JP7398747B2 - Booklet page turning device and page scanning system - Google Patents

Description

The present invention relates to a device that turns over pages one by one of a booklet that is bound at least partially on one side, and a paper scanning system equipped with the device.

For example, in order to save space and improve accessibility, there is a desire to convert and save the contents of a partially bound booklet as data. For this reason, it is common practice to scan individual pages of the closed booklet with a scanner and convert them into data.

JP2009-32186A

However, the above-mentioned work is complicated and time-consuming, and each page of the bound booklet becomes disjointed.

The present invention has been made in view of the above circumstances, and its purpose is to provide a booklet page turning device that can automatically turn over the pages of a bound booklet one by one, and the device. The purpose of the present invention is to provide a paper scanning system with the following features.

According to the booklet page turning device according to claim 1, on the near side of the booklet placed on the workbench, the first end and the other end in the X direction each have a suction section at the end thereof. Place the first and second arms. The auxiliary mechanism includes a bar whose proximal end moves linearly along the X direction on the near side of the booklet and whose distal end extends in the Y direction. The control section is
1st step: When you press the first side of the booklet with the tip of the second arm,
Second step: When the suction part of the first arm attracts the second side of the paper surface of the booklet and lifts the paper surface upward to a predetermined height, a standby process is performed in which the operation of the arm is stopped for a predetermined period of time. In this standby process, for example, even if a paper surface that was in contact with the attracted paper surface before being lifted is lifted together due to the influence of static electricity, etc., the paper surface is waited for to fall due to its own weight.

Third step: Move the bar of the auxiliary mechanism so that it goes under the lifted paper surface.
Fourth step: By moving the bar of the auxiliary mechanism until it exceeds the first side, the page is turned over, that is, the closed booklet is opened.
Fifth step: The suction section of the second arm attracts the turned-over second side of the paper and pulls the paper outward. This eliminates the bending of the turned paper.

Sixth step: Move the tips of the first and second arms to the outside of the booklet with the paper side opened, and move the bar of the auxiliary mechanism to the initial position. As a result, there is no obstacle in the space above the opened booklet, and the image of the opened booklet can be scanned by a scanner or the like.

That is, by the control unit cyclically repeating the first to sixth steps, the pages of the booklet in the closed state are automatically turned over one by one, and both pages are successively opened. Therefore, by scanning images with a scanner or the like and converting them into data when each page is opened, all the contents written in the closed booklet can be converted into electronic data without operator intervention. becomes possible.

According to the booklet sheet turning device according to claim 2, in the second step, the control section causes the suction section of the first arm to suction the second side of the sheet surface of the booklet to raise the sheet surface to a predetermined height. When lifting the paper, the suction section first holds down the center of the second side of the paper, moves the suction section once to the end in the Y direction, returns to the center again, and then lifts the paper. By controlling in this manner, the paper surface can be properly adjusted and lifted without distorting it.

According to the booklet page turning device according to claim 3, in the third step, when moving the bar of the auxiliary mechanism below the page surface, the control section lifts the page surface to a predetermined height using the first arm. In this state, when the auxiliary mechanism is moved to between the suction part of the first arm and the first side of the page, it is once returned in the opposite direction. By controlling in this way, if there is any deflection in the paper being turned by the auxiliary mechanism, the auxiliary mechanism can return in the opposite direction to eliminate the deflection, and the paper can be turned more reliably. You will be able to do this.

According to the booklet page turning device according to claim 4, in the third step, when the bar of the auxiliary mechanism is moved below the paper surface, the control section stops the suction of the paper surface by the suction section of the first arm. Have the person press down on the second side of the next page below the page. By controlling in this way, it is possible to reliably prevent the next paper surface from rising.

According to the booklet surface turning device according to claim 5, the first and second holding mechanisms are arranged on one side of the booklet on the workbench, and are arranged on the closed side and open side of the booklet, respectively. It acts as if holding down a part of the body from above. Then, before starting the first step, the control unit causes the first pressing mechanism to press down a part of the corresponding paper surface. This prevents the paper from bending when the first side of the booklet is pressed by the end of the second arm in the first step, and releases the pressed state before starting the second step. Then, the first arm prepares for the lifting operation of the paper surface.

Further, after the standby process of the first arm is completed and the paper surface that has been lifted along with it falls due to its own weight, a part of the paper surface is pressed down by the first holding mechanism, as described above. Furthermore, after executing the fifth step, by having the second pressing mechanism press a part of the corresponding paper surface, it is possible to move the tips of the first and second arms to the outside of the booklet in the sixth step. , the flipped paper surface and the closed paper surface can each be pulled outward and held in an extended state.

According to the booklet page turning device according to claim 6, after moving the bar of the auxiliary mechanism in the fourth step, the control section moves the first side of the page turned over by the hand of the first arm. Press in the X direction. As a result of moving the bar of the auxiliary mechanism beyond the first side, the tip of the first arm presses the first side of the paper in the X direction even if the page is not turned over completely. By doing this, you can assist the movement of turning the page.

According to the booklet page turning device according to claim 7, in the fourth step, when the first side of the paper surface is pressed in the X direction by the hand of the first arm, the control section moves the suction section between the paper surface and the bar. Try to get it in between. Then, move the hand in the Y direction and then move it upward. This operation allows the operation of turning over the pages to be completed.

According to the booklet page turning device according to claim 8, when pulling the page outward in the fifth step, the control section moves the tip of the second arm upward and then moves it in the X direction. Pull outward, then move your hand downwards to press the paper against the workbench. This makes it possible to more reliably eliminate bending of the turned paper surface.

According to the booklet page turning device according to claim 9, a Bernoulli chuck is used for the suction portion of the first arm. By using a Bernoulli chuck, a part of the paper surface will not be suctioned excessively, and damage such as wrinkles on the adsorbed part of the paper surface and its surroundings can be avoided, and the suctioned paper surface can be removed smoothly. I can do it.

According to the booklet page turning device according to claim 10, an imaging section for capturing an image of the booklet on the workbench is disposed on the first arm, and the control section controls the image captured by the imaging section in the fourth step. Based on this, it is determined whether the page has been turned over. Then, if the paper has not been turned over, error processing is performed. With this configuration, the control unit can reliably judge based on the image whether or not the page has been turned over in the fourth step, and can perform a notification operation or retry the fourth step if necessary. It becomes possible to perform error handling such as

According to the booklet page turning device according to the eleventh aspect, the suction portion of the second arm has a rod shape extending along the Y direction. This allows the second arm to more efficiently perform operations such as holding down the first side of the booklet along that side in the first step and pulling the turned page outward in the fifth step. .

According to the booklet page turning device according to the twelfth aspect, the bar of the auxiliary mechanism has a rectangular shape with the long side in the Y direction, and the surface of the bar is inclined in the direction of turning the page with respect to the surface of the workbench. By slanting the surface of the rectangular bar in this way, when moving the bar in the third step, it becomes easier to move the bar under the lifted paper surface.

According to the booklet page turning device according to the thirteenth aspect, vertical six-axis robot arms are used as the first and second arms. That is, by using a vertical 6-axis robot arm with a relatively high degree of freedom, the necessary movements as the first and second arms can be easily executed.

According to the paper scanning system according to claim 14, the booklet page turning device according to any one of claims 1 to 13, a supply device that supplies the booklet to the workbench from the first arm side, and the workbench. The present invention includes a scanning device that scans the paper surface of a booklet located on the workbench, an ejecting device that ejects the booklet from the workbench from the second arm side, and a control device that controls the operation of each of these devices. With this configuration, the pages of the booklet supplied from the supplying device are sequentially scanned by the scanning device while being turned over by the page turning device, and the booklets that have been scanned are ejected by the discharging device automatically. can be set. Therefore, it becomes possible to quickly scan the paper surface of a booklet and convert it into electronic data.

According to the paper scanning system according to the fifteenth aspect, the control device causes the suction transfer section to move the booklet located at the top of the suction side storage section above the conveyance section, and then stops the suction. Place it on the transport section. Next, when the supply-side X-direction transfer section moves the conveyance section in the +X direction with the transport section positioned above the stopper on the workbench and transfers the booklet to a predetermined position on the workbench, the slit moves to the stopper. Position the conveyance unit so that it hangs over it, and then move it in the -X direction. Note that the "+X direction" is a direction from the first arm side to the second arm side, and the "-X direction" is the opposite direction. With this control, after the booklet has been transferred to a predetermined position on the workbench by the transfer section, the second side of the booklet will come into contact with the stopper when the transfer section is retracted in the -X direction, so that the booklet will not be transferred to the transfer section. The booklet can be reliably placed at a predetermined position on the workbench without leaving anything behind.

According to the paper scanning system according to claim 16, before the booklet scanning process is started, the control device causes the ejection side X-direction transfer unit to move the conveying unit on the workbench in advance so that the booklet on which the scanning process has been completed is loaded. Move it to the location where it will be placed. When the booklet scanning process is completed, the conveying section is moved in the +X direction while being positioned above the stopper provided near the ejection side storage section, and when the slit reaches the position where it engages with the stopper, After the conveying section is lowered so that the slit engages with the stopper, the conveying section is further moved in the +X direction to move the booklet to the discharge side storage section. If controlled in this manner, the first side of the booklet will come into contact with the stopper when the booklet is transferred to the discharge side storage section by the conveyance section, so the booklet will not remain in the conveyance section and the booklet will be transferred to the discharge side storage section. can be reliably placed.

According to the paper scanning system according to claim 17, the control device adjusts the position of the booklet supplied to the workbench by the supply device based on the image captured by the imaging device disposed on the second arm. A correction process is performed in which the adsorption portion of the arm corrects each corresponding side so that it is along the Y direction and the X direction, respectively. By controlling in this manner, even if the position of the booklet fed by the feeding device is misaligned, it can be corrected so that each side is along the Y direction and the X direction, respectively.

A perspective view showing the appearance of a paper turning device according to the first embodiment Plan view showing the appearance of the paper turning device Side view showing the appearance of the paper turning device Functional block diagram showing the configuration of the control system A perspective view showing the initial state of the paper turning device Perspective view showing operation 1 A diagram schematically showing a state in which the suction pad 10 presses the booklet B Perspective view showing operation 2 Perspective view showing operation 3 A diagram schematically showing the state of paper surfaces Pu and Pd that overlap vertically in operation 3. Perspective view showing operation 4 (part 1) Perspective views showing operation 4 (part 1) from different angles Perspective view showing operation 4 (part 2) Perspective views showing operation 4 (part 2) from different angles Perspective view showing operation 5 Perspective views showing operation 5 from different angles A diagram schematically showing a state in which the paper surface P is pressed by the suction pad Perspective view showing operation 6 A diagram schematically showing the virtual movement of the bar Perspective view showing operation 7 Diagram schematically showing operation 8 Perspective view showing operation 9 Perspective views showing operation 9 from different angles Diagram schematically showing operation 9 Perspective view showing operation 10 (part 1) Perspective view showing operation 10 (part 2) Perspective view showing operation 10 (part 3) Perspective view showing operation 11 Perspective view (part 1) of the second embodiment showing operation 2 Perspective view showing operation 2 (part 2) Perspective view showing operation 2 (part 3) Perspective view showing operation 2 (part 4) Perspective view showing operation 5 (part 1) Perspective view showing operation 5 (part 2) Perspective view showing operation 5 (part 3) Perspective view showing operation 5 (part 4) This is a third embodiment, and is a perspective view (part 1) showing a paper scanning system and showing operation E2. Functional block diagram showing the configuration of the control system Perspective view showing operations S1 and E1 (part 1) Perspective view showing operation S1 (Part 2) Perspective view showing operation S2 Perspective view showing operation S3 Perspective view showing operation 0 (part 1) Perspective view showing operation 0 (Part 2)

(First embodiment)
The first embodiment will be described below with reference to FIGS. 1 to 28. 1 to 3 are a perspective view, a plan view, and a side view showing the appearance of the page turning device of this embodiment. The paper turning device 1 has pedestals 3L and 3R provided on the rear side of a rectangular workbench 2, and two vertical 6-axis robots 4L and 3R, which are relatively small in size, are mounted on the pedestals 3L and 3R. 4R is arranged. The robots 4L and 4R correspond to the first and second arms, respectively. As the robot 4, for example, COBOTTA (registered trademark) manufactured by Denso Wave Corporation is used.

In the following description, the left-right direction of the workbench 2 in FIG. 1 will be referred to as the X direction, and the depth direction of the workbench 2 will be referred to as the Y direction. Further, the left and right are basically shown with the robots 4L and 4R facing the workbench 2, but depending on the figure, the left and right in the figure may be shown.

On the workbench 2, a booklet B bound on one side is initially placed on the left side of the workbench 2 in a completely closed state. From this state, the page turning device 1 operates to turn over the pages P constituting each page of the booklet B one by one to the right using the robot 4 or the like.

A drive unit 6 of the auxiliary jig 5 is arranged between the workbench 2 and the pedestal 3. The drive unit 6 is a linear actuator, and linearly moves the movable unit 8 in the X direction, to which the base end of a bar 7 extending in the Y direction is attached. The drive source of the drive unit 6 is, for example, air. The bar 7 has a rectangular shape, and its surface is sloped so that the right side of the short side is slightly lower than the left side. The auxiliary jig 5 corresponds to an auxiliary mechanism.

A non-contact suction pad 9 as a suction part is attached to the hand of the robot 4L. For the non-contact suction pad 9, a Bernoulli chuck or the like is used, for example. The suction pad 9 has a short cylindrical outer shape, and generates a swirling flow inside the pad by jetting air sent from a compressor (not shown) from a nozzle on the side facing the workbench 2. Then, by releasing air into the atmosphere from the gap between the pad 9 and the paper surface P, which is the object of suction, a negative pressure is generated between the pad 9 and the paper surface P, and the paper surface P is attracted in a non-contact state. On the other hand, a suction pad 10 as a suction unit is attached to the hand of the robot 4R. The suction pad 10 has a bar shape extending in the Y direction, and suctions the paper surface P in a contact state by suctioning air with a compressor from a nozzle on the side facing the workbench 2. These pads 9 and 10 both attract and release the paper surface P by controlling air circulation, and correspond to a suction section.

Further, a camera 11 corresponding to an imaging section is attached to the wrist portion of the robot 4L. The camera 11 captures an image of the booklet B placed on the workbench 2, and based on the image, the IPC 15, which will be described later, is used to determine whether or not the operation of turning over the page P has been reliably executed. Ru.

On the back side of the workbench 2, a scanning device 12 that optically scans and reads the written content on the paper surface P, and clampers 13L and 13R for pressing the upper end side of the paper surface P are arranged. The scanning device 12 rotates a head (not shown) to perform reading from the front side of the device 12 toward the depth direction using a line-type CCD sensor (also not shown). The clampers 13L and 13R are arranged on both sides of the scanning device 12, and operate to press and release the upper end side of the page P by vertically rotating the clamp member 14 using, for example, a stepping motor as an actuator. . The clampers 13L and 13R correspond to first and second holding mechanisms.

FIG. 4 is a functional block diagram showing the configuration of the control system. Each component of the paper turning device 1 is controlled by an IPC 15, which is an industrial programmable controller. The IPC 15, which corresponds to a control section, controls the auxiliary jig 5, the suction pads 9 and 10, and the clampers 13L and 13R via the IO port. The scanning device 12 is connected to the IPC 15 via a USB (Universal Serial Bus) interface. Further, the IPC 15 is connected to the robots 4L, 4R and the camera 11 via Ethernet (registered trademark) via a switching hub 16. The switching hub 16 also has a function of supplying power to the camera 11.

Next, the operation of this embodiment will be explained. Hereinafter, the bound side of the booklet B will be referred to as the "back side," and the side that faces the back side and is turned over will be referred to as the "open side." The back side corresponds to the first side, and the open side corresponds to the second side. Furthermore, the reference numerals of each part are given only to the key points of the operation, and the hoses that connect the pads 9 and 10 to the compressor and allow air to flow therethrough are omitted from illustration.

<Initial state; initial scan>
As shown in FIG. 5, in the initial state, the auxiliary jig 5 is located on the left end side of the workbench 2, and the hands of the robots 4L and 4R are located on the left end side and the right end side of the workbench 2, respectively. . Furthermore, both clampers 13L and 13R move the clamp member 14 upward. A closed booklet B is placed on the left half of the workbench 2. In this state, the scanning device 12 first performs scanning, and if booklet B is placed, starts reading. If booklet B is not placed, it is determined that there is no work target, and an error warning or work completion report is issued via the IPC 15 and a user interface (not shown).

<Operation 1; Hold down the back of booklet B>
Next, as shown in FIG. 6, the robot 4R moves the suction pad 10 at its hand to the back side of the booklet B and presses it from above (first step). Further, the clamp member 14L of the clamper 13L is moved downward to press the upper end side of the booklet B. FIG. 7 schematically shows a state in which the suction pad 10 presses the booklet B. As shown in FIG. In order to prevent the paper surface P on the top layer of the booklet B from shifting or slipping, it is desirable to hold it at a position slightly to the right of the left end of the booklet B in the figure.

<Operation 2; Pick up the open side of booklet B>
Next, as shown in FIG. 8, the robot 4L moves the suction pad 9 at its hand to the open side of the booklet B, presses it lightly from above, and uses the suction pad 9 to suction the top layer of paper P in a non-contact state. .

<Operation 3; Lifting the top layer of paper P>
Next, as shown in FIG. 9, after moving the clamp member 14L of the clamper 13L upward, the robot 4L lifts the uppermost paper surface P upward and performs a standby process in which it waits in that state for a certain period of time. 2 steps). At this time, as shown in FIG. 10, the angle θ formed when the robot 4L stops its operation by lifting the paper surface P upward is, for example, about 30 degrees to 45 degrees. When the suction pad 9 lifts the uppermost paper surface Pu, the paper surface Pd in contact with the paper surface Pu is lifted together with the paper surface Pu in a state stuck to the paper surface Pu due to the suction force and electrostatic force of the suction pad 9 acting slightly. is assumed.

The paper surface Pd is pulled in the vertical direction by a force G1 that is the result of gravity acting on its own weight. If the force with which the suction pad 9 suctions the top layer of paper Pu is F1, and the vertical component corresponding to the angle θ is F1-1, then the angle θ may be such that (F1-1)<G1 holds. . The purpose of the standby process performed here is to wait for the paper surface Pd to be pulled by the force G1 and fall toward the workbench 2. When the standby process is finished, the clamp member 14L of the clamper 13L is moved downward to press the upper end side of the booklet B, that is, the paper surface Pd.

<Operation 4; Movement of bar 7 of auxiliary jig 5>
Next, as shown in FIGS. 11 to 14, the bar 7 of the auxiliary jig 5 is moved from the initial position in the X direction to be positioned below the paper surface P being lifted by the robot 4L.

<Operation 5; Release of paper surface Pu by suction pad 9 → Pressing of paper surface Pd on the open side>
Next, as shown in FIGS. 15 and 16, when the paper surface Pu is released from suction by the suction pad 9, the hand of the robot 4L moves to the open side of the paper surface Pd and presses it from above (third step). At this time, suction by the suction pad 9 is not necessary, and as shown in FIG. 17, there is no problem even if the booklet B is pressed at a position slightly protruding from the right end in the figure. Further, the hand of the robot 4R is moved upward to release the pressure on the back side of the paper surface Pu by the suction pad 10.

<Operation 6; Movement of robot 4R to the right and turnover of paper surface Pu by bar 7>
Next, as shown in FIG. 18, the suction pad 10 is moved rightward; +X direction. Note that the drive unit 6 is not controlled using a sensor, and only moves from the initial position in the right direction (+X direction) when turned ON, and to the left (-X direction) when turned OFF. Therefore, a stopper 17 is arranged in the middle of the movement path of the movable part 8, and when the movable part 8 comes into contact with the stopper 17, the bar 7 is approximately moved in the +X direction at a position near the back side of the booklet B. Movement stops. At this point, the paper surface Pu is turned over using the bar 7 (fourth step).

As shown in FIG. 19, if the bar 7 is moved to a position that slightly exceeds the back of the booklet B, the paper surface Pu can be completely turned over, but in order to shorten the working time, It is desirable to turn off the drive section 6 at the position where the movable section 8 abuts the stopper 17 and return it to the initial position.

<Operation 7; Confirmation of turnover of paper surface Pu by camera 11>
Next, as shown in FIG. 20, the wrist of the robot 4L is brought close to the center of the workbench 2, and an image of the booklet B is captured by the camera 11. The IPC 15 analyzes the image and confirms whether the paper surface Pu has been turned over, that is, whether it has been "turned over." If the paper surface Pu has not been completely turned over, the following operation 8 is performed, for example, as error processing.

<Operation 8; Error processing, assist operation by robot 4L>
As the above-mentioned error processing, for example, as schematically shown in FIG. Let it get into you. Then, move the hand in the +Y direction and then move it in the +Z direction. The suction pad 9 is operated in this manner to assist in turning over the paper surface Pu. In addition, as a plan to avoid the occurrence of an error in operation 6, when the bar 7 is moved to a position that slightly exceeds the back side of the booklet B, without turning off the drive unit 6, the bar 7 is moved to the right end side of the workbench 2. It is also conceivable to move it until it reaches . In this case, the confirmation work in operation 7 may be omitted.

<Operation 9; Resolving the bending of the turned paper surface Pu>
Even if the paper surface Pu is completely turned over in operation 6, it is assumed that the paper surface Pu is bulged and bent near the back side of the booklet B. In the next operation 10, the suction pad 10 of the robot 4R is scheduled to suction the right end side of the turned paper surface Pu. However, if the paper surface Pu is largely bent near the back side of the booklet B, the hands of the robot 4R may not be able to reach it, and the suction pad 10 may not be able to suction it. Therefore, as shown in FIGS. 22 to 24, the hand of the robot 4L is moved to the back side of the booklet B so that the suction pad 9 pushes out the bent portion of the paper surface Pu in the +X direction. This eliminates the bending of the paper surface Pu and brings it closer to a flat state.

<Operation 10; Leveling operation of the turned paper surface Pu>
Next, as shown in FIGS. 25 to 27, the hand of the robot 4R is moved to the right end side of the turned-up paper surface Pu, and the paper surface Pu is sucked by the suction pad 10, and the hand is moved slightly upward and then +X direction and pull the paper surface Pu in the same direction to level it (fifth step). Then, the clamp member 14R of the clamper 13R is moved downward to press the upper end side of the paper surface Pu.

<Operation 11; Scanning paper surfaces Pu and Pd>
Then, as shown in FIG. 28, the hands of the robots 4L and 4R are moved to the outside of the workbench 2, and the bar 7 is returned to the initial position (sixth step), with the paper surfaces Pu and Pd opened to the right and left. , the scanning device 12 scans the information written on each paper and converts it into electronic data.

This completes the series of operations, returns to operation 1, and repeats operations up to operation 11. As a result, each page of the booklet B is sequentially turned over one by one while the scanning device 12 scans the pages.

<Operation 12; Completion confirmation>
When the page turning device 1 turns over all the pages, the booklet B on the workbench 2 is closed on its right half. In this state, when the scanning device 12 performs scanning in operation 11, it is recognized that there is no paper surface on the left half of the workbench 2. As a result, the controller determines that there is no page to be turned next, and ends the operation of the page turning device 1.

As described above, according to the paper turning device 1 of this embodiment, the suction pads 9 are placed at one end and the other end in the X direction on the near side of the booklet B placed on the workbench 2, respectively. Robots 4L and 4R equipped with 10 are placed. The auxiliary jig 5 includes a bar 7 whose proximal end side moves linearly along the X direction on the near side of the booklet B, and whose distal end side extends in the Y direction. When the back side of the booklet B is pressed by the suction pad 10 on the robot 4R side, the IPC 15 causes the suction pad 9 on the robot 4L side to suction the open side of the paper surface P of the booklet B, and lifts the paper surface P upward to a predetermined height. The robot 4L is made to lift up and perform a standby process in which the operation of the robot 4L is stopped for a predetermined period of time.

Next, the bar 7 of the auxiliary jig 5 is moved to enter below the paper surface Pu, the suction by the suction pad 9 is stopped, and then the open side of the next paper surface Pd is suctioned. Then, when the bar 7 is moved beyond the back side and the paper surface Pu is turned over, the suction pad 10 attracts the turned open side of the paper surface Pu and pulls the paper surface Pu outward to smooth out the flexure of the paper surface Pu. Then, the hands of the robots 4L and 4R are moved to the outside of the booklet B with the paper surfaces Pu and Pd opened, and the bar 7 is moved to the initial position.

By the IPC 15 cyclically repeating the above process, the pages P of the booklet B in the closed state are automatically turned over one by one, and both pages are successively opened. Therefore, if the scanning device 12 scans the image and converts it into data when each page is opened, all the contents written in the booklet B in the closed state can be converted into electronic data without the operator's intervention. It becomes possible to become

Further, the clampers 13L and 13R are placed on the upper side of the booklet B on the workbench 2, and the IPC 5 causes the clamper 13L to press the upper side of the corresponding paper surface P before starting the first step. Therefore, when the opening side of the booklet B is pressed by the suction pad 9, the paper surface P is prevented from being bent, and the pressed state is released before the second step is started, so that the robot 4L can press the paper surface P. Prepare for lifting action.

Further, after the standby process of the robot 4L is completed and the paper surface Pd lifted together with the paper surface Pu falls due to its own weight, the upper side of the paper surface Pd is held down by the clamper 13L. Furthermore, even if the fingers of the robots 4L and 4R are moved to the outside of the booklet B in the sixth step by having the clamper 13R press down the upper side of the paper surface P corresponding to the fifth step, The paper surface P on the turned-over side and the closed side can each be pulled outward and maintained in an extended state.

Further, after moving the bar 7 in the fourth step, the IPC 15 presses the back side of the turned-up page P in the X direction with the pad 9 of the hand of the robot 4L. At this time, in order to insert the suction pad 9 between the paper surface Pu and the bar 7, the hand is moved in the +Y direction and then in the +Z direction. By operating the suction pad 9 in this manner, assist processing is performed so that the paper surface Pu can be completely turned over. Thereby, even if the movement of turning over the page P is incomplete as a result of moving the bar 7, the hand of the robot 4L can assist in the turning operation and bring it to a perfect state.

In addition, when pulling the paper surface P outward in the fifth step, the IPC 15 moves the hand of the robot 4R upward, moves it in the X direction, pulls it outward, and then moves the hand downward. to press the paper surface P against the workbench 2. Thereby, it is possible to more reliably eliminate the bending of the turned paper surface P.

In addition, since a Bernoulli chuck is used for the suction pad 9, a part of the paper surface P is not excessively suctioned, and damage such as wrinkles on the suctioned part of the paper surface P and its surroundings can be avoided. The removed paper surface P can also be removed smoothly.

Further, a camera 11 for capturing an image of the booklet B on the workbench 2 is arranged on the robot 4L, and the IPC 15 determines whether or not the paper page P has been turned over based on the image captured by the camera 1 in the fourth step. . Then, if the page P has not been turned over, error processing is performed. As a result, the IPC 15 can reliably determine whether or not the page P has been turned over, and can perform error processing such as performing a notification operation or retrying the fourth step as necessary. . Note that the above-mentioned assist processing may be performed as the error processing here.

Moreover, since the shape of the suction pad 10 is made into a bar shape extending along the Y direction, the robot 4R can more efficiently perform operations such as pressing the back side of the booklet B and pulling the turned-up paper surface P outward. I can do it.

Furthermore, the bar 7 is made into a rectangular shape whose long side is in the Y direction, and the surface of the bar 7 is inclined with respect to the surface of the workbench 2 in the direction in which the paper surface P is turned over, so that when the bar 7 is moved, the paper surface P It will be easier to get it under. In addition, by using the vertical six-axis robot 4 for the first and second arms, the necessary operations for the first and second arms can be easily executed.

(Second embodiment)
Hereinafter, parts that are the same as those in the first embodiment are given the same reference numerals and explanations will be omitted, and different parts will be explained. In the first embodiment, in <operation 2>, when the suction pad 9 suctions the uppermost paper surface P, the suction pad 9 is positioned at the center of the paper surface P on the open side, as shown in FIG. Ta.

On the other hand, in <Operation 2> of the second embodiment, as shown in FIGS. 29 to 32, when the suction pad 9 first holds down the central part of the open side of the paper surface P, the suction pad 9 is temporarily pressed down. After it is moved to the front end in the Y direction, it is returned to the center again and the paper surface P is sucked and lifted. By controlling in this way, the paper surface P can be properly adjusted and lifted without being distorted.

In addition, in the first embodiment, as shown in FIGS. 11 to 14, in <operation 4>, the bar 7 of the auxiliary jig 5 is moved to the robot while the closed side of the paper surface P is pressed by the suction pad 10 of the robot 4R. When 4L is positioned below the paper surface P being lifted, in the following <operation 5>, after the suction pad 9 releases the paper surface Pu, the suction pad 9 presses the paper surface Pd from above.

On the other hand, in <Operation 5> of the second embodiment, as shown in FIGS. 33 and 34, the suction pad 10 is retracted to the right side and then the bar 7 is started to move. Further, the suction pad 9 continues to attract the paper surface Pu without pressing the paper surface Pd. For example, if the paper surface Pu and the paper surface Pd below it can be separated without any problem in <operation 4> depending on conditions such as the paper quality of the booklet B and the humidity during operation, such control may be performed.

In addition, in the first embodiment, in <operations 4 to 6>, the bar 7 is moved in the +X direction at once until the movable part 8 of the auxiliary jig 5 comes into contact with the stopper 17, and the paper surface Pu being lifted by the robot 4L is They were causing turnovers. On the other hand, in <Operation 5> of the second embodiment, as shown in FIGS. 34 to 36, once the bar 7 is moved between the suction pad 9 and the first side of the paper surface Pu, the bar 7 is moved in the opposite direction. , that is, return it to the -X direction. Then, the movable part 8 is moved again in the +X direction and brought into contact with the stopper 17.

By controlling in this way, when the paper surface Pu that is being turned over by the bar 7 is deflected, the bar 7 returns in the opposite direction to eliminate the deflection, thereby making the paper surface Pu more You will be able to turn the pages with certainty.

(Third embodiment)
The third embodiment shows a paper scanning system 23 in which a booklet B supplying device 21 and ejection device 22 are added to the paper turning device 1 and the scanning device 12. As shown in FIG. 37, the supply device 21 is arranged on the robot 4L side of the paper turning device 1, and the discharge device 22 is arranged on the robot 4R side.

The feeding device 21 is in the form of a small rectangular desk with the longitudinal direction of the main body 24 along the Y direction, and its upper surface is substantially flush with the plane of the workbench 2 of the paper turning device 1 . A stocker 25 is provided in a portion of the main body 24 located on the left side of the robot 4L to accommodate a plurality of booklets B in a stacked state inside the main body 24. A push-up mechanism 26 for pushing up the booklet B located at the top to near the top surface is disposed inside the stocker 25 corresponding to the supply-side storage section.

The main body 24 is provided with a Y-direction transfer section 27 that transfers the booklet B from the stocker 25 in the +Y direction. The Y-direction transfer section 27, which corresponds to the suction transfer section, includes a linear transfer arm 28, a movable section 29 that moves in the Y direction along the transfer arm 28 by an actuator, and is located below the movable section 29. A suction pad 30 is provided.

An X-direction transfer section 31 for transferring the booklet B to the workbench 2 of the page turning device 1 is arranged at the front of the main body 24 in the figure. Incidentally, on the robot 4L side of the workbench 2, two convex stoppers 18, which are related to the operation of the X-direction transfer unit 31, are provided so as to be lined up in the Y-direction. The X-direction transfer section 31 on the supply side includes a linear transfer arm 32, a movable section 33 that moves in the X direction along the transfer arm 32 by an actuator, and a substantially L-shaped portion whose base is fixed to the movable section 33. The support arm 34 has a shape, and a conveyance section 35 is attached to the distal end of the support arm 34.

The conveyance section 35 has a plate shape having approximately the same area as the booklet B, and has slits 36 formed in the X direction to match the positions of the two stoppers 18 provided on the workbench 2. Further, the left end of the transport section 35 is bent to stand up vertically, and the tip of the support arm 34 is attached to the upright portion. The Y direction transfer section 27 and the X direction transfer section 31 correspond to a supply transfer mechanism.

The discharge device 22 has a small rectangular desk shape with the longitudinal direction of the main body 41 along the X direction, and its upper surface is substantially flush with the plane of the workbench 2 . A stocker 42 is provided in a portion of the main body 41 located to the right of the workbench 2. The stocker 42 accommodates the booklets B that have been scanned in a stacked state. A lowering mechanism (not shown) for lowering and storing the booklet B is disposed inside the stocker 42, which corresponds to the discharge side storage section.

The main body 41 is provided with an X-direction transfer unit 44 that transfers the booklet B that has been scanned from the workbench 25 to the stocker 42 . The X-direction transfer section 44, which corresponds to the discharge transfer mechanism, includes a linear transfer arm 45, a movable section 46 that moves in the X direction along the transfer arm 45 by an actuator, and a base fixed to the movable section 46. It includes a substantially L-shaped support arm 47 and a transport section 48 attached to the tip of the support arm 47. The right end of the conveyance section 48 is bent to stand up vertically like the conveyance section 35, and the tip of the support arm 47 is attached to the upright portion.

On the right side of the stocker 42, like the stopper 18, two convex stoppers 49 related to the operation of the X-direction transfer section 44 are provided. The conveyance section 48 is generally plate-shaped and has approximately the same area as the booklet B, and has slits 50 formed in the X direction that match the positions of the two stoppers 49. As shown in FIG. 38, the operations of the supply device 21 and the discharge device 22 are controlled by the IPC 15 as a control device. The paper scanning system 23 is configured as described above. The shape of the bar 19 of the page turning device 1 is such that convex pieces 20 are provided at two locations in the Y direction on the lower surface side of the bar 7.

As shown in FIG. 38, the supply device 21 and the discharge device 22 are controlled by the IPC 15. Further, a camera 11R is also arranged at the end of the robot 4R, and the camera 11R is also connected to the IPC 15 via the switching hub 16. Accordingly, the camera on the robot 4L side is the camera 11L.

Next, the operation of the third embodiment will be explained with reference to FIGS. 39 to 44. In addition, in the following, operation numbers related to the supply device 21 are indicated with a suffix "S", and operation numbers related to the discharge device 22 are indicated with a suffix "E". Further, although the IPC 15 is the main body that controls the operations of the devices 21 and 22, in order to simplify the explanation, the description will be made so that the devices 21 and 22 are the main body. Further, since the operations of the devices 21 and 22 will be mainly explained below, for the sake of convenience, some drawings are not connected to the flow of the operations of the page turning device 1.

<Operation S1; Supply of booklet B (1)>
As shown in FIGS. 39 to 40, the supply device 21 adsorbs the booklet B pushed up near the top surface of the stocker 25 by the push-up mechanism 26 with the suction pad 30 of the Y-direction transfer section 27, and After transporting the booklet B above the transport section 35, the adsorption is released and the booklet B is placed on the transport section 35.

<Operation S2; Supply of booklet B (2)>
From the state shown in FIG. 37, the transport section 35 is moved in the X direction as shown in FIG. 41 to supply the booklet B to the left half side of the workbench 2. The movable section 33 of the X-direction transfer section 31 can move up and down slightly, and when feeding the booklet B to the workbench 2, the transfer section 35 is moved so that the booklet B reaches the stopper 18 of the workbench 2. Move it in the X direction while positioning it at a height where it does not touch.

<Operation S3; Supply of booklet B (3)>
When the opening side of the booklet B exceeds the position of the stopper 18, the conveying section 35 is moved downward so that the slit 36 engages with the stopper 18. Then, as shown in FIG. 42, the conveyance section 35 is moved in the -X direction and evacuated from the workbench 2. At this time, even if the booklet B is dragged by the transport section 35 and moves in the -X direction, the opening side comes into contact with the stopper 18, so that the movement is blocked there.

<Operation 0; Adjust position of booklet B>
Before starting the <initial scan> of the first embodiment, the paper turning device 1 determines the position of the booklet B supplied to the workbench 2 based on the image captured by the camera 10R, and determines the position of the booklet B by suction by the hand of the robot 4R. Correct using pad 10. As shown in FIG. 43, after applying the suction pad 10 to the closing side of booklet B to correct it along the Y direction, as shown in FIG. Correct it so that it follows the X direction.

<Operation E1; Preparing to eject booklet B>
As shown in FIG. 39, the discharging device 22 moves the conveyance section 48 of the X-direction transfer section 44 to the right half side of the workbench 2 in advance. From this stage, the page turning device 1 executes <Initial scan, operations 1 to 12>.

<Operation E2; Ejection of booklet B (1)>
When operation 12 is completed, the entire booklet B is placed on the conveyance section 48 as shown in FIG. Then, as shown in FIG. 41, the ejecting device 22 moves the transport section 48 of the X-direction transport section 44 in the X direction. Like the movable part 33, the movable part 46 can also move up and down slightly, and when ejecting the booklet B from the workbench, the transport part 46 is positioned at a height where it does not come into contact with the stopper 49 and moved in the X direction. move it to

When the right end of the conveying section 46 exceeds the position of the stopper 49, the conveying section 46 is moved downward so that the slit 50 engages with the stopper 49. Then, the conveyance unit 35 is moved in the X direction. Then, the right end of the booklet B comes into contact with the stopper 49, and the movement of the booklet B is stopped there, and the booklet B is removed from the conveying section 46 and stored in the stocker 42, as shown in FIG. Then, when the paper turning device 1 performs operation 0, the ejection device 22 executes operation E1.

As described above, according to the third embodiment, the supply device 21 supplies the stocker 25 that accommodates a plurality of loaded booklets B and the booklet B located at the top in the stocker 25 to the paper turning device 1. A stopper 18 is provided on the second side of the booklet B on the workbench 2. The supply transfer mechanism includes an X-direction transfer section 27 that adsorbs and transfers the booklet B from the stocker 25, and an X-direction transfer section 31 that moves the 35 transfer section in the X direction to transfer the booklet B to the workbench 2. , the IPC 15 uses the X-direction transfer section 27 to move the attracted booklet B above the transfer section 35, then stops the adsorption and places the booklet B on the transfer section 35, and the X-direction transfer section 31 moves the booklet B to the transfer section 35. 35 is transferred to the left half side of the workbench 2, the slit 36 is hooked to the stopper 18, and the slit 36 is moved in the -X direction. If controlled in this manner, the second side of the booklet B will come into contact with the stopper 18 when the transport section 35 is retracted in the -X direction, so the booklet B will not remain on the transport section 35 and the booklet B will be moved to the workbench. can be reliably placed in the specified position.

In addition, before the scanning process for the booklet B is started, the IPC 15 moves the transport unit 46 to the right half side of the workbench 2 in advance using the X-direction transport unit 44 of the ejection device 22. When the scanning process for booklet B is completed, the conveying section 46 is moved in the +X direction, and when the slit 50 reaches the position where it engages with the stopper 49, the slit 50 of the conveying section 46 engages with the stopper 49. From there, the conveyance section 46 is further moved in the +X direction to move the booklet B to the stocker 47. If controlled in this way, the first side of the booklet B will come into contact with the stopper 49, so the booklet B will not remain in the transport section 46, and the booklet B can be reliably stored in the stocker 47.

Further, the IPC 15 allows the suction unit 10 of the robot 4R to adjust the position of the booklet B supplied to the workbench 2 by the supply device 21 based on the image captured by the camera 12 disposed on the arm of the robot 4R. A correction process is performed to correct each side so that each side is along the Y direction and the X direction. Therefore, even if a shift occurs in the position of the booklet B supplied by the supply device 21, it can be corrected so that each side is along the Y direction and the X direction, respectively.

The present invention is not limited to the embodiments described above or illustrated in the drawings, but can be modified or expanded as described below.
The two arms are not limited to vertical six-axis robots, and the specific configuration of each arm is not critical as long as it can perform similar tasks.
The plane of the bar 7 may be parallel to the workbench 2. Further, the shape of the bar does not have to be rectangular, and may be, for example, round or square.
The non-contact suction pad 9 may be a non-contact suction pad other than a Bernoulli chuck, or may be a contact type suction pad.

The shape of the suction pad 10 does not have to be rod-like, and may be circular like the suction pad 9, for example.
The camera 11 may be provided as necessary.
Instead of the stopper 17, the bar 7 may be brought into contact with the robot 4R to regulate the movement position.
The booklet B does not need to be bound all the way on the back side, but only needs to be bound on at least part of the sides.

The camera 10R placed at the hand of the robot 4R detects the paper surface Pu based on the image captured by the camera 10R, for example, when moving the hand in the +X direction after sucking the paper surface Pu with the suction pad 10 in the fifth step of operation 10. Detect the slope of Then, the inclination may be corrected and the paper surface Pu may be moved in the +X direction in a state parallel to the workbench 2. As a result, the paper surfaces Pu and Pd can be scanned and read more clearly by the scanning device 12 in the subsequent operation 11.
An escape prevention member for preventing the paper from escaping in the −X direction may be provided on the lower surface of the bar 7 so as to extend downward.

In the drawings, 1 is a paper turning device, 2 is a workbench, 4L and 4R are robots, 5 is an auxiliary jig, 7 is a bar, 9 is a non-contact suction pad, 10 is a suction pad, 11 is a camera, and 12 is a scanning device , 13L and 13R are clampers, 15 is an IPC, 17 and 18 are stoppers, 21 is a supply device, 22 is a discharge device, and 23 is a paper scanning system.

Claims (17)

This involves turning over each page of a booklet, which is bound at least partially on one side, one by one.
a workbench on which the booklet is placed;
If the direction along the bottom side of the booklet on the front side is the X direction, and the direction perpendicular to this X direction and along the bound side of the booklet is the Y direction, then in both cases, the suction that attracts the paper surface to the hand. first and second arms arranged along the X direction on the workbench, facing the booklet;
an auxiliary mechanism including a bar whose proximal end side moves linearly along the X direction on the near side of the booklet and whose distal end side extends in the Y direction;
a control unit that controls the first and second arms and the auxiliary mechanism;
When the booklet is closed, the bound side is the first side, and the side opposite to this first side is the second side.
The control unit moves the bar of the auxiliary mechanism to an initial position on the second side,
a first step of pressing the first side of the booklet with the tip of the second arm;
When the suction portion of the first arm attracts the second side of the paper surface of the booklet and lifts the paper surface upward to a predetermined height, a standby process is performed in which the operation of the first arm is stopped for a predetermined period of time. The second step and
a third step of moving the bar of the auxiliary mechanism below the plane of the paper;
a fourth step of turning over the page by moving the bar of the auxiliary mechanism beyond the first side;
a fifth step of sucking the turned-over second side of the paper by the suction part of the second arm and pulling the paper outward;
a sixth step of moving the tips of the first and second arms to the outside of the booklet with the pages opened, and moving the bar of the auxiliary mechanism to the initial position. In the second step, when the suction unit of the first arm attracts the second side of the paper surface of the booklet and lifts the paper surface upward to a predetermined height,
The suction unit first holds down the central part of the second side of the paper surface, moves the suction part once to an end in the Y direction, and then returns to the central part again before lifting the paper surface. 1. The booklet page turning device described in 1. In the third step, when moving the bar of the auxiliary mechanism below the plane of the paper, the control unit moves the bar of the auxiliary mechanism in a state where the first arm lifts the plane of the paper upward to a predetermined height. 3. The booklet page turning device according to claim 1, wherein when the mechanism is moved between the suction portion of the first arm and the first side of the paper surface, it is temporarily returned in the opposite direction. In the third step, when the bar of the auxiliary mechanism is moved below the paper surface, the control section stops the adsorption section of the first arm from adsorbing the paper surface, and the next 4. The booklet page turning device according to claim 1, wherein the second side of the page is pressed down. disposed on the workbench on a side opposite to the first and second arms,
a first pressing mechanism that operates to press a portion of the paper surface on the closed side of the booklet from above;
a second holding mechanism that operates to press down a part of the paper surface on the opened side of the booklet from above;
Before starting the first step, the control unit causes the first pressing mechanism to press a portion of the corresponding paper surface,
Before starting the second step, the first holding mechanism releases the holding state, and when the standby process of the first arm is completed, a part of the next paper surface below the paper surface is moved to the first It is held down by the holding mechanism,
The booklet page turning device according to any one of claims 1 to 4, wherein after executing the fifth step, the second pressing mechanism presses down a part of the corresponding page. Claims 1 to 5, wherein in the fourth step, after moving the bar of the auxiliary mechanism, the control unit causes a hand of the first arm to press a first side of the turned-up page in the X direction. A device for turning the pages of a booklet as described in any one of the above. In the fourth step, when the first side of the paper surface is pressed in the X direction by the tip of the first arm, the control section causes the suction section to enter between the paper surface and the bar; 7. The booklet page turning device according to claim 6, wherein the hand is moved in the Y direction and then moved upward. In the fifth step, when pulling the paper surface outward, the control unit moves the tip of the second arm upward, moves it in the X direction and pulls it outward, and moves the tip of the second arm downward. The booklet page turning device according to any one of claims 1 to 7, wherein the booklet page turning device is operated so as to move and press the page on the workbench. The booklet page turning device according to any one of claims 1 to 8, wherein a Bernoulli chuck is used as the suction portion of the first arm. disposing an imaging unit on the first arm to take an image of the booklet on the workbench;
9. The control unit, in the fourth step, determines whether or not the page has been turned over based on the image captured by the image pickup unit, and performs error processing if the page has not been turned over. A device for turning the pages of a booklet as described in any one of the above. The booklet page turning device according to any one of claims 1 to 10, wherein the suction portion of the second arm has a rod shape extending in the Y direction. 12. The bar of the auxiliary mechanism has a rectangular shape with a long side in the Y direction, and a surface of the bar is inclined with respect to a surface of the workbench in a direction in which the page is turned over. A device for turning the pages of the booklet described in . 13. The booklet page turning device according to claim 1, wherein the first and second arms are vertical six-axis robot arms. A booklet page turning device according to any one of claims 1 to 13;
a supply device that supplies a booklet from the first arm side to a workbench of the paper turning device;
a scanning device that scans the paper surface of the booklet on the workbench;
an ejection device that ejects the booklet from the workbench from the second arm side;
A paper scanning system comprising: a control device that controls operations of the feeding device, the paper turning device, the scanning device, and the ejecting device. The supply device includes a supply side storage section that stores a plurality of booklets in a loaded state;
a supply transfer mechanism that transfers the booklet located at the top of the supply side storage section to the workbench of the paper turning device;
Providing convex stoppers at two locations on the second side of the booklet on the workbench,
The supply transfer mechanism includes a suction transfer unit that adsorbs and transfers the booklet located at the top of the supply side storage unit;
a supply side X-direction transfer unit that moves a plate-shaped transfer unit in which slits are formed in accordance with the positions of the two stoppers in the X direction to transfer the booklet to the workbench;
The control device causes the suction transfer unit to move the suctioned booklet above the conveyance unit, and then stops suction to place the booklet on the conveyance unit;
When the supply-side X-direction transfer section moves the transfer section in the +X direction while being positioned above the stopper to transfer the booklet to a predetermined position on the workbench, the slit is moved to the stopper. 15. The paper scanning system according to claim 14, wherein the conveyance section is positioned so as to hang thereon and then moved in the -X direction. The ejection device includes an ejection-side storage section that accommodates the booklet that has undergone the scanning process;
comprising a discharge transfer mechanism that transfers the booklet on the workbench to the discharge side storage section,
Providing convex stoppers at two locations on the first side of the booklet in the discharge side storage section,
The discharge transfer mechanism includes a discharge side X-direction transfer section that moves a plate-shaped conveyance section in which slits are formed in accordance with the positions of the two stoppers in the X direction to transfer the booklet to the discharge side storage section. and
The control device is configured to cause the ejection side X-direction transfer unit to move the transport unit in advance to a position on the workbench where the booklet that has undergone the scan process is placed, before the scan process of the booklet is started. Keep it
When the scanning process for the booklet is completed, the conveyance section is moved in the +X direction while being positioned above the stopper, and when the slit reaches a position where the stopper is engaged, the conveyance section is lowered. 16. The paper scanning system according to claim 14, wherein after the slit engages with the stopper, the transport section is further moved in the +X direction to move the booklet to the discharge side storage section. The suction part of the second arm of the paper turning device has a rod-like shape,
comprising an imaging device disposed on the second arm,
The control device is configured to control the position of the booklet supplied to the workbench by the supply device based on the image captured by the image pickup device, so that each side of the booklet supplied to the workbench by the suction portion of the second arm is arranged in the Y direction and 17. The paper scanning system according to claim 14, wherein the paper scanning system performs a correction process along the X direction.

Images