YES), the operating speed of the packaging device 50 is increased accordingly (step S23).

  On the other hand, as a result of the comparison, when the count value A is less than the lower threshold value A4 (step S22: YES), the rotational speeds of the drive motor 55g and the feed motor 51c are reduced by a predetermined difference, and the linear motor 46 controls the moving body 42. The moving speed V3 is reduced by a predetermined difference. Then, the packaging speed N4 of the packaging device decreases by the predetermined difference ΔN4, and the supply speed N3 of the second transport device 40 decreases by the predetermined difference ΔN3 (step S24). That is, if the packaging speed N4 of the packaging device 50 before the shift is higher than the supply speed N1 of the first transport device 30, or if many missing items occur in the row of articles being transported by the first transport device 30, the second Since the supply of articles from one transport device 30 to the second transport device 40 is insufficient (step S22: YES), the operating speed of the packaging device 50 is reduced accordingly (step S24).

  On the other hand, as a result of the comparison, when the count value A is equal to or more than the lower threshold value A4 and equal to or less than the upper threshold value A3 (steps S21 and S22: NO), the control unit 70 maintains the rotational speeds of the drive motor 55g and the feed motor 51c, The moving speed V3 of the moving body 42 by the linear motor 46 is maintained. Then, the packaging speed N4 of the packaging device is maintained, and the supply speed N3 of the second transport device 40 is maintained (step S25). That is, irrespective of the supply speed N1 of the first transport device 30 or the packaging speed N4 of the packaging device 50 before step S25, regardless of whether or not the row of articles being transported by the first transport device 30 is missing, If the number of articles 2 supplied from one transport device 30 to the second transport device 40 is appropriate for the packaging speed N4 of the packaging device 50 (steps S21 and S22: NO), the operation speed of the packaging device 50 is maintained. (Step S25).

  The control unit 70 executes the above-described comparison / shift process each time one count process is completed.

  As described above, the number of articles 2 actually supplied per unit time from the first transport apparatus 30 to the second transport apparatus 40 due to lack of the article row being transported by the first transport apparatus 30 is reduced. Even if it is not stable, a stable number of articles 2 are arranged and pooled on the upstream side of the packaging device 50. Therefore, no omission occurs in the supply of the articles from the second transport apparatus 40 to the packaging apparatus 50, and the package 5 having no articles is not produced. That is, the yield of the production of the package 5 is very high.

When the control unit 70 repeatedly executes the counting process and the comparing / shifting process, even if the count value A exceeds the upper threshold value A3 (step S23: YES), the packaging of the packaging device 50 before the speed increase in step S23. If the speed N4 is a predetermined maximum value N4 _max [1 / sec], together with the control unit 70 maintains the rotational speed of the drive motor 55g and the feed motor 51c, maintain the moving speed V3 of the moving member 42 by the linear motor 46 I do.

13. Speed / cycle control (fifth example)
During the steady operation of the packaging system 1, the supply device 20, the first transport device 30, the second transport device 40, and the packaging device 50 are controlled by the control unit 70 as follows.

13-1. Constant Speed Control Control similar to “12-1. Constant Speed Control” is performed by the control unit 70.

13-2. Shift control As described above, the control unit 70 controls the linear motor 46, the feed motor 51c, and the drive motor 55g such that the supply cycle T3 and the packaging cycle T4 are equal, and the supply speed N3 and the packaging speed N4 are equal. Further, when the control unit 70 controls the linear motor 46, the timing at which the moving body 42 descends from the downstream end (position P3) in the X-axis direction of the forward path 41a is determined by the rotation cycle of the feed motor 51c and the drive motor 55g. Synchronize with a predetermined phase. Therefore, the timing at which the article 2 is supplied from the second transport device 40 (in particular, the transport table 10) to the packaging device 50 (in particular, the former 52) is synchronized with a predetermined phase of the packaging cycle T4. Thereby, the article 2 is not bitten by the press contact portions 55c and 55d of the horizontal sealing machine 55.

  Here, the control unit 70 counts the number of the moving bodies 42 arrayed while moving at the moving speed V3 in the section S on the upstream side of the packaging device 50 for each supply cycle T3 or an integral multiple thereof. Based on the count value B, the rotation speed of the driving motor 55g and the feed motor 51c is controlled, and the moving speed V3 of the moving body 42 by the linear motor 46 is controlled. Therefore, the supply speed N3 and the packaging speed N4 change in the supply cycle T3 or every integral multiple thereof as follows. Since the control unit 70 recognizes the position and the moving speed for each moving body 42 as described above, the control unit 70 can count the number of the moving bodies 42 in the section S.

  Specifically, control unit 70 compares count value B with predetermined upper threshold value B1 and lower threshold value B2. Here, B1> B2> 0.

  As a result of the comparison, when the count value B exceeds the upper threshold value B1, the control unit 70 increases the rotation speeds of the drive motor 55g and the feed motor 51c by a predetermined difference, and moves the moving body 42 by the linear motor 46. V3 is accelerated by a predetermined difference. Then, the packaging speed N4 of the packaging device 50 increases by the predetermined difference ΔN4, and the supply speed N3 of the second transport device 40 increases by the predetermined difference ΔN3. That is, since the articles 2 are long arranged in the section S on the upstream side of the packaging device 50 before the shift, the operating speed of the packaging device 50 is increased. As a result, the row of the articles 2 in the section S thereafter does not become longer or gradually becomes shorter.

  On the other hand, as a result of the comparison, when the count value B is less than the lower threshold B2, the control unit 70 reduces the rotation speeds of the drive motor 55g and the feed motor 51c by a predetermined difference, and moves the moving body 42 by the linear motor 46. V3 is decelerated by a predetermined difference. Then, the packaging speed N4 of the packaging device 50 decreases by the predetermined difference ΔN4, and the supply speed N3 of the second transport device 40 decreases by the predetermined difference ΔN3. That is, since the articles 2 are arranged short in the section S on the upstream side of the packaging device 50 before the shift, the operating speed of the packaging device 50 is reduced. Thereby, the row of the articles 2 in the section S thereafter does not become shorter any longer or gradually becomes longer.

  On the other hand, as a result of the comparison, when the count value B is equal to or more than the lower threshold value B2 and equal to or less than the threshold value B1, the control unit 70 maintains the rotational speeds of the drive motor 55g and the feed motor 51c, and moves the moving body 42 by the linear motor 46. Maintain V3. Then, the packaging speed N4 of the packaging device is maintained, and the supply speed N3 of the second transport device 40 is maintained. That is, since the arrangement of the articles 2 in the section S on the upstream side of the packaging device 50 has an appropriate length, the operation speed of the packaging device 50 is maintained.

  Therefore, a drop occurs in the row of articles being transported by the first transport apparatus 30, and the number of articles 2 actually supplied per unit time from the first transport apparatus 30 to the second transport apparatus 40 becomes unstable. However, a stable number of articles 2 are arranged upstream of the packaging device 50 and kept in a pooled state. Therefore, no omission occurs in the supply of the articles from the second transport apparatus 40 to the packaging apparatus 50, and the package 5 having no articles is not produced. That is, the yield of the production of the package 5 is very high.

In addition, when the above-mentioned shift control is continued, even if the count value B exceeds the upper threshold value B1, the packaging speed N4 of the packaging device 50 before the speed increase is set to the predetermined maximum value N4 _max [ 1 / sec], the control unit 70 maintains the rotation speed of the driving motor 55g and the feed motor 51c, and also maintains the moving speed V4 of the moving body 42 by the linear motor 46.

14． Speed / cycle control (sixth example)
During the steady operation of the packaging system 1, the supply device 20, the first transport device 30, the second transport device 40, and the packaging device 50 are controlled by the control unit 70 as follows.

14-1. Constant Speed Control Control similar to “12-1. Constant Speed Control” is performed by the control unit 70.

14-2. Shift control As described above, the control unit 70 controls the linear motor 46, the feed motor 51c, and the drive motor 55g such that the supply cycle T3 and the packaging cycle T4 are equal, and the supply speed N3 and the packaging speed N4 are equal. Further, when the control unit 70 controls the linear motor 46, the timing at which the moving body 42 descends from the downstream end (position P3) in the X-axis direction of the forward path 41a is determined by the rotation cycle of the feed motor 51c and the drive motor 55g. Synchronize with a predetermined phase. Therefore, the timing at which the article 2 is supplied from the second transport device 40 (in particular, the transport table 10) to the packaging device 50 (in particular, the former 52) is synchronized with a predetermined phase of the packaging cycle T4. Thereby, the article 2 is not bitten by the press contact portions 55c and 55d of the horizontal sealing machine 55.

  Here, the control unit 70 monitors the outputs of the article sensors 62 and 63 at every supply cycle T3 or an integer multiple thereof, and based on the outputs of the article sensors 62 and 63, controls the rotation speeds of the drive motor 55g and the feed motor 51c. While controlling, the moving speed V3 of the moving body 42 by the linear motor 46 is controlled. Therefore, the supply speed N3 and the packaging speed N4 change in the supply cycle T3 or every integral multiple thereof as follows.

  Specifically, as shown in the truth table of FIG. 15, when the article 2 is detected by both of the article sensors 62 and 63, and the detection signal is input to the control unit 70, the control unit 70 drives the drive motor 55g. In addition to increasing the rotation speed of the feed motor 51c by a predetermined difference, the moving speed V3 of the moving body 42 by the linear motor 46 is increased by the predetermined difference. Then, the packaging speed N4 of the packaging device 50 increases by the predetermined difference ΔN4, and the supply speed N3 of the second transport device 40 increases by the predetermined difference ΔN3. That is, since the articles 2 are long arranged in the section S on the upstream side of the packaging device 50 before the shift, the operating speed of the packaging device 50 is increased.

  On the other hand, since the article 2 is not detected by both the article sensors 62 and 63 and the detection signal is not input to the control unit 70, the control unit 70 reduces the rotational speeds of the drive motor 55g and the feed motor 51c by a predetermined difference, The moving speed V3 of the moving body 42 by the linear motor 46 is reduced by a predetermined difference. Then, the packaging speed N4 of the packaging device 50 decreases by the predetermined difference ΔN4, and the supply speed N3 of the second transport device 40 decreases by the predetermined difference ΔN3. That is, since the articles 2 are arranged short in the section S on the upstream side of the packaging device 50 before the shift, the operating speed of the packaging device 50 is reduced.

  On the other hand, when the article 2 is detected by the article sensor 62 on the upstream side and the article 2 is detected by the article sensor 63 on the downstream side, a detection signal is input from the article sensor 63 to the control unit 70. The controller 70 maintains the rotation speed of the drive motor 55g and the feed motor 51c, and also keeps the moving speed V3 of the moving body 42 by the linear motor 46 because the input is not input to the controller 70. Then, the packaging speed N4 of the packaging device is maintained, and the supply speed N3 of the second transport device 40 is maintained. That is, since the arrangement of the articles 2 in the section S on the upstream side of the packaging device 50 has an appropriate length, the operation speed of the packaging device 50 is maintained.

  Therefore, a drop occurs in the row of articles being transported by the first transport apparatus 30, and the number of articles 2 actually supplied per unit time from the first transport apparatus 30 to the second transport apparatus 40 becomes unstable. However, a stable number of articles 2 are arranged upstream of the packaging device 50 and kept in a pooled state. Therefore, no omission occurs in the supply of the articles from the second transport apparatus 40 to the packaging apparatus 50, and the package 5 having no articles is not produced. That is, the yield of the production of the package 5 is very high.

In addition, even if the article 2 is detected by both the article sensors 62 and 63 while the above-described shift control is continued, the packaging speed N4 of the packaging apparatus 50 before the speed increase is set to the predetermined maximum. When the value is N4 _max [1 / sec], the control unit 70 maintains the rotation speed of the drive motor 55g and the feed motor 51c, and also maintains the moving speed V4 of the moving body 42 by the linear motor 46.

[Second embodiment]
FIG. 16 is a plan view of the packaging system 101. FIG. The packaging system 101 includes a transport table 10, a worktable 180, a supply device 110, a first transport device 30, a second transport device 40, a packaging device 50, article sensors 61 to 63, and a control unit 70.

  The first transport device 30, the second transport device 40, the packaging device 50, and the article sensors 61 to 63 are the same as those in the first embodiment, and thus description thereof will be omitted.

  Similarly to the case of the first embodiment, the upstream portion 11 of the transfer table 10 is higher than the downstream portion 13, and the portion 12 between them is inclined downward toward the downstream portion 13, and is downstream from the intermediate portion 12. The slit 14 is formed so as to extend in the X-axis direction toward the end of the portion 13. Here, below the portion on the X-axis upstream side of the first transport device 30, not the transport table 10 but the supply device 110 is arranged. The supply device 110 is provided from below a portion on the upstream side in the X-axis direction of the first transport device 30 to an upstream side in the Y-axis direction.

  The supply device 110 arranges the articles 2 in a line while transporting the articles 2 in the Y-axis direction, and sequentially supplies the articles 2 to the first transport apparatus 30. The supply device 110 includes belt conveyors 111, 112, 113 arranged in the Y-axis direction, a reduced-line belt conveyor 115 provided on the belt conveyor 111, and a reduced-line belt conveyor 116 provided on the belt conveyor 112. And

  The belt conveyor 111 is disposed adjacent to the worktable 180 on the downstream side in the Y-axis direction, the belt conveyor 112 is disposed adjacent to the belt conveyor 112 on the downstream side in the Y-axis direction, and the belt conveyor 113 is disposed in the Y-axis direction of the belt conveyor 112. It is arranged adjacent to the downstream side in the direction. The transport table 10 is arranged adjacent to the downstream side of the belt conveyor 113 in the X-axis direction, and the first transport device 30 extends from the downstream end of the belt conveyor 113 in the Y-axis direction to an intermediate portion of the transport table 10. It is located above. The conveying surfaces of these belt conveyors 111 to 113 are provided horizontally and have the same height. In addition, the transport surface of the belt conveyor 113 has the same height as the upper surface of the transport table 10.

  The reduced-row belt conveyor 115 is provided on the belt conveyor 111 such that its transport surface is orthogonal to the transport surface of the belt conveyor 111. The transport surface of the reduction belt conveyor 115 is inclined with respect to a vertical plane parallel to the Y-axis direction. The reduced-row belt conveyor 116 is provided on the belt conveyor 112 such that its transport surface is orthogonal to the transport surface of the belt conveyor 112. The transport surface of the reduction belt conveyor 116 is inclined with respect to a vertical plane parallel to the Y-axis direction in a direction opposite to the inclination direction of the transport surface of the reduction belt conveyor 115. The upstream end of the reduced-sequence belt conveyor 116 in the Y-axis direction is shifted downstream of the downstream end of the reduced-sequence belt conveyor 115 in the X-axis direction.

  When the worker slides the articles 2 on the work table 180 onto the belt conveyor 111, the articles 2 are conveyed downstream in the Y-axis direction by the belt conveyor 111 in a multi-row state. When these articles 2 hit the reduction belt conveyor 115, resistance occurs in the flow in the Y-axis direction, so that the articles 2 are conveyed while being aligned in a direction oblique to the Y-axis direction. When the article 2 reaches the end of the reduced-line belt conveyor 115 on the downstream side in the Y-axis direction, the article 2 is transported downstream by the belt conveyor 111 and transferred from the belt conveyor 111 to the belt conveyor 112. The article 2 transferred to the belt conveyor 112 is conveyed downstream in the Y-axis direction by the belt conveyor 112 and hits the reduced-row belt conveyor 116. Also on the reduction row belt conveyor 116, the articles 2 are conveyed while being aligned in a direction oblique to the Y-axis direction. The articles 2 are arranged in a line on the downstream side of the reduced row belt conveyor 116, and the articles 2 are conveyed one by one from the downstream end of the reduced row belt conveyor 116 to the Y axis direction downstream by the belt conveyor 112. Then, the article 2 that has reached the downstream end in the Y-axis direction of the belt conveyor 112 is transported downstream in the Y-axis direction by the belt conveyor 113. The transport speed of the belt conveyor 113 is higher than the transport speeds of the belt conveyors 111 and 112, and the interval increases when the articles 2 are transferred from the belt conveyor 112 to the belt conveyor 113. The article 2 conveyed by the belt conveyor 113 enters between the adjacent pushing fingers 34 of the first conveying device 30.

  As described above, at the downstream end of the supply device 110 in the Y-axis direction, the articles 2 are sequentially and integrally supplied to the first transport device 30 by the supply device 110 in a state of being arranged in a line in the Y-axis direction. However, since the intervals between the articles 2 on the belt conveyor 113 are irregular, a row of the articles 2 conveyed in the X-axis direction by the first conveying device 30 is missing.

  Therefore, similarly to the case of the first embodiment, the first transport device 30, the second transport device 40, and the packaging device 50 are controlled by the control unit 70, and the articles from the second transport device 40 to the packaging device 50 are controlled. There is no dropout in the supply, and no package 5 without articles is produced.

  In the first embodiment, the transport speed V1 of the first transport device 30 and the operation speed of the supply device 20 (the rotational speed n of the rotary drum 21) are directly proportional. The transport speed V1 of the transport device 30 and the operating speed of the supply device 110 (in particular, the transport speed of the belt conveyor 113) are directly proportional.

[Third Embodiment]
FIG. 17 is a plan view of the packaging system 201. FIG. The packaging system 201 includes the transport table 10, the supply device 20, the first transport device 230, the belt conveyors 238, 238, the second transport device 40, the packaging device 50, the article sensors 61 to 63, and the control unit 70.

  In the transport table 10, the heights of the upstream portion 11 and the downstream portion 13 are uniform, the upstream portion 11 and the downstream portion 13 are interrupted, and a pair of belt conveyors 238 and 238 are provided between the upstream portion 11 and the downstream portion 13. Is provided. As will be described in detail later, the belt conveyor 238 relays the article 2 from the first transport device 230 to the second transport device 40, and the portion where the belt conveyor 238 is provided is moved from the first transport device 230 to the second transport device. The first delivery point P4 where the article 2 is delivered to 40.

  The upstream portion 11 of the transfer table 10 is formed in an L shape when viewed from above, and the slit 14 of the upstream portion 11 is also formed in an L shape. Specifically, the upstream portion 11 of the transport table 10 is provided with a linear portion 11a extending in the Y-axis direction, a linear portion 11c extending in the X-axis direction, and provided between the linear portion 11a and the linear portion 11c. Corner 11b. The slit 14 of the upstream portion 11 is formed linearly so as to extend in the Y-axis direction at the linear portion 11a, is curved in an arc shape at the corner portion 11b, and extends in the X-axis direction at the linear portion 11c. It is formed in a straight line.

  The installation direction of the supply device 20 in the third embodiment is different from that in the first embodiment. That is, in the first embodiment, the rotation axis of the rotary drum 21 of the supply device 20 extends in the X-axis direction, whereas in the third embodiment, the rotation axis of the rotation drum 21 of the supply device 20 is Y It extends in the axial direction.

  In the third embodiment, the rotary drum 21 is disposed above the linear portion 11a of the upstream portion 11 and is rotated by the rotary motor 22. The rows 4 of the articles 2 to be supplied to the supply device 20 are arranged in the X-axis direction on the X-axis direction side of the rotating drum 21 and are conveyed toward the rotating drum 21 along the X-axis by a vibration feeder or the like. . The suction nozzle 23 rotates by the rotation of the rotary drum 21 driven by the rotary motor 22, but when the suction nozzle 23 faces the row 4 of the articles 2, the suction nozzle 23 suctions the first article 2 in the column 4 by negative pressure, and The article 2 is released by positive pressure.

  Below the upstream part 11 of the transfer table 10, a first transfer device 230 is provided. The first transfer device 230 is provided instead of the first transfer device 30 of the first embodiment. Here, the first transport device 30 of the first embodiment is a side finger conveyor, whereas the first transport device 230 of the third embodiment is a vertical finger conveyor. That is, while the rotation axes of the pulleys 31 and 32 of the first transfer device 30 of the first embodiment are vertical, the rotation axes of the pulleys (or sprockets) of the first transfer device 230 of the third embodiment are horizontal. It is.

  The endless belt (or endless chain) of the first transfer device 230 of the third embodiment is driven by a driven member (for example, a driven roller, a driven pulley, or a driven sprocket) below the upstream portion 11 of the transfer table 10. Is provided along the slit 14 of the upstream portion 11 from the upstream end to the downstream end. A plurality of pushing fingers 234 are attached to the endless belt (or endless chain) of the first transfer device 230 at predetermined intervals. The pitch of the arrangement of the pushing fingers 234 is equal to the pitch of the arrangement of the suction nozzles 23 arranged in the Y-axis direction, similarly to the pushing fingers 34 of the first transport device 30 of the first embodiment. When the endless belt (or endless chain) of the first transfer device 230 is rotated by the motor of the first transfer device 230 (corresponding to the motor 35 of the first embodiment), the pushing finger 234 passes through the slit 14 of the upstream portion 11. And moves from the upstream end to the downstream end of the upstream portion 11 while protruding above the upstream portion 11. As a result, the article 2 that has dropped from the suction nozzle 23 onto the upstream portion 11 of the transport table 10 is pushed from the upstream side by the pushing finger 234 and sent.

  In the third embodiment, the first transport device 230 is controlled by the control unit 70 in the same manner as the first transport device 30 is controlled by the control unit 70 in the first embodiment.

  The pair of belt conveyors 238 are arranged in parallel between the linear portion 11 c of the upstream portion 11 of the transfer table 10 and the downstream portion 13. The belt conveyors 238 are arranged at intervals in the Y-axis direction, and the gap between the belt conveyors 238 extends from the slit 14 at the upstream portion 11 to the slit 14 at the downstream portion 13. The article 2 conveyed to the downstream end of the upstream portion 11 by the pushing finger 234 is transferred from the upstream portion 11 to the belt conveyor 238. The article 2 reloaded on the belt conveyor 238 is conveyed in the X-axis direction by the belt conveyor 238 while straddling the pair of belt conveyors 238. Further, when the article 2 is replaced on the belt conveyor 238, the pushing finger 234 pushing the article 2 is drawn downward between the pair of belt conveyors 238, and then the pushing finger 234 is moved upstream of the transport table 10. After returning to the upstream end of the upstream part 11 below the part 11, it protrudes above the slit 14 at the upstream end.

  The transport speed of the belt conveyor 238 is controlled by the control unit 70 so as to be equal to the transport speed V1 of the first transport device 30. Therefore, the pitch of the arrangement of the articles 2 on the belt conveyor 238 is equal to the pitch of the arrangement of the articles 2 on the first transport device 230.

  An article sensor 61 is provided above a gap between the belt conveyor 238 and the belt conveyor 238. Accordingly, when the article 2 being conveyed by the belt conveyor 238 is detected by the article sensor 61, the specific moving body 42 is moved from the upper portion of the ascending track 41d to the X-axis direction of the outward path 41a in the same manner as in the first embodiment. The specific finger 43 of the specific moving body 42 protrudes upward from between the belt conveyors 238 at this time. Therefore, the specific article 2 is pushed from behind by the specific finger 43 and sent.

  Since the second transport device 40, the packaging device 50, and the article sensors 61 to 63 are the same as those in the first embodiment, the description thereof will be omitted. Also in the third embodiment, the above-described “9. Speed control / period control (first example)”, “10. Speed control / period control (second example)”, and “11. Third example), "12. Speed control / cycle control (fourth example)", "13. Speed control / cycle control (fifth example)", "14. Speed control / cycle control (sixth example)" Is executed.

  Here, in the case where a row of the articles 2 conveyed by the first conveying device 230 is missing, the worker beside the linear portion 11c of the upstream portion 11 of the conveying table 10 places the articles 2 in the missing section. refill. Even if the replenishment work of the worker is not in time, the gap between the articles 2 sandwiching the missing portion is reduced by the operation of the second transport device 40 as in the first embodiment. Therefore, the occurrence of empty packages 5 can be suppressed without temporarily stopping the packaging device 50. Further, even when the worker cannot perform the replenishment work continuously, the above-mentioned “9. Speed control / cycle control (first example)”, “10. Speed control / cycle control (second example)”, “11. Speed control / cycle control (third example) "," 12. Speed control / cycle control (fourth example) "," 13. Speed control / cycle control (fifth example) "," 14. Speed control / cycle " Since the “control (sixth example)” is executed, no loss occurs in the supply of articles from the second transport device 40 to the packaging device 50, and an empty package 5 is not produced.

  In the above description, the transport route of the article 2 by the first transport device 230 is L-shaped, but the transport route of the article 2 by the first transport device 230 may be linear along the X axis. Good.

(Modification)
The embodiments for carrying out the present invention have been described above. However, the embodiments are intended to facilitate understanding of the present invention, and are not intended to limit the present invention. Further, the embodiments of the present invention can be changed and improved without departing from the spirit of the present invention, and the present invention also includes equivalents thereof. Changes from the above embodiment will be described below. The modifications described below may be combined and applied.

(1) In the above-described embodiment, the packaging device 50 is a regular pillow packaging device (the vertical sealing machine 54 is disposed below the receiving plate 53, the raw material roll 51a is disposed above the former 52, Although both sides are bent downward by the former 52), an inverted pillow packaging device may be used. In the case of the reverse pillow packaging device, the vertical sealing machine 54 is arranged above the receiving plate 53, the raw roll 51 a is arranged below the former 52, and both sides of the band-shaped film 6 are bent upward by the former 52. .

(2) Further, the packaging device 50 may be a three-side seal packaging device. In the case of the three-side seal packaging apparatus, the raw roll 51a is arranged on the side of the former 52, and the belt-shaped film 6 fed from the raw roll 51a is conveyed to the former 52 in a state orthogonal to the horizontal plane, and the film 6 are folded in two by the former 52, and a lateral sealing machine 54 is arranged on the side of the path of the folded film 6, and the lateral sealing machine 54 moves the overlapping edge of the film 6 up and down. And seal it.

(3) The packaging device 50 may be a four-sided seal packaging device. In the case of a four-side seal packaging apparatus, two raw rolls 51a are arranged vertically, and two films 6 fed from these raw rolls 51a are vertically stacked at the downstream end of the transport table 10 in the X-axis direction. The two lateral sealing machines 54 are conveyed to the downstream side in the X-axis direction, and two lateral sealing machines 54 are arranged on both sides of the path of the two stacked films 6. The upper and lower edges on both sides are sandwiched vertically and sealed.

(4) The cutting blades 55e and 55f may be omitted. In this case, a continuous package in which a plurality of packages 5 are connected is produced.

(5) The cutting blades 55e and 55f may be changed to perforated blades. In this case, a continuous package body in which a plurality of packages 5 are connected is produced, and perforation lines (perforations) are formed between the packages 5.

(6) The article sensors 61 to 64 may be other types of sensors (for example, a limit switch, a touch sensor, and an electrostatic sensor) instead of the optical sensors as long as the articles 2 can be detected.

  DESCRIPTION OF SYMBOLS 1, 101 ... Packaging system, 2 ... Article, 5 ... Package 6 ... Film, 10 ... Transport table, 12 ... Intermediate part, 30 ... First transport device, 40 ... Second transport device, 41 ... Guide, 42 ... Moving Body, 43: Pushing finger (pushing member), 46: Linear motor, 50: Packaging device, 52: Former, 61: Article sensor (detection unit), P4: First delivery point, P5: Second delivery point, 70 ... Control unit

Claims (8)

A first transport device that sequentially transports and supplies the first delivery point in a state where a plurality of articles are arranged,
A second transport device that sequentially transports and supplies the articles transported by the first transport device along the transport path from the first delivery point to a second delivery point,
The article conveyed by the second conveyance device is wrapped in a film at the second delivery point and conveyed together with the film, and by sealing a portion of the film between the articles, the articles are sequentially wrapped. Packaging equipment;
A detection unit that detects an article passing through the first delivery point,
The first transport device, comprising a control unit that controls the second transport device and the packaging device,
The second transport device,
A guide formed in a closed path shape, a part of which is provided along the transport path,
A plurality of moving bodies guided along the guide by the guide,
A pushing member that is provided on the moving body and that pushes out an article by protruding from the moving body that moves along a portion of the guide along the transport path to the transport path;
A linear motor that drives the moving body to individually circulate the moving body along the guide in a direction from the first delivery point to the second delivery point along the transport path,
The control unit includes:
Each time the detecting unit detects an article, the linear motor starts moving the head of the moving body arranged behind the first delivery point of the moving body toward the second delivery point, and moves. An operation process of controlling the linear motor so as to decelerate when the started moving body catches up with the preceding moving body,
For each predetermined period, a counting process for counting the number of times the detection unit detects an article during the predetermined period,
A shifting process for controlling a supply speed of the first transport device based on a count value of the counting process. A first transport device that sequentially transports and supplies the first delivery point in a state where a plurality of articles are arranged,
A second transport device that sequentially transports and supplies the articles transported by the first transport device along the transport path from the first delivery point to a second delivery point,
The article conveyed by the second conveyance device is wrapped in a film at the second delivery point and conveyed together with the film, and by sealing a portion of the film between the articles, the articles are sequentially wrapped. Packaging equipment;
A detection unit that detects an article passing through the first delivery point,
The first transport device, comprising a control unit that controls the second transport device and the packaging device,
The second transport device,
A guide formed in a closed path shape, a part of which is provided along the transport path,
A plurality of moving bodies guided along the guide by the guide,
A pushing member that is provided on the moving body and that pushes out an article by protruding from the moving body that moves along a portion of the guide along the transport path to the transport path;
A linear motor that drives the moving body to individually circulate the moving body along the guide in a direction from the first delivery point to the second delivery point along the transport path,
The control unit includes:
Each time the detecting unit detects an article, the linear motor starts moving the head of the moving body arranged behind the first delivery point of the moving body toward the second delivery point, and moves. An operation process of controlling the linear motor so as to decelerate when the started moving body catches up with the preceding moving body,
For each predetermined cycle, a counting process for counting the number of moving bodies moving toward the second delivery point in a state where the speed is reduced by the linear motor,
A shifting process for controlling a supply speed of the first transport device based on a count value of the counting process. The control unit, when the count value of the counting process exceeds the upper threshold, reduces the supply speed of the first transport device in the shift process, and the count value of the counting process is lower than the upper threshold. If it is less than the threshold value, the supply speed of the first transport device is increased in the shift process, and if the count value of the counting process is equal to or less than the upper threshold value and equal to or greater than the lower threshold value, the first transport device is shifted in the shift process. 3. The packaging system according to claim 1, wherein the supply speed of the device is maintained.   The said control part performs the process which controls the packaging speed of the said packaging apparatus to fixed, The packaging system of Claim 3 characterized by the above-mentioned. A first transport device that sequentially transports and supplies the first delivery point in a state where a plurality of articles are arranged,
A second transport device that sequentially transports and supplies the articles transported by the first transport device along the transport path from the first delivery point to a second delivery point,
The article conveyed by the second conveyance device is wrapped in a film at the second delivery point and conveyed together with the film, and by sealing a portion of the film between the articles, the articles are sequentially wrapped. Packaging equipment;
A detection unit that detects an article passing through the first delivery point,
The first transport device, comprising a control unit that controls the second transport device and the packaging device,
The second transport device,
A guide formed in a closed path shape, a part of which is provided along the transport path,
A plurality of moving bodies guided along the guide by the guide,
A pushing member that is provided on the moving body and that pushes out an article by protruding from the moving body that moves along a portion of the guide along the transport path to the transport path;
A linear motor that drives the moving body to individually circulate the moving body along the guide in a direction from the first delivery point to the second delivery point along the transport path,
The control unit includes:
Each time the detecting unit detects an article, the linear motor starts moving the head of the moving body arranged behind the first delivery point of the moving body toward the second delivery point, and moves. An operation process of controlling the linear motor so as to decelerate when the started moving body catches up with the preceding moving body,
For each predetermined period, a counting process for counting the number of times the detection unit detects an article during the predetermined period,
A shifting process for controlling a packaging speed of the packaging device based on a count value of the counting process. A first transport device that sequentially transports and supplies the first delivery point in a state where a plurality of articles are arranged,
A second transport device that sequentially transports and supplies the articles transported by the first transport device along the transport path from the first delivery point to a second delivery point,
The article conveyed by the second conveyance device is wrapped in a film at the second delivery point and conveyed together with the film, and by sealing a portion of the film between the articles, the articles are sequentially wrapped. Packaging equipment;
A detection unit that detects an article passing through the first delivery point,
The first transport device, comprising a control unit that controls the second transport device and the packaging device,
The second transport device,
A guide formed in a closed path shape, a part of which is provided along the transport path,
A plurality of moving bodies guided along the guide by the guide,
A pushing member that is provided on the moving body and that pushes out an article by protruding from the moving body that moves along a portion of the guide along the transport path to the transport path;
A linear motor that drives the moving body to individually circulate the moving body along the guide in a direction from the first delivery point to the second delivery point along the transport path,
The control unit includes:
Each time the detecting unit detects an article, the linear motor starts moving the head of the moving body arranged behind the first delivery point of the moving body toward the second delivery point, and moves. An operation process of controlling the linear motor so as to decelerate when the started moving body catches up with the preceding moving body,
For each predetermined cycle, a counting process for counting the number of moving bodies moving toward the second delivery point in a state where the speed is reduced by the linear motor,
A shifting process for controlling a packaging speed of the packaging device based on a count value of the counting process. When the count value of the counting process exceeds the upper threshold, the control unit increases the packaging speed of the packaging device in the shift process, and the count value of the counting process is lower than the lower threshold. If it is less than, the packaging speed of the packaging device is reduced in the speed change process, and if the count value of the counting process is equal to or less than the upper threshold and equal to or greater than the lower threshold, the packaging speed of the packaging device is maintained in the speed change process. 7. The packaging system according to claim 5, wherein   The packaging system according to claim 7, wherein the control unit executes a process of controlling a supply speed of the first transport device to be constant.

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