JP5912519B2 - Direction change device - Google Patents

Description

  The present invention relates to a direction changing device that changes the direction of an article.

  Corone bread such as chocolate corone is a confectionery bread in which bread dough is wound around a conical surface in a spiral shape and baked, and then cream such as chocolate is packed therein. In such a packaging line in which coronepan is pillow-wrapped, coronepan is randomly supplied to the pillow packaging machine one after another by a transport device such as a belt conveyor. Then, the coronepan is individually packaged by a packaging material such as a film in a pillow packaging machine.

  The packaging material is printed with coronepan product information or the like in a certain direction, or is given a certain direction by a label. When making product specifications constant, it is necessary to carry out pillow packaging with coronepan in a certain direction. That is, it is necessary to supply coronepan to a pillow packaging machine in a certain direction.

  Therefore, it is conceivable to apply the direction changing device described in Patent Document 1 as a conveying device that supplies coronepan to the pillow packaging machine and supply the coronepan to the pillow packaging machine in a certain direction. When this direction changing device is applied, the coronepan is converted into a certain direction until the coronepan is received from the upstream conveyor and sent to the downstream conveyor.

  Specifically, the direction changing device includes a pair of transport rollers arranged side by side in the width direction, a pair of motors that rotate the pair of transport rollers independently of each other, and a coronepan that is being transported by a transport conveyor on the upstream side. And a CPU for controlling the pair of motors based on the imaging result of the camera. According to this direction conversion device, the coronepan can be converted into a certain direction by setting the relative rotational speed of the pair of transport rollers to a speed according to the imaging result.

Japanese Patent No. 2896776 (see FIGS. 1 and 3)

  However, in the direction changing device described in Patent Document 1, it is necessary to control the rotation speed of the transport roller according to the imaging result. That is, the control of the conveyance roller is complicated. Further, it is conceivable that the coronepan slides on the transport roller due to the difference in individual physical properties of the coronepan, and the rotation amount (direction change amount) is insufficient. That is, the direction changing device may not be able to reliably change the direction. The tendency that the amount of direction change is insufficient is remarkable when the coronepan is conveyed at high speed.

  Such a problem may exist not only in the case of coronepan but also in the case of various articles such as other foods and daily necessities. Moreover, not only when conveying toward a packaging machine, it may exist in common when conveying to another conveyance destination.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a direction changing device that reliably converts an article in a certain direction without complicating control.

(1) The present invention is a direction changing device that reverses the direction of an arbitrary article while converting sequentially supplied articles, and converts the article into a predetermined arrangement, and the first carrying that travels with the article placed thereon. A conveying means having a surface; a first guiding means arranged in a direction crossing the traveling direction of the first conveying surface; and guiding the article from the side; and the first conveying located downstream of the first guiding means. An abutting means for reversing the direction of the article that is in contact above the surface, the conveying means conveys the article in a forward or backward orientation, and the first guiding means is movable. The article that is not reversed by expanding and contracting is guided to a position that does not contact the abutting means on the first transport surface, and the article that is inverted is guided to a position that is in contact with the abutting means. It is a direction change device.

  (2) The present invention is also characterized in that the first guide means includes a first guide belt that rotates laterally, and a belt speed of the first guide belt is different from a speed of the first conveying surface. The direction changing device according to (1) above.

( 3 ) In the present invention, article alignment means is provided on the upstream side of the conveyance means, and the article alignment means has a second conveyance surface on which the article is placed and travels, and the second conveyance surface. And a second guide means that guides the article from the side, the second guide means having a second guide belt that rotates laterally, and the second guide belt and the second guide belt The direction changing device according to (1) or (2) above, wherein a speed difference is provided with respect to the second transport surface.

( 4 ) The present invention also provides the direction changing device according to ( 3 ), wherein the first transport surface is faster than the second transport surface.

  According to the above invention, the direction of the article can be changed after the interval between the articles is widened. Thereby, it can prevent that another article | item contacts and interferes with the article | item which is changing the direction. As a result, the article can be reliably converted in a certain direction without complicating the control.

( 5 ) The direction according to any one of (1) to ( 4 ), wherein the present invention is also a bread whose cross-sectional area gradually decreases from one to the other in the front-rear direction. It is a conversion device.

  According to the direction changing device described in the above (1) to (6) of the present invention, the article can be reliably changed in a certain direction without complicating the control.

It is a top view of the direction change apparatus of this invention, (A) shows the motion of each structure with the arrow, (B) shows the motion of coronepan. It is a side view of a direction change apparatus. It is a top view of an alignment unit, (A) shows the state of dividing into two rows which makes coronepan into two rows, and (B) shows the state of making into one row which makes coronepan into one row. It is a side view and sectional drawing of a direction detection means in a direction change unit, (A)-(C) shows the case where the direction of coronepan is detected as a basic direction, and (D)-(F) shows the direction of coronepan Is detected in the reverse direction. (A)-(C) are top views of the guide means and the abutting means in the direction changing unit, and show the operation when the direction of the coroneppan is the basic direction. (A)-(C) are the top views of the guide means and the abutting means in a direction change unit, and show operation | movement in case the direction of a coronepan is a reverse direction.

  Hereinafter, a direction changing device according to the present invention will be described in detail with reference to the drawings.

  First, the structure of the direction change apparatus 10 is demonstrated using FIGS. 1A and 1B are top views of the direction changing device 10, in which FIG. 1A shows the movement of each component by arrows, and FIG. 1B shows the movement of the coronepan XA1. FIG. 2 is a side view of the direction changing device 10. 3A and 3B are top views of the alignment unit 11. FIG. 3A shows a state in which the coronepan XA1 is divided into two rows. FIG. 3B shows a state where the coronepan XA1 is made into one row.

  FIG. 4 is a side view and a sectional view of the direction detecting means 32 in the direction changing unit 12. 4A to 4C show a case where the direction of coronepan XA1 is detected as the basic direction. 4D to 4F show a case where the direction of the coronepan XA1 is detected as the reverse direction. FIGS. 5A to 5C are top views of the guide means 33 and the abutting means 34 in the direction changing unit 12, and show the operation when the direction of the coronepan XA1 is the basic direction. 6 (A) to 6 (C) are top views of the guide means 33 and the abutting means in the direction changing unit 12, and show the operation when the direction of the coronepan XA1 is the reverse direction. Note that in each drawing, a part of the configuration is omitted as appropriate to simplify the drawing.

  1 and 2 is used in a line for packaging coronepan XA1. The line for packaging the coronepan XA1 includes a transport process for transporting the plurality of coronepans XA1 toward a packaging machine (not shown), and a packaging process for individually packaging the coronepan XA1 in the packaging machine.

  The direction changing device 10 is used in the transport process. As will be described in detail later, the direction changing device 10 aligns the coronepan XA1 in one or two rows while conveying the coronepan XA1, and further converts the coronepan XA1 aligned in the one or two rows into a certain direction. . That is, the direction changing device 10 reverses the direction of an arbitrary coronepan XA1 while converting the coronepan XA1 that is sequentially supplied, and converts it into a predetermined arrangement.

Corone bread XA1 is a confectionery bread in which bread dough is wound around a conical surface in a spiral shape and baked, and then a cream such as chocolate is packed therein. Such coronepan XA1 has a substantially conical shape. That is, the coronepan XA1 has a shape in which the cross-sectional area gradually decreases from one to the other in the front-rear direction. Specifically, the coronepan XA1 has a first height H ₁ on the front side (see FIGS. 4A and 4C) and a second height H ₂ on the rear side different from the first height H _1. (See FIGS. 4A and 4B). In the present specification, the coronepan XA1 will be described with the pointed and thin side as the front side and the thicker side with the mouth (not shown) for filling the cream as the back side. That is, the coronepan XA1 will be described assuming that the front side is low and the rear side is high.

  And in this specification, although the case where coronepan XA1 is packaged is demonstrated to an example, this invention is applicable when packaging various articles | goods, such as other foodstuffs and daily necessities. However, the article is required to have a shape that gradually decreases from one to the other in the front-rear direction. The article preferably has a length in the front-rear direction that is longer than a length in the width direction. Moreover, although this specification demonstrates as an example the case where it conveys toward a packaging machine, this invention is not limited to a packaging machine.

  The direction changing device 10 includes an alignment unit 11, a direction changing unit 12, a centering unit 13, a delivery unit 14, and a control unit (not shown).

  Each unit of the direction changing device 10 is controlled in an integrated manner by the control unit. That is, each unit of the direction changing device 10 operates under the control of the control unit, and the operation status is managed by the control unit. The control unit includes a CPU, a RAM, a ROM, and the like, and executes various controls. The CPU is a so-called central processing unit, and various programs are executed to realize various functions. The RAM is used as a work area for the CPU. The ROM stores a basic OS and programs executed by the CPU.

  The alignment unit 11 serving as the article alignment means takes over the coronepan XA1 having a disordered row from the belt conveyor 101 in the apparatus 100 in the previous process upstream of itself. Then, the alignment unit 11 aligns the inherited coronepan XA1 into one or two columns which are a preset number of columns. The alignment unit 11 sends the coronepan XA1 aligned in one or two rows to the direction changing unit 12 in either the basic direction in which the front side faces downstream or the reverse direction in which the front side faces upstream.

  As shown in FIGS. 1, 2, 3 </ b> A and 3 </ b> B, the alignment unit 11 includes a belt conveyor 17 and a passage forming means 18.

  The belt conveyor 17 is a pair of sprockets 20 and 21, an annular chain (not shown) that travels by being hooked on the pair of sprockets 20 and 21, and is continuously arranged from upstream to downstream to be integrated with the chain. And a pair of side guides 23, 24 arranged along the traveling direction of the traveling plate 22.

  One of the sprockets 20 is connected to a servo motor and rotates normally by driving the servo motor. The other sprocket 21 normally rotates in conjunction with one sprocket 20 by the steady running of the chain. The chain and the plurality of traveling plates 22 travel in a steady manner so as to circulate by the steady rotation of one sprocket 20. The travel plate 22 travels at a higher speed than the belt conveyor 101 in the apparatus 100 of the previous process. The pair of side guides 23 and 24 are integrated with the passage forming means 18 to form a passage on the travel plate 22 serving as the second transport surface.

  The passage forming means 18 forms a passage gradually narrowing toward the downstream on the traveling plate 22. The number of passages can be switched between one and two according to the use mode. In each passage, the outlet on the downstream side is set wider than the width of the coronepan XA1 and narrower than the length of the coronepan XA1 in the front-rear direction. Thereby, the direction of the coronepan XA1 that has passed through the outlet is either the basic direction in which the front side faces downstream or the reverse direction in which the front side faces upstream.

  Specifically, the passage forming means 18 includes a support gate 27 and a pair of side guides 28 and 29. The support gate 27 is provided so as to be bridged above the belt conveyor 17. The support gate 27 supports the pair of side guides 28 and 29 so as to be slidable in the width direction and rotatable about the vertical axis.

  One side guide 28 is arranged in a direction intersecting with the traveling direction of the traveling plate 22, and forms a passage on the traveling plate 22 between the side guides 23. The side guide 28 includes a pair of rollers (reference numerals omitted), an annular belt (reference numerals omitted) that runs on the pair of rollers, and a servo motor (reference numerals omitted) that serves as a power source. .

  One roller is connected to a servo motor and rotates normally by driving the servo motor. The other roller rotates normally in conjunction with one of the rollers as the belt runs steadily. The belt travels steadily so as to circulate by the steady rotation of one of the rollers. This belt is a second guide belt that rotates laterally and travels in a steady manner so that a portion that faces the side guide 23 and forms a passage flows toward a packaging machine (not shown). The running speed of the belt is the same as the running speed of the belt conveyor 17. However, the traveling speed of the belt may be different from the traveling speed of the belt conveyor 17. Specifically, the belt traveling speed is preferably such that the speed of the component in the flow direction of the belt conveyor 17 (the horizontal direction in the drawing) is the same as the traveling speed of the belt conveyor 17.

  The other side guide 29 is arranged in a direction intersecting the traveling direction of the traveling plate 22, and forms a passage on the traveling plate 22 between the side guide 29 and the side guide 24. Similar to the side guide 28, the side guide 29 includes a pair of rollers (reference numeral omitted), a belt (reference numeral omitted), and a servo motor (reference numeral omitted) serving as a power source. The operation of the side guide 29 is the same as the operation of the side guide 28, and the description thereof is omitted.

  Returning to FIG. 1 and FIG. The direction changing unit 12 serving as the conveying means takes over the above-described coronepan XA1 in the basic direction or the reverse direction from the belt conveyor 17 of the alignment unit 11 upstream thereof. Then, the direction changing unit 12 conveys the coronepan XA1 in a forward or backward posture. The direction changing unit 12 converts all the inherited coronepan XA1 into a certain direction. That is, the direction changing unit 12 keeps the coronepan XA1 in the basic direction in the basic direction and converts the coronepan XA1 in the reverse direction into the basic direction. In addition, the direction changing unit 12 sends out the coronepan XA1 in a fixed direction to the centering unit 13.

  Specifically, the direction conversion unit 12 includes a belt conveyor 31, direction detection means 32, guide means 33, abutment means 34, and a center guide 35.

  Similar to the belt conveyor 17, the belt conveyor 31 includes a pair of sprockets 36, 37, a chain (not shown), a travel plate 38, and a servo motor (not shown). The travel plate 38 that is the first transport surface travels at a higher speed than the travel plate 22 of the alignment unit 11. The other operations of the belt conveyor 31 are the same as the operations of the belt conveyor 17, and the description thereof is omitted.

  The direction detection means 32 includes two pairs of sensor boxes 39, 40, 41, 42 on the upstream side of the belt conveyor 31. The pair of sensor boxes 39, 40 are arranged on the right side in the width direction facing the traveling direction of the belt conveyor 31, and detect the direction of the coronepan XA1 flowing through the right column. The pair of sensor boxes 41 and 42 are arranged on the left side in the width direction facing the running direction of the belt conveyor 31 and detect the direction of the coronepan XA1 flowing through the left column.

As shown in FIG. 4, the sensor box 39 includes a housing 43, a low position sensor 44, and a high position sensor 45. Lower position sensor 44 on the belt conveyor 31, to detect the presence or absence of Koronepan XA1 at a height H ₂ and the front height height h ₁ less than either of an H ₁ of the rear side of the Koronepan XA1. High position sensor 45 on the belt conveyor 31 is lower than the side of the height _{H 2} after Koronepan XA1, and the presence or absence of Koronepan XA1 at the height _{h 2} is higher than the front height _{H 1} of Koronepan XA1 To detect. The low position sensor 44 and the high position sensor 45 output detection result signals to the control unit.

  The sensor box 40 is arranged on the downstream side of the sensor box 39 with a space between the sensor box 39 and the sensor box 39. Similar to the sensor box 39, the sensor box 40 includes a housing 46, a low position sensor 47, and a high position sensor 48. The operation of the sensor box 40 is the same as the operation of the sensor box 39, and the description thereof is omitted.

  Each sensor 44, 45, 47, 48 is a well-known reflection type photosensor, and includes a light projecting unit and a light receiving unit (both not shown). Each of the sensors 44, 45, 47, and 48 projects light from the light projecting unit toward the coronepan XA1 and, when light is reflected from the coronepan XA1, causes the reflected light to enter the light receiving unit. Each sensor 44, 45, 47, 48 detects the presence / absence of coronepan XA1 based on the presence / absence of light incident on the light receiving unit. Each sensor 44, 45, 47, and 48 only needs to be able to detect the presence or absence of coronepan XA1, and is not limited to a reflective photosensor.

  As shown in FIGS. 4A to 4C, when the coronepan XA1 is detected by the low position sensors 44 and 47 and the high position sensor 45 and the coronepan XA1 is not detected by the high position sensor 48, The control unit determines that the coronepan XA1 is in the basic direction.

  On the other hand, as shown in FIGS. 4D to 4F, the coronepan XA1 is detected by the low position sensors 44 and 47 and the high position sensor 48, and the coronepan XA1 is not detected by the high position sensor 45. In addition, the control unit determines that the coronepan XA1 is in the reverse direction.

  Returning to FIG. Similar to the sensor box 39, the sensor box 41 includes a casing (reference numeral omitted), a low position sensor (not shown), and a high position sensor (not shown). The operation of the sensor box 41 is the same as that of the sensor box 39, and the description thereof is omitted.

  The sensor box 42 is disposed on the downstream side of the sensor box 41 with a gap between the sensor box 42 and the sensor box 41. Similar to the sensor box 39, the sensor box 42 includes a housing (reference numeral omitted), a low position sensor (not shown), and a high position sensor (not shown). The operation of the sensor box 42 is the same as that of the sensor box 39, and the description thereof is omitted. The detection of the coronepan XA1 by the pair of sensor boxes 41 and 42 is the same as that of the pair of sensor boxes 39 and 40, and the description thereof is omitted.

  As shown in FIGS. 1, 2, 5, and 6, the guide means 33 that is the first guide means includes a pair of shuttle-type side guides 51 and 52. Each of the pair of shuttle type side guides 51 and 52 is provided to be rotatable around a vertical axis. When the direction changing unit 12 is made to function, the shuttle type side guide 51 is arranged toward the guide roller 53 and the shuttle type side guide 52 is arranged toward the guide roller 54. That is, the pair of shuttle type side guides 51 and 52 are arranged in a direction intersecting with the travel plate 38.

  One shuttle-type side guide 51 includes a plurality of rollers (reference numerals omitted), an annular belt (reference numerals omitted) that is hooked on the plurality of rollers, and a servo motor (reference numerals omitted) that serves as a power source. I have. The shuttle type side guide 51 is movable as will be described later.

  One roller is connected to a servo motor and rotates normally by driving the servo motor. The remaining rollers rotate normally in conjunction with the rollers connected to the servo motor as the belt runs steadily. The belt travels steadily so as to circulate by steady rotation of a roller connected to the servo motor. This belt is a first guide belt that rotates laterally, and travels so that a portion facing the center guide 35 flows toward a packaging machine (not shown). Further, the portion of the belt facing the center guide 35 expands and contracts according to the direction of the coronepan XA1. That is, the belt extends so as to approach the guide roller 53 or contracts so as to move away from the guide roller 53. The timing at which the belt expands and contracts will be described later. The traveling speed of the belt is the same as the traveling speed of the belt conveyor 31. However, the traveling speed of the belt may be different from the traveling speed of the belt conveyor 31. Specifically, the belt traveling speed is preferably such that the speed of the component in the flow direction of the belt conveyor 31 (left and right direction in the drawing) is the same as the traveling speed of the belt conveyor 31.

  The other shuttle-type side guide 52 includes a plurality of rollers (reference numerals omitted), a belt (reference numerals omitted), and a servo motor (reference numerals omitted), like the shuttle-type side guides 51. The operation of the shuttle type side guide 52 is the same as the operation of the shuttle type side guide 51, and the description thereof is omitted.

  The abutting means 34 includes a pair of guide rollers 53 and 54. The guide roller 53 is provided at a position where the coronepan XA1 guided by the shuttle type side guide 51 abuts so as to be rotatable about the vertical axis. The guide roller 54 is rotatably provided around the vertical axis at a position where the coronepan XA1 guided by the shuttle type side guide 52 abuts. These guide rollers 53, 54 rotate the abutted coronepan XA1 around its axis to change the direction. That is, the direction of the coronepan XA1 in contact with the guide rollers 53 and 54 is reversed.

  Here, with reference to FIG. 5A to FIG. 5C, an operation of conveying the coronepan XA1 in the basic direction while keeping the basic direction will be described. That is, the coronepan XA1 in the basic direction is not reversed by the guide rollers 53 and 54. The case where the coronepan XA1 flows through the right side (lower side in the drawing) row in the width direction facing the traveling direction of the belt conveyor 31 will be described as an example.

  When the direction detection means 32 determines that the direction of the coronepan XA1 is the basic direction, the shuttle-type side guide 51 is in a state in which the belt is contracted and between the guide roller 53 and the front and rear direction of the coronepan XA1. Leave a gap wider than the length. That is, the shuttle type side guide 51 guides the coronepan XA1 to a position where it does not contact the abutting means 34 on the traveling plate 38. The coronepan XA1 is conveyed while maintaining the basic direction so as to pass between the shuttle-type side guide 51 and the guide roller 53.

  Next, using FIG. 6A to FIG. 6C, an operation of converting the coronepan XA1 in the reverse direction to the basic direction and transporting it will be described. That is, the coronepan XA1 in the reverse direction is reversed in the basic direction by the guide rollers 53 and 54. The case where the coronepan XA1 flows through the right side (lower side in the drawing) row in the width direction facing the traveling direction of the belt conveyor 31 will be described as an example.

  When the direction detection means 32 determines that the direction of the coronepan XA1 is the reverse direction, the shuttle-type side guide 51 makes the belt stretched and closes the space between the guide roller 53 (FIG. 6 ( A) → see FIG. 6B). That is, the shuttle-type side guide 51 guides the coronepan XA1 to a position on the traveling plate 38 that contacts the abutting means 34. The coronepan XA1 is guided by the shuttle-type side guide 51 and abuts against the guide roller 53 (see FIG. 6B).

  Thereafter, the shuttle-type side guide 51 is in a state in which the belt is contracted, and is spaced from the guide roller 53 by a distance wider than the length in the front-rear direction of the coronepan XA1. The coronepan XA1 rotates around the guide roller 53 and is conveyed so as to pass between the shuttle type side guide 51 and the guide roller 53 while changing the direction from the reverse direction to the basic direction (FIG. 6 ( C)).

  Returning to FIG. 1 and FIG. The centering unit 13 takes over the coronepan XA1 from the belt conveyor 31 of the direction changing unit 12 upstream of itself. Then, the centering unit 13 brings the inherited coronepan XA1 toward the center in the width direction. Further, the centering unit 13 sends out the coronepan XA1 that has been justified to the delivery unit 14.

  Specifically, the centering unit 13 includes a belt conveyor 57 and centering means 58.

  Similar to the belt conveyor 17, the belt conveyor 57 includes a pair of sprockets 59, 60, a chain (not shown), a travel plate 61, and a servo motor (not shown). The travel plate 61 travels at the same speed as the travel plate 38 of the direction changing unit 12. The operation of the belt conveyor 57 is the same as that of the belt conveyor 17, and the description thereof is omitted.

  The centering means 58 forms a passage on the traveling plate 61 that gradually narrows toward the downstream.

  Specifically, the centering means 58 includes a support gate 62 and a pair of side guides 63 and 64 as in the passage forming means 18. The pair of side guides 63 and 64 form a passage on the traveling plate 61 between them. The operation of the centering means 58 is the same as the operation of the passage forming means 18, and the description thereof is omitted.

  The delivery unit 14 takes over the coronepan XA1 from the belt conveyor 57 of the centering unit 13 upstream of itself. And the delivery unit 14 sends out the taken-up coronepan XA1 to a packaging machine (illustration omitted).

  Specifically, the delivery unit 14 includes a belt conveyor 67.

  Similar to the belt conveyor 17, the belt conveyor 67 includes a pair of sprockets 68 and 69, a chain (not shown), a traveling plate 70, a servo motor (not shown), and a pair of side guides 71 and 72. ing. The travel plate 70 travels at the same speed as the travel plate 61 of the centering unit 13. The operation of the belt conveyor 67 is the same as the operation of the belt conveyor 17, and the description thereof is omitted.

  Next, the operation | movement procedure of the direction change apparatus 10 is demonstrated based on FIG. 1 (A) and FIG. 1 (B). However, the case where the coronepan XA1 is arranged in two rows will be described as an example.

  The alignment unit 11 takes over the coronepan XA1 having a disordered row from the belt conveyor 101 in the apparatus 100 in the previous process and arranges it in two rows. Then, the alignment unit 11 sends the coronepan XA1 to the direction changing unit 12 in either the basic direction or the reverse direction.

  The direction changing unit 12 takes over the coronepan XA1 in the basic direction or the reverse direction from the belt conveyor 17 of the alignment unit 11 upstream of itself. Then, the direction changing unit 12 converts all the coronepans XA1 into a certain direction (basic direction) and sends them to the centering unit 13.

  The centering unit 13 takes over the coronepan XA1 in a certain direction (basic direction) from the belt conveyor 31 of the direction changing unit 12 upstream of itself. Then, the centering unit 13 brings the coronepan XA1 to the center in the width direction and sends it to the delivery unit 14.

  The delivery unit 14 takes over the coronepan XA1 brought to the center in the width direction from the belt conveyor 57 of the centering unit 13 upstream thereof, and sends it out to the packaging machine (not shown) as it is.

  Thus, according to the direction changing device 10, by passing the coronepan XA1 through the exit of the passage formed by the passage forming means 18, the coronepan XA1 can be changed from the basic direction to the reverse direction. . When the coronepan XA1 that has passed through the outlet is in the basic direction, the coronepan XA1 can remain in the basic direction by contracting the shuttle-type side guides 51 and 52 of the guide means 33 (FIG. 5). (See (A) to FIG. 5 (C)). When the coronepan XA1 that has passed through the outlet is in the reverse direction, the shuttle-type side guides 51 and 52 of the guide means 33 are extended so that the coronepan XA1 abuts against the abutting means 34 and rotates. Direction (see FIGS. 6A to 6C). In this way, the coronepan XA1 can be reliably converted to the basic direction only by controlling the shuttle-type side guides 51 and 52 of the guide means 33 by two choices of contraction or expansion.

  According to the direction detection means 32, the direction of the coronepan XA1 can be detected with a simple configuration and without complicated control. As a result, according to the direction changing device 10, the coronepan XA1 can be reliably changed in a certain direction without complicating the control.

  Further, since the travel plate 38 of the direction conversion unit 12 travels at a higher speed than the travel plate 22 of the alignment unit 11, the coronepan XA1 can be direction-changed after widening the interval between the coronepan XA1. Thereby, it can prevent that other coronepan XA1 contacts and interferes with coronepan XA1 which is changing direction. As a result, the coronepan XA1 can be reliably converted in a certain direction without complicating the control.

  Furthermore, since the travel plate 22 of the alignment unit 1 travels at a higher speed than the belt conveyor 101 of the apparatus 100 in the previous process, the coronepan XA1 can be fed into the passage after widening the gap between the coronepans XA1. As a result, it is possible to prevent the coronepans XA1 from clogging the passage due to contact with each other or the like. As a result, the coronepan XA1 can be reliably converted in a certain direction without complicating the control.

  Then, the passage is formed so that the passage gradually narrows toward the downstream by the passage formation means 18, so that the coronepan XA1 is brought close to either the basic direction or the reverse direction in the middle of the passage, or the coronepan XA1 is basically used. It can be either in parcel or inversion direction. Thereby, when passing the exit of a channel | path, coronepan XA1 can be made into either a basic direction and a reverse direction smoothly and reliably.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit and technical idea thereof.

  That is, in the above embodiment, the position, size, shape, material, orientation, quantity, and the like of each component can be changed as appropriate.

  Or in the said embodiment, although the direction detection means 32 has detected the direction of coronepan XA1 by one pair of sensor boxes 39,40 or 41,42, this invention is not limited to this, One sensor You may make it detect the direction of coronepan XA1 with a box.

  The sensor box in this case includes a housing, a low position sensor, and a high position sensor, like the sensor boxes 39 to 42. In this case, the low position sensor and the high position sensor detect the presence or absence of the coronepan XA1 at intervals of a predetermined time (a time shorter than the time when one coronepan XA1 passes in front of the sensor box). Thereby, the direction of the coronepan XA1 can be determined.

  Specifically, the coronepan XA1 is detected by the low position sensor, the coronepan XA1 is not detected by the high position sensor, and after a predetermined time interval, the coronepan XA1 is detected by the low position sensor and the high position sensor. In this case, the control unit determines that the coronepan XA1 is in the basic direction.

  In addition, after the coronepan XA1 is detected by the low position sensor and the high position sensor and after a predetermined time interval, the coronepan XA1 is detected by the low position sensor and the coronepan XA1 is not detected by the high position sensor. The control unit determines that the coronepan XA1 is in the reverse direction.

  Or in the said embodiment, although the direction detection means 32 has arrange | positioned several sensors and has detected the direction of coronepan XA1, this invention is not limited to this, The image image | photographed with the electronic camera is analyzed. It may be detected.

  Or in the said embodiment, it may replace with the guidance means 33 and may employ | adopt the guidance apparatus described, for example in the patent 4269151 gazette.

  Or in the said embodiment, it may replace with the belt conveyors 17, 31, 57, 67, and may employ | adopt a plate conveyor and a roller conveyor.

  Or in the said embodiment, it may replace with the guide means 33 and the 1st guide means may employ | adopt the rocking side belt described in Unexamined-Japanese-Patent No. 2011-16660, for example.

  Or in the said embodiment, the guide means 33 which is a 1st guide means is good also as a structure which provides plate-shaped members, such as resin with small frictional resistance, on a guide surface.

DESCRIPTION OF SYMBOLS 10 Direction change apparatus 11 Alignment unit (article alignment means)
12 Direction conversion unit (conveying means)
22 Traveling plate (second transport surface)
28, 29 Side guide (second guide means)
33 Guide means (first guide means)
34 Abutting means 38 Traveling plate (first conveying surface)
XA1 Coronepan (goods, bread)

Claims (5)

A direction changing device that reverses the direction of any of the articles while converting the articles that are sequentially supplied and converts the articles into a predetermined arrangement,
Transport means having a first transport surface on which the article is placed and travels;
First guide means arranged in a direction intersecting with the traveling direction of the first transport surface to guide the article from the side;
Abutting means that is located downstream of the first guiding means and is above the first conveying surface and that reverses the direction of the article that has contacted;
The conveying means conveys the article in a forward or backward posture;
The first guide means is movable and guides the article that is not reversed by expanding and contracting to a position on the first transport surface that does not contact the abutting means, while the article to be reversed is the abutting means. Direction changing device characterized in that it is guided to a position where it comes into contact. The direction according to claim 1, wherein the first guide means includes a first guide belt that rotates laterally, and a speed difference is provided between a belt speed of the first guide belt and the first conveying surface. Conversion device. Article alignment means is provided on the upstream side of the conveying means,
The article alignment means is
A second transport surface on which the article is placed and travels;
A second guide means arranged in a direction intersecting the traveling direction of the second transport surface to guide the article from the side,
The second guide means has a second guide belt that rotates laterally,
The direction changing device according to claim 1 , wherein a speed difference is provided between the second guide belt and the second transport surface . The first transport surface is faster than the second transport surface.
The direction changing device according to claim 3 . Redirecting device according to any one of claims 1 to 4, wherein the article is a bread sectional area gradually reduced toward the one from the other in the longitudinal direction.

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