JP5761213B2 - Tablet sheet transport unit, and control method and program thereof. - Google Patents

Description

  The present invention relates to a tablet sheet conveyance unit, and a control method and program technology thereof.

Conventionally, in order to provide prescription tablets to patients in dispensing operations, the PTP sheets are transported one by one according to the form of the prescription, and the tablets contained in the PTP sheets are taken out from the PTP sheets or one by one There is an operation of taking out the PTP sheet from the storage shelf and providing it to the patient.
Patent Document 1 discloses a technique for preventing movement of a tablet sheet that is not in an appropriate posture by a movement prevention unit in order to select only tablet sheets in an appropriate posture.

  In Patent Document 2, in order to prevent double feeding of tablet sheets, when taking out from the tablet cassette, the previous tablet sheet is moved to a predetermined position at the timing when the pocket position of the previous tablet sheet is removed from the next tablet sheet. A technique for lifting the height is disclosed.

JP 2012-139317 A JP 2012-192191 A

  Patent Document 1 and Patent Document 2 are techniques for appropriately transporting tablet sheets one by one, but do not mention a technique related to recovery when the tablet sheets are not transported normally.

  A mechanism that prevents double feeding due to warping of the leading end of the PTP sheet that tends to be distorted when trying to convey the PTP sheet one by one with a plurality of PTP sheets stacked in the PTP sheet inlet In addition, a phenomenon occurs in which the warped leading edge is caught and the PTP sheets are not normally conveyed sequentially to the back of the insertion port.

  In such a case, the deformed PTP sheet that could not be normally conveyed is manually pushed up and down by hand, and if the conveyance is automatically stopped due to an error, an instruction to re-execute the sheet conveyance is given again. It is necessary to execute this, and such a response is very troublesome for the user. Further, the user has to check whether or not the PTP sheet is normally conveyed, and frequently has to visually check whether or not the PTP sheet is normally conveyed.

  The present invention relates to a user who has so far supported the user so that the sheet is normally conveyed from the insertion port even when the tablet sheet is not normally conveyed from the sheet insertion port to the back side of the insertion port. The purpose is to provide a mechanism that can reduce the time and effort.

  The tablet sheet transport unit of the present invention includes a transport mechanism for performing a transport operation of transporting a tablet sheet to a tablet take-out position where a tablet of the tablet sheet is taken out from an input portion on which a plurality of tablet sheets can be placed, and the transport mechanism Than the double feed prevention unit, which is positioned with a gap through which one tablet sheet can pass with respect to the tablet sheet holding surface located on the lower side in the gravity direction of the tablet sheet conveyed by A detection mechanism that is provided downstream of the tablet sheet in the conveyance direction and detects the passage of the tablet sheet; and after the conveyance operation is started, if the passage of the tablet sheet cannot be detected by the detection mechanism, the conveyance operation is predetermined. And a control means for controlling the transport mechanism so as to resume after a time stop.

The tablet sheet transport unit of the present invention is transported by a transport mechanism for performing a transport operation for transporting a tablet sheet to a tablet take-out position where a tablet is taken out from an input section on which a plurality of tablet sheets can be placed. A multi-feed prevention unit positioned with a gap through which one tablet sheet can pass with respect to the tablet sheet holding surface located below the tablet sheet in the gravity direction, and the tablet sheet more than the multi-feed prevention unit A detection mechanism for detecting the passage of a tablet sheet, and after the start of the conveyance operation, the detection mechanism cannot detect the passage of the tablet sheet to be conveyed by the conveyance mechanism. And a control means for controlling to vibrate the tablet sheet to be transported by the transport mechanism on the upstream side in the transport direction with respect to the double feed preventing portion.

  According to the present invention, even if the tablet sheet is not normally conveyed from the sheet input port to the back side of the input port, the user has been adapted to the user so far that the sheet is normally conveyed from the input port. It is possible to provide a mechanism that can reduce the time and effort.

The figure which shows a packaging apparatus and a tablet supply apparatus. The figure which shows a tablet supply apparatus. The figure which shows the internal structure of a tablet extraction unit. The figure which shows the internal structure of a tablet extraction unit. The figure which shows the internal structure of a tablet supply apparatus. The figure which shows the internal structure of a tablet supply unit. The figure which shows the internal structure of a packaging unit. The figure which shows operation | movement of the extrusion block of a tablet taking-out mechanism. The figure which shows operation | movement of the extrusion board of a tablet taking-out mechanism. The figure which shows a depackaging operation | movement. The figure which shows retry operation | movement (packaging speed). It is a figure which shows a flowchart. The figure which shows retry operation (unpacking position). The figure which shows a flowchart. The figure which shows a flowchart. The figure which shows a detection position and a depackaging position. The figure which shows a flowchart. The figure which shows the structure of the curvature correction mechanism of a tablet sheet. The figure which shows the order of the tablet pocket which a tablet taking-out unit performs unpacking operation | movement for every package from a tablet sheet. The figure which showed the internal structure of the unpacking motor mechanism of a tablet extraction unit. The figure which showed the case where a tablet extraction unit performs the unpacking operation | movement (normal time) of a left row. The figure which showed the case where a tablet extraction unit performs the unpacking operation | movement (normal time) of a right row. The figure which showed the case where a tablet extraction unit performs the unpacking operation | movement (at the time of a retry) of a left row. The figure which shows the flowchart of the whole process step at the time of a tablet taking-out unit performing a depackaging process. The figure which shows sectional drawing which shows the internal structure of a tablet extraction unit. The figure which shows the inclination figure which shows the internal structure of a tablet extraction unit. The figure which shows the example which a tablet sheet will be caught in the multifeed prevention part, when the tablet sheet is distorted. The figure which shows the example which a tablet sheet will be caught in the multifeed prevention part, when the tablet sheet is distorted. The figure which shows the flowchart for a tablet taking-out unit to detect the discharge mistake of a tablet sheet. The figure which shows the flowchart for the recovery from which the tablet extraction unit makes the discharge mistake of a tablet sheet.

Referring to FIG.
FIG. 1 is a diagram showing a packaging device 5 and a tablet supply device 10.
The tablet supply system includes a tablet supply device 10 and a packaging device 5 that wraps tablets supplied from the tablet supply device.
Reference numeral 1 denotes a tablet taking-out unit, which is a unit for taking out tablets from the tablet sheet 51.

A plurality of tablet take-out units are stored in the tablet supply device. Six tablet take-out units 1 are arranged in the width direction (left-right direction), and a set of the six tablet take-out units is arranged in three stages up and down. That is, the tablet taking-out units 1 are arranged in 6 rows on the left and right and 3 steps on the top and bottom.
Although the tablet supply apparatus 10 includes a plurality of tablet extraction units 1, the number of tablet extraction units may be one.
Reference numeral 5 denotes a packaging device, which is a device for packaging the tablets supplied from the tablet extraction unit of the tablet supply device.
Reference numeral 10 denotes a tablet supply device, which takes out and supplies tablets from a tablet sheet by a tablet extraction unit. The tablet supply device includes a plurality of tablet extraction units 1.
The tablet supply device 10 takes out and supplies tablets from a tablet sheet in which a plurality of tablets are enclosed in a tablet container.
The tablet supply device 10 includes one or a plurality of tablet extraction units and a supply unit that supplies tablets extracted by the tablet extraction unit.
FIG. 2 will be described.
FIG. 2 is a view showing a tablet supply device.
It is the figure which looked at the tablet supply apparatus from the front side.
Reference numeral 203 denotes a tablet sheet slot.
FIG. 3 will be described.
FIG. 3 is a view showing the internal structure of the tablet taking-out unit 10.
It is the figure which looked at the tablet extraction unit from the front side.

The tablet take-out unit 10 presses the second transport mechanism that transports the tablet sheet, the mounting table on which the tablet sheet transported by the second transport mechanism is mounted, and the tablet storage portion of the tablet sheet on the mounting table And an extrusion mechanism for taking out the tablets.
51 is a tablet sheet.

  The tablet sheet is obtained by sealing a tablet in the tablet housing portion by providing a sealing sheet using a metal foil made of aluminum or the like on the lower surface of a sheet main body having a tablet housing portion for housing the tablet. The tablet sheet has a form in which convex tablet accommodating parts are arranged in two rows at intervals in the width direction on the sheet part. The plurality of tablet accommodating portions forming each row are arranged along the length direction of the tablet sheet.

Note that the tablet sheet is not limited to the form in which the tablet accommodating portions are arranged in two rows on the sheet portion, but the form in which the tablet accommodating portions are arranged in one row in the length direction of the tablet sheet, A configuration in which three or more rows are arranged at intervals in the width direction is also possible.
FIG. 4 will be described.
FIG. 4 is a diagram showing an internal structure (cross section) of the tablet take-out unit.
It is a figure at the time of setting a sheet | seat to a tablet sheet insertion port, and conveying a PTP sheet to the unpacking position (tablet extraction position).

The tablet taking-out unit includes a tablet sheet carrying mechanism (second carrying mechanism) for carrying the tablet sheet, a mounting table 18 on which the tablet sheet is placed, and a tablet taking-out mechanism (extrusion mechanism) for taking out the tablet from the tablet sheet. I have.
Reference numeral 39 denotes a lower roller (second transport mechanism).

  The tablet sheet transport mechanism (second transport mechanism) transports the tablet sheet in the traveling direction, and is provided with a lower roller provided at a distance in the traveling direction and at a distance from each other in the traveling direction. And an upper roller provided.

The transport mechanism 39 further transports the tablet sheet by a predetermined distance from the pressed position on the mounting table before continuing to press the tablet storage unit, and the extrusion mechanism continues (retrys) pressing of the tablet storage unit. . (Tablet supply method)
The lower roller can be rotationally driven by a drive source, and can contact the lower surface of the sheet portion to apply a force to the advance method to the tablet sheet.
The upper roller can be rotationally driven by a drive source, and can contact the upper surface of the sheet portion to apply a force in the traveling direction to the tablet sheet.
Since the position of the upper roller in the width direction is a position corresponding to between the two rows of tablet accommodating portions, the upper roller does not contact the tablet accommodating portion 52.

The lower roller and the upper roller can sandwich the sheet portion from above and below to convey the tablet sheet in the traveling direction. Further, the lower roller and the upper roller can sandwich the sheet portion from above and below to transport the tablet sheet 51 in the direction opposite to the traveling direction.
Reference numeral 24 denotes an introduction chute.
The lead-out chute 24 guides the tablet dropped into the discharge port, has an upper opening having a size including the discharge port, and is provided on the lower surface side of the mounting table.
The tablet taking-out unit further has a changing mechanism for changing the speed at which the tablet accommodating portion of the tablet sheet on the mounting table is pressed.
The push-out mechanism continues (retrys) pressing of the tablet accommodating portion at a speed changed to a higher speed.
The extruding mechanism includes an inner pressing body 83 that presses the vicinity of the center of the tablet accommodating portion, and an outer pressing body 84 that presses a portion outside the vicinity of the center.
The inner pressing body and the outer pressing body operate independently to press the tablet container and take out the tablet.
The extruding mechanism presses the tablet housing portion with the outer pressing body before the inner pressing body.

  Reference numeral 83 denotes an inner pressing body. Since the tip of the inner pressing body has a smaller area than the tablet accommodating portion of most tablet sheets, the tip of the inner pressing body protrudes from a hole opened in the tablet sheet when taking out the tablet (when descending).

Reference numeral 84 denotes an outer pressing body. Since the tip of the outer pressing body has a larger area than the tablet accommodating portion of most tablet sheets, the tip does not protrude from the hole opened in the tablet sheet when the tablet is taken out (lowered). That is, it is for crushing the tablet accommodating part of a tablet sheet.
The tablet taking-out mechanism (extrusion mechanism) has a first lifting mechanism that lifts and lowers the outer pressing body and a second lifting mechanism that lifts and lowers the inner pressing body.

  The first elevating mechanism includes a first elevating body to which an outer pressing body is attached, a cam that is rotationally driven to raise and lower the first elevating body, and an urging member (spring) that urges the first elevating body in the upward direction. And.

  The first lifting body is a columnar body extending in the front-rear direction, and an outer pressing body is attached to the front end portion. The cam is a plate-like body designed in consideration of the lifting and lowering operation of the outer pressing body, and is fixed to a shaft portion that is rotationally driven by a drive mechanism (not shown). The cam is provided on the upper surface side of the first elevating body, is rotationally driven with the rotation of the shaft portion, adjusts the height position by pressing the first elevating body, and thereby the height position of the outer pressing body. Can be adjusted. The first elevating mechanism can arbitrarily set the elevating operation timing and displacement amount of the outer pressing body by setting the cam rotating operation timing, the cam shape, the cam fixing position with respect to the shaft portion, and the like.

  The second elevating mechanism includes a second elevating body to which the inner pressing body is attached, a cam that rotates and elevates the second elevating body, and a biasing member (spring) that urges the second elevating body in the upward direction. And.

  A 2nd raising / lowering body is a columnar body extended over the front-back direction, and the inner side press body is attached to the front-end part. The cam is provided on the upper surface side of the second elevating body, and is rotationally driven with the rotation of the shaft portion, and presses the second elevating body to adjust the height position, thereby adjusting the height position of the inner pressing body. Can be adjusted. The second elevating mechanism can arbitrarily set the elevating operation timing and the displacement amount of the inner pressing body by setting the timing of the cam rotating operation, the shape of the cam, the fixed position of the cam with respect to the shaft portion, and the like.

  Therefore, the cam 94 and the cam 99 can operate independently of each other with respect to the first lifting body and the second lifting body, and the inner pressing body and the outer pressing body can be lifted and lowered independently of each other.

The timing of the rotational operation of the two cams in the tablet take-out mechanism can be determined based on a signal from the detection unit of the tablet position detection mechanism. Specifically, the inner pressing body and the outer pressing body can be operated in accordance with the detected position of the tablet accommodating portion.
The tablet taking-out unit further includes a detection mechanism 17 that detects the length of the pressed tablet container before the tablet container is pressed.
The tablet supply device further includes a calculation unit that calculates a predetermined distance based on the detected length of the tablet container.
The detection mechanism 17 further detects the position of the pressed tablet container while detecting the length of the pressed tablet container.
The tablet supply device further includes a calculation unit that calculates a transport distance to the pressed position based on the detected position of the tablet container.
The transport mechanism 39 transports the tablet sheet to a position where the tablet storage unit on the mounting table is pressed by the transport distance.
The transport mechanism 39 transports the tablet sheet forward (advance) or backward (return) by a predetermined distance.
FIG. 5 will be described.
FIG. 5 is a diagram showing an internal structure of the tablet supply device.
It is the figure which looked at the tablet supply apparatus from the back side.

An optical sensor (beam sensor) 204 detects a fallen object. When the unwrapped tablet falls in the discharge hopper (introduction chute), the unwrapped tablet passes over the beam sensor and shields the beam sensor. The state where the beam sensor is shielded from light is referred to as an ON state, and the state where the beam sensor is not shielded is referred to as an OFF state. Using this ON / OFF state, a fallen object is determined.
The tablet falling detection mechanism includes an optical sensor and a falling tablet counter.
The tablet supply device has a second detection mechanism 204 that detects the extracted tablet in order to determine whether the tablet has been extracted from the tablet container by pressing.

The push-out mechanism continues (retrys) pressing of the tablet storage unit when the taken-out tablet is not detected, and does not continue (retry) press of the tablet storage unit when the taken-out tablet is detected.
401 is a tablet introduction path. The tablet taken out from the tablet sheet and dropped is relayed from the introduction chute 24 to the first accumulation hopper.
FIG. 6 will be described.
FIG. 6 is a view showing the internal structure of the tablet supply unit 400.
Reference numeral 402 denotes a first integrated hopper. The tablets taken out from the tablet sheet and dropped are collected.
Reference numeral 501 denotes a second integrated hopper. The tablets accumulated in the first accumulation hopper are further accumulated.
Reference numeral 502 denotes a first delivery mechanism. The tablets accumulated in the second accumulation hopper are moved to the third accumulation hopper.
Reference numeral 503 denotes a third integrated hopper. Accumulate the delivered tablets.
Reference numeral 504 denotes a second delivery mechanism. The tablets accumulated in the third accumulation hopper are moved to the main hopper.
Reference numeral 505 denotes a main hopper. The delivered tablets are accumulated and the accumulated tablets are put into a packaging sheet (wrapping paper).
FIG. 7 will be described.
FIG. 7 is a view showing the internal structure of the packaging unit 701.
Reference numeral 702 denotes a roll paper feed mechanism that feeds roll paper including a series of packaging sheets to the packaging mechanism.
703 encloses the tablet put in the packaging sheet in the packaging sheet by heat welding (packaging mechanism).
704 encloses the tablet put in the packaging sheet into the packaging sheet by heat welding (packaging mechanism).
705 forms the perforation for a division | segmentation for dividing the continuous roll paper into the packaging sheet for every package in a packaging sheet. (Severing mechanism)
A printer 706 prints date, patient data, and error information on a packaging sheet (printing mechanism).
FIG. 8 will be described.

  FIG. 8 is a diagram in which the block (outer pressing body) is operated after reaching the unpacking position during normal unpacking, and the aluminum foil of the PTP sheet is broken. The block is intended to break the aluminum foil and at this point the tablet cannot be removed.

  When the tablet sheet 51 reaches the mounting table and the tablet accommodating portion from which the tablets are to be taken out reaches a position corresponding to the discharge port, the cam of the first elevating mechanism is rotated by the rotation of the shaft portion, and the first elevating body is moved. By lowering, the outer pressing body is lowered, and the lower edge portion presses the portion outside the central portion of the tablet housing portion downward.

Since the outer pressing body presses a portion outside the central portion of the tablet accommodating portion, a direct force is not applied to the tablet as compared with the case where the central portion is pressed. For this reason, the tablet is not completely taken out, but a part of the tablet breaks the sealing sheet and comes out of the tablet container. In this state, since the tearing of the sealing sheet is slight, the tablet is supported by the sealing sheet, and a part of the tablet remains in the tablet accommodating portion. Further, the encapsulating sheet is not largely broken and no debris is generated.
FIG. 9 will be described.

  In FIG. 9, at the time of normal unpacking, the extrusion plate is operated to extrude the tablet so as to protrude. Even if a series of operations are performed, the tablet may be sandwiched between the aluminum foils of the PTP sheet, and the tablet may not be taken out.

  Next, the cam of the second elevating mechanism is rotated by the rotational drive of the shaft portion, and the inner pressing body is lowered by lowering the second elevating body, and the extending end portion lowers the central portion of the tablet accommodating portion. Press.

  Since the inner pressing body presses the central portion of the tablet accommodating portion, a direct force is applied to the tablet, and the tablet is completely removed. As a result, tearing of the sealing sheet is enlarged, but this tearing is caused by the tearing of a few minor points in the initial stage caused by the outer pressing body being widened by the inner pressing body, so there are few breakage points and sealing Sheet separation is unlikely to occur.

  On the other hand, when a large force is applied to the tablet accommodating portion at one time and the sealing sheet is torn, it is easy for tearing to occur at many locations on the sealing sheet at the same time, so that fragment separation is likely to occur.

Thus, since the tablet is partially removed from the tablet container by the first stage pressing by the outer pressing body, and then the tablet is completely removed from the tablet container by the second stage pressing by the inner pressing body, The pressing force applied to the tablet at each stage is small. For this reason, compared with the case where a big force is applied to a tablet accommodating part at once, a tablet is hard to break.
FIG. 10 will be described.
FIG. 10 is an enlarged view of FIG.
The tablet taking-out mechanism has a pressing portion and an elevating mechanism that moves the pressing portion in a direction approaching the tablet accommodating portion.

The pressing unit includes an inner pressing body (extruding plate) that presses the central portion of the tablet housing portion and an outer pressing body (extruding block) that presses a portion outside the central portion of the tablet housing portion.
The outer pressing body further includes a front wall portion, a rear wall portion provided in parallel to the front wall portion with a space behind the front wall portion, and an inner wall provided at an inner edge of the front wall portion and the rear wall portion. Part.
In other words, the outer pressing body has a front and rear wall portion which is a pair of facing wall portions facing each other, and an inner wall portion provided between one edge portion of these.

  Since the lower edge part of the outer pressing body is shaped so that the lower edge part of the front wall part and the rear wall part extend in the width direction from the front and rear ends of the lower edge part of the inner wall part, when the outer pressing body descends, Lower edges of the front and rear wall portions and the inner wall portion press the tablet housing portion.

The inner pressing body is a plate-like body having an extended end portion whose width becomes narrower toward the lower end, and is inserted into a space surrounded by the front wall portion, the rear wall portion, and the inner wall portion of the outer pressing body. Can move up and down within.
FIG. 11 will be described.

FIG. 11 shows a diagram of the vibration operation during retry (continuation) unpacking. If the aluminum foil is broken by a series of operations and the tablet cannot be removed even if the tablet is pushed out by the extrusion plate, the unpacking operation in FIG. 15 is changed at high speed (changing mechanism), and the PTP sheet is vibrated. give. By giving vibration, the vibration is transmitted to the tablet sandwiched between the aluminum foils, and the sandwiched state can be released.
FIG. 12 will be described.
FIG. 12 shows a flowchart of the unpacking operation and vibration operation during retry unpacking. The operation procedure is as follows.
During the unpacking operation, the input of the drop sensor 204 is constantly monitored, and if there is a change in the input, the drop counter value is updated. However, the value at the start of the unpacking operation is “0”.
In step S101, the rotation direction and rotation amount of the unpacking motor 2901 are set so that the extrusion unit descends to the PTP sheet.
In step S102, the unpacking motor 2901 is operated.
In step S103, the operating state of the unpacking motor 2901 is acquired.

  In step S104, it is checked whether the unpacking motor 2901 is stopped from the state of the unpacking motor 2901 acquired in S103, and the process of S103 is executed until the operation stops.

In step S105, during S101 to S104, if the number of times the drop sensor 204 is input in the tablet hopper is “1” or more, the process proceeds to S106, and otherwise, the process proceeds to S111.
In step S106, the rotation direction of the unpacking motor 2901 is set so that the extrusion unit moves up to the initial position.

In step S107, the unpacking motor 2901 is operated until the initial position sensor 280 that is the standby position of the extrusion unit is turned ON for the extrusion plate (inner pressing body) and the extrusion block (outer pressing body).
In step S108, the state of the initial position sensor 2801 is acquired.

In step S109, the state of the initial position sensor 2801 acquired in S108 is checked. If the initial position sensor 2801 is ON, the process proceeds to S110, and if it is OFF, the process proceeds to S108.
In step S110, the unpacking motor 2901 is stopped and the unpacking operation is terminated.

In step S111, the number of vibrations is checked. If the number is less than the set number of vibrations, the process proceeds to S112. Otherwise, the process proceeds to S106 in order to move the extrusion unit to the initial position.

In step S112, the rotation direction and rotation amount of the unpacking motor 2901 are set so that the extrusion unit descends. The rotation amount at this time is different from the rotation amount of S101 because of the vibration operation.
In step S113, the unpacking motor 2901 is operated until the extrusion unit moves to the set position.
In step S114, the same process as S103 is performed.

  In step S115, it is checked whether the unpacking motor is stopped from the state of the unpacking motor 2901 acquired in S114, and the process of S114 is continued until the operation is stopped.

  In step S116, similarly to S105, the number of inputs of the drop sensor 204 is set in the drop counter between S111 and S116. If “1” or more, the process proceeds to S106, and otherwise, the process proceeds to S117. .

In step S117, the rotation direction of the unpacking motor 2901 and processing are performed so that the extrusion unit moves up. Similar to S115, the set value differs from S106 because of the vibration operation.
In step S118, the unpacking motor 2901 is operated until the extrusion unit moves to the set position.
In step S119, the same process as S103 is performed.

  In step S120, it is checked whether the unpacking motor 2901 is stopped from the state of the unpacking motor acquired in S119, and the process of S119 is executed until the operation stops.

In step S121, as in step S105, the drop counter value is checked during execution of steps S105 to S116. If “1” or more, the process proceeds to step S106. Otherwise, the process proceeds to step S122.
In step S122, the vibration counter value is incremented by one.
FIG. 13 will be described.
FIG. 13 shows the movement of the tablet sheet at the unpacking position (position for taking out the tablet from the tablet container) during retry unpacking.

  If the package cannot be unpacked even after the vibration operation, the position of the tablet pocket to be unpacked is moved in the front-rear direction. By moving the unpacking position, the position where the tablet is pushed out changes, so that it is possible to take out the tablet that was sandwiched between aluminum foils and could not be taken out. However, if the unpacking is successful, the unpacking position is moved to the center of the PTP sheet pocket.

In 601 to 603, since the extrusion unit has pushed the tablet, the extrusion unit is caught by the PTP sheet as it is, and the tablet cannot be conveyed. Therefore, the extruding plate and the block of the extruding unit are arranged at the initial position so as not to contact the PTP sheet, and the unpacking position is moved.
Reference numeral 601 denotes a case where the tablet does not fall after the same operation as that in FIG.

  Reference numeral 601 denotes a state where the PTP sheet reaches the unpacking position and the tablet is taken out from the PTP sheet. When the tablet can be taken out by this operation, only the operation 601 is performed, and the operation proceeds to the operation of taking out the next tablet. If it cannot be removed by this operation (such as being sandwiched between aluminum foils), the operation proceeds to 602.

Reference numeral 602 denotes a state where the upper end of the pocket of the PTP sheet is being pressed. When the tablet cannot be taken out from the PTP sheet in 601, it is difficult to take out the tablet if it is sandwiched between aluminum foils or the like even if the same place is pushed again. In this case, by changing the extrusion position, it is possible to reduce resistance due to the pinching of the aluminum foil or the like, and it is possible to take out the tablet from the PTP sheet (tablet sheet).
If it cannot be taken out by this operation, the operation proceeds to operation 603.

Reference numeral 603 denotes a state where the lower end of the pocket of the PTP sheet is being pressed. If the tablet cannot be taken out from the PTP sheet even at 602, the resistance due to the pinching of the aluminum foil or the like can be reduced by changing the position to be pushed out again. Tablets can be pushed out by reducing this resistance.
Reference numeral 601 denotes a position where the first unpacking is performed after reaching the unpacking position.
Reference numeral 602 denotes a depackaging position where retry (re) unpacking of the odd-numbered unpacking operation is performed.
Reference numeral 603 denotes an unwrapping position at which retry (re) unpacking of the even number of unpacking operations is performed.
FIG. 14 will be described.

  FIG. 14 shows a flowchart when the tablet take-out unit 1 moves the tablet sheet to the unpacking position (position for taking out the tablet from the tablet container) during retry unpacking, and changes the push-out position.

In the first movement process of the unpacking position, the value of the transport counter is set so as to unpack the front side of the PTP sheet pocket from the center of the PTP sheet pocket (tablet accommodating portion). From the second time onward, a value that moves to the front / back side of the PTP sheet pocket is set in the conveyance counter. (* The value to be set here is the process of measuring the pocket size of the PTP sheet when transported to the unpacking position, and the measurement result is used.)
The front / back side of the PTP sheet pocket is determined based on the value of the retry counter, and when the unpacking is successful or the upper limit of the number of movements is exceeded, the value is set to “0”.

The number of retries described here represents the number of unpacking failures of the tablet that is currently performing the unpacking operation. During this movement, the extruding unit touches the tablet and does not hinder the transport of the tablet.

In step S201, the number of retries is checked, and if it is an odd number, the process proceeds to S202 in order to unpack the back side portion of the tablet sheet in the traveling direction (state 602 in FIG. 13). If it is an even number, the process proceeds to S210 in order to unpack the front side portion of the tablet sheet in the traveling direction (state 603 in FIG. 13).
In step S202, the distance for moving the tablet on the PTP sheet is set in the retry conveyance counter.
In step S203, the rotation direction of the transport motor is set so that the tablet sheet moves backward.
In step S204, the transport motor is operated to retract the tablet sheet. (State 602 in FIG. 13)
In step S205, the retry conveyance distance is decremented and the remaining conveyance distance is updated.
In step S206, the retry conveyance distance is checked, and if the designated distance movement is completed, the process proceeds to S207, and if not, the process proceeds to S204.
In step S207, the transport motor is stopped.
In step S208, the rotation direction of the transport motor is set to be the normal forward direction.
In step S209, the number of retries is incremented.
In step S210, the same process as S202 is performed.
In step S211, the conveyance motor is operated to advance the tablet sheet. (State 603 in FIG. 13)
In step S212, the same processing as in S205 is performed.
In step S213, the retry conveyance distance is checked, and if the designated distance movement is completed, the process proceeds to S214, and if not, the process proceeds to S211.
FIG. 15 will be described.
FIG. 15 is a flowchart showing the state of the unpacking operation during normal unpacking.
In step S501, it is checked whether the tablet has reached the unpacking position.
In step S502, the extrusion block 84 is operated.

In step S503, the aluminum foil is shattered using the force that pushes out the tablet by operating the extrusion block. Extruded blocks do not have the function of extruding tablets and exist only to break aluminum foil. If the aluminum foil is not torn before extruding the tablet, peeling of the aluminum foil and cracking or chipping of the tablet will remarkably appear. When trying to extrude a tablet from the PTP sheet in one operation, the aluminum foil on the back of the PTP sheet becomes resistance, and the operation of breaking the aluminum foil and the operation of extruding the tablet must be performed at the same time. Therefore, the above problems occur.
In step S504, the extrusion plate 83 is operated.

In step S505, the extrusion plate is operated to take out the tablet. Since the aluminum foil is broken in S503, the resistance to the tablet is reduced. Thereby, the cracking and chipping of the tablet can be prevented.
In step S506, the tablet sheet is conveyed to the unpacking position.
FIG. 16 is a diagram showing a position for detecting the tablet storage portion of the PTP sheet and a position for unpacking.

112 is arranged on the side surface through which 103 passes and the unevenness of the seat pocket is detected. By detecting this unevenness, the width dimension of the pocket can be determined. Based on the calculated value, the center position of the seat pocket is moved to 114.
Reference numeral 51 denotes a PTP sheet.
Reference numeral 17 denotes an optical sensor, which is used for measuring the length of the tablet container.
301 represents the detection position of the tablet (tablet storage part) by the optical sensor 17, and the length of the tablet storage part is measured when the tablet storage part passes (blocks).
Reference numeral 300 denotes an unpacking position (tablet taking-out position), which is a position for performing the unpacking operation for taking out the tablet.
FIG. 17 will be described.
FIG. 17 shows a flowchart for measuring the length of the tablet container using the optical sensor 17.

Here, the conveyance (movement) distance of the tablet sheet during normal unpacking and the conveyance (movement) distance of the tablet sheet during retry unpacking in steps S202 and S210 are calculated.
In step S301, the transport motor is advanced to transport the tablet sheet forward (advance).
In step S302, the state of the optical sensor 17 is acquired.

In step S303, it is determined from the acquired state of the optical sensor whether it is ON (the tablet container is shut off). If it is ON, the process proceeds to step S304. If it is not ON, the process proceeds to step S301.
In step S304, the position of the tablet container is detected. Start measuring the length of the tablet container.
In step S305, the conveyance motor is advanced to convey the tablet sheet forward (advance).
In step S306, the state of the optical sensor 17 is acquired.

  In step S307, it is determined from the acquired state of the optical sensor whether it is OFF (the tablet container is not shut off). If it is OFF, the process proceeds to step S308. If not OFF, the process proceeds to step S304.

In step S308, the measurement of the length of the tablet container is finished. Based on the position of the tablet container measured here, the conveyance (movement) distance of the tablet sheet from the detection position to the unpacking position is calculated.
Furthermore, based on the length of the tablet storage unit measured here, the transport distance (predetermined distance) of the tablet sheet at the time of retry (during continuation) is also calculated.
The travel distance of the tablet sheet at the time of retrying is calculated based on the result of the length of the tablet container so that the distal ends on the far side and the near side in the traveling direction are the unpacking positions.
The retry conveyance distance is the difference between the measured radius of the tablet sheet and the radius of the tip of the push plate. The tablet sheet is moved by a predetermined distance forward (forward) and backward (return) by the distance of the tablet sheet conveyance (movement) at the time of retry calculated based on the center of the tablet container.
FIG. 18 will be described.
When the PTP sheet passes through the interval sensor sensing unit 17, the size of the sheet pocket is measured by the sensor 17, and the PTP sheet is conveyed to the tablet removal position. FIG. 18 is a diagram showing a PTP sheet passage path of the interval sensor sensing unit 17 in the embodiment of the present invention.

By providing a fine groove 1002 (about 0.6 mm) in the passage path of the PTP sheet, it is pushed from the vertical direction and warpage is prevented during passage. Further, by providing the minute groove portion in the distance sensor sensing portion, the dimension of the sheet pocket can be measured in a state where the warp of the PTP sheet is prevented.
FIG. 19 will be described.
In addition, the front shown in FIG.19, FIG.20, FIG.21, FIG.22, FIG.23, FIG.25, FIG.26 means the direction (advance) which conveys a tablet sheet from an insertion port to an unpacking position, Means the reverse direction (return) in which the tablet sheet is conveyed from the insertion port to the unpacking position.
The left column shown in FIGS. 19, 20, 21, 22, 23, 25, and 26 is based on the direction in which the tablet sheet is conveyed from the insertion port to the unpacking position (advance). Means the left column in each tablet sheet row, and the right column shown in the figure indicates each tablet sheet when the tablet sheet is transported from the insertion port to the unpacking position (forward). It means the right column in the column.
FIG. 19 shows the order of the tablet pockets 52 in which the tablet take-out unit 1 performs the unpacking operation for each pack from the tablet sheet 51.

  Reference numeral 2701 denotes an arrow indicating the order of the unpacking operation. For example, when there is a request for taking out a total of 3 tablets, the take-out operation is sequentially performed from the back side in the sheet traveling direction. Unpacking operation on the left row side (1st tablet) → Unpacking operation on the right row side (2nd tablet) → Transport of tablet sheets to the next row → Unpacking operation on the left row side (3rd tablet) Take out the tablets.

In the unlikely event that the take-out operation fails in the middle, the take-out operation on the left side → the take-out operation on the right side → the transport to the next row → the eject operation on the left side → the eject operation on the right side → the transport to the next row → This operation is repeated until the predetermined number of three tablets are successfully taken out, that is, until the tablet sensor 204 detects a total of three tablets.
FIG. 20 will be described.
FIG. 20 shows the internal structure of the unpacking motor mechanism of the tablet taking-out unit 1.

Reference numeral 1111 denotes a shaft. Two cams 94, two cams 99, and a shielding plate 2802 are fixed to the shaft at a preset angle with respect to the rotation axis of the shaft.
When the rotation shaft is rotated by driving by the depacking motor, the two cams 94, the two cams 99, and the shielding plate 2802 fixed to the shaft are also rotated in conjunction with each other.

  Also, in order to share the initial position during left-row unpacking and right-row unpacking, the two cams 94 fixed at a preset angle are unwrapped at the midpoint of the angle formed with respect to the rotation axis. The initial position of operation is set. In other words, the left row cam is at an angle (for example, 45 °) that is equal to the reference angle (for example, 0 °) of the unpacking motor, which is the initial position of the unpacking operation, and the direction in which the unpacking motor 2901 rotates is exactly opposite. 94 and the right row cam 94 are fixed. Similarly, the left row cam 99 and the right row cam 99 are located at the same angle (eg, 135 °) from the reference angle (eg, 0 °) of the unpacking motor and in the opposite direction of rotation of the unpacking motor. Each is fixed.

  Reference numeral 2801 denotes an initial position sensor. This sensor is an optical sensor and detects ON / OFF depending on whether or not an object blocks light. When the input of the initial position sensor is ON, it is determined that the cam has reached the initial position.

  Only one initial position sensor is arranged for the tablet take-out unit 1 so that the initial position 350 at the time of unpacking the left row and the initial position 380 at the time of unpacking the right row are common. This is because the angle used as the reference for the unpacking motor is common when unpacking the left row and unpacking the right row.

  Since one initial position sensor 2801 can be used in common, it is only necessary to start rotation in different directions (forward or backward) at the time of left row unpacking and right row unpacking starting from this reference angle. It is possible to take out the tablets one by one on the left and right, and it is not necessary to manage the initial position separately for left row unpacking and right row unpacking, which makes it easy to control the unpacking operation. The effect of. Furthermore, since the mechanism of the expensive unpacking motor 2901 can be shared by using one initial position sensor 2801 in common, the manufacturing cost of the tablet dispensing unit 1 can be reduced.

  2802 is a light shielding plate for turning on / off the initial position sensor, and is fixed to the tip of the shaft 1111. When the light shielding plate blocks the light of the initial position sensor, the light is turned on (the shaft rotation angle is at the reference angle).

Reference numeral 2901 denotes a depacking motor. By rotating the unpacking motor, the shaft 1111 rotates in conjunction with each other, and the rotation angle of the block cam and the push-out plate cam fixed to the shaft 1111 can be controlled.
Reference numeral 2902 denotes a depacking motor pulley.

Reference numeral 2903 denotes a shaft pulley, which is connected to a depacking motor pulley by a belt. The shaft pulley and the rotating shaft (shaft) of the cam are also connected, and the rotation of the unpacking motor pulley, the rotation of the shaft pulley, and the rotation of the cam are all controlled by the rotation of the unpacking motor 2901.
FIG. 21 will be described.
When performing the unpacking operation in the left column (normal time), the unpacking operation is performed in the order of 350 → 360 → 370 → 360 → 350 as shown in FIG.
Reference numeral 350 denotes an initial position of the cam 94 when the left-side unpacking operation is performed.

  360 is the lowest point of the block 84 in the left row, the shaft 1111 rotates in the backward direction from the state of 350, the cam 94 presses the first lifting body 93, the block 84 is lowered, A state where the block 84 has reached the lowest point is shown. As the unpacking motor 2901 rotates, the cam 94 rotates, and the block 84 descends before the pushing plate 83. The block 84 breaks the aluminum foil in the pocket until the block 84 starts to descend and reaches the lowest point of the block 84.

  Reference numeral 370 denotes the lowermost point of the extrusion plate 83 in the left row. The shaft 1111 rotates in the reverse rotation direction from the state of 360, and the extrusion plate 83 descends when the cam 99 presses the second elevating body 98. And the state which the extrusion board 83 reached | attained the lowest point is shown. The push-out plate 83 pushes the pocket 52 to take out the tablet.

360 is the lowest point of the block 84, and the shaft 1111 is reversed in the forward direction from the state of 370, and the cam 94 presses the first elevating body 93, so that the block 84 is lowered and the block 84 is The state where the lowest point has been reached is shown.
Reference numeral 350 denotes the end position of the cam 94 when performing the left-side unpacking operation.

Here, when the initial position sensor 2801 is turned ON, it is determined that the state has returned to the state 350 (initial position) and the rotation of the unpacking motor 2901 is stopped, so that the push-out plate cam 99 and the block cam 94 are rotated. Stop.
FIG. 22 will be described.
When performing the unpacking operation (normal time) in the right column, the unpacking operation is performed in the order of 380 → 390 → 400 → 390 → 380 as shown in FIG.
Reference numeral 380 denotes an initial position of the cam 94 when performing the right row unpacking operation.

  390 is the lowest point of the block 84 in the right row, the shaft 1111 rotates in the forward rotation direction from the state of 380, the cam 94 presses the first lifting body 93, the block 84 is lowered, A state where the block 84 has reached the lowest point is shown.

  Reference numeral 400 denotes the lowermost point of the extrusion plate 83 in the right row, and the shaft 1111 rotates in the forward rotation direction from the state of 390, and the extrusion plate 83 is lowered by the cam 99 pressing the second elevating body 98. And the state which the extrusion board 83 reached | attained the lowest point is shown.

390 is the lowest point of the block 84. The shaft 1111 is reversed in the reverse direction from the state of 400, and the cam 94 presses the first elevating body 93, so that the block 84 is lowered and the block 84 is The state where the lowest point has been reached is shown.
Reference numeral 380 denotes the end position of the cam 94 when performing the right-side unpacking operation.

Here, when the initial position sensor 2801 is turned ON, it is determined that the state has returned to the state 380 (initial position), and the rotation of the unpacking motor 2901 is stopped, so that the push-out plate cam 99 and the block cam 94 are rotated. Stop.
FIG. 23 will be described.

  When performing the unpacking operation (at the time of retry) in the left column, if the vibration is set to 3 times as shown in FIG. 23, 350 → 360 → 370 → 360 → 370 → 360 → 370 → 360 It operates in the order of → 370 → 360 → 350, and the vibrations in the block and the extrusion plate are repeated a set number of times.

  Similarly, when performing the unpacking operation (at the time of retry) in the right column, if the vibration is set to 3 times, 380 → 390 → 400 → 390 → 400 → 390 → 400 → 390 → 400 → 390 → Operates in the order of 380, and repeats the vibration of the block and the extrusion plate a set number of times.

In this way, 360 → 370 is repeated a set number of times (for example, 3 times) during the unpacking operation at the time of retry in the left column, but the cam is rotated at a higher angle at a shorter angle than the unpacking operation at the normal time. At this time, since the block and the pushing plate are alternately pressed at a high speed, vibration is applied to the PTP sheet 51, and it is possible to promote the dropping of the tablet caught on the aluminum foil. This operation is a vibration operation.
FIG. 24 will be described.
FIG. 24 shows the entire processing steps when the tablet taking-out unit 1 performs the depackaging process.

In S601, the tablet supply device 10 or the medicine packaging device 5 manages the count update data of the total number of tablets detected for each tablet extraction unit 1 by the optical sensor 204 in the storage unit, so that the tablet supply device 10 or the medicine packaging device 5 has a predetermined number (tablet extraction). It is determined whether or not the unpacking operation of the number of tablets designated in unit 1 is completed. If it is determined that the process has not been completed, the process proceeds to S602. If it is determined that the process has been completed, the depackaging process is terminated, and the PTP sheet is discharged to the discharge unit.

In S602, the processing steps when the tablet take-out unit 1 conveys the PTP sheet by one row of the tablet pocket intervals calculated in S308 of FIG. 17 to the unpacking position 300 in order to move forward simultaneously to the left row and the right row. It is.

In S603, it is a processing step when the tablet taking-out unit 1 performs the left row unpacking operation (normal time). This operation is always performed to take out each tablet from the PTP sheet. Since the unpacking operation as described in FIG. 21 is executed, it is defined as normal unpacking. Detailed hardware control in this processing step will be described with reference to the flowchart of FIG. After the depackaging operation according to the flowchart of FIG. 15, the process proceeds to S604.

In S604, the tablet supply device 10 or the medicine packaging device 5 determines whether the optical sensor 204 has detected (successfully taken out) one tablet based on the result of S603. When it is determined that the tablet 50 has been successfully taken out from the tablet pocket 52 within a predetermined time, the count update data for managing the total number of tablets taken out in the tablet take-out unit 1 is incremented by one, and the process goes to S608. move on. If it is determined that the extraction is not successful within the predetermined time, the process proceeds to S605.

In S605, it is a processing step when the tablet taking-out unit 1 performs the left row unpacking operation (at the time of retry). This operation is performed when the tablet 50 is not successfully taken out even after the normal unpacking operation described with reference to FIG. Since the unpacking operation at the time of retry described in FIG. 23 is executed again at the unpacking position, it is defined as retry unpacking. Detailed hardware control in this processing step will be described in S111 to S122 of the flowchart of FIG. After retry depackaging according to S111 to S122 in the flowchart of FIG. 15, the process proceeds to S606.

In S606, the tablet supply device 10 or the medicine packaging device 5 determines whether the optical sensor 204 has detected (successfully taken out) one tablet based on the result of S605. When it is determined that the tablet 50 has been successfully taken out from the tablet pocket 52 within a predetermined time, the count update data for managing the total number of tablets taken out in the tablet take-out unit 1 is incremented by one, and the process goes to S608. move on. If it is determined that the extraction is not successful within the predetermined time, the process proceeds to S607.

In S607, it is a processing step when the tablet taking-out unit 1 changes the push-out position. This operation is performed when the tablet 50 is not successfully taken out even if the vibration operation at the time of retry described in FIG. 23 is performed a specified number of times. Since the unpacking operation at the time of retry described with reference to FIG. 23 is performed again after the PTP sheet 51 is moved to a different unpacking position, it is defined as retry conveyance. Detailed hardware control in this processing step will be described with reference to the flowchart of FIG. After the PTP sheet 51 is transported and moved to a different unpacking position (forward or backward) according to the flowchart of FIG. 14, the process proceeds to S605.

In S608, the tablet supply device 10 or the medicine packaging device 5 manages the count update data of the total number of tablets detected by the optical sensor 204 for each tablet extraction unit 1 in the storage unit. It is determined whether or not the unpacking operation is completed in comparison with the number of tablets designated in unit 1). If it is determined that the process has not been completed, the process proceeds to S609. If it is determined that the process has been completed, the depackaging process is terminated, and the PTP sheet is discharged to the discharge unit.

In S609, it is a processing step when the tablet taking-out unit 1 performs the right row unpacking operation (normal time). This operation is always performed to take out each tablet from the PTP sheet. Since the unpacking operation as described in FIG. 22 is executed, it is defined as normal unpacking. Detailed hardware control in this processing step will be described with reference to the flowchart of FIG. After the unpacking operation according to the flowchart of FIG. 15, the process proceeds to S610.

In S610, the tablet supply device 10 or the medicine packaging device 5 determines whether or not the optical sensor 204 has detected (successfully extracted) one tablet based on the result of S609. If it is determined that the tablet 50 has been successfully taken out from the tablet pocket 52 within a predetermined time, the count update data for managing the total number of tablets taken out by the tablet take-out unit 1 is incremented by one, and the process goes to S601. move on. If it is determined that the extraction is not successful within the predetermined time, the process proceeds to S611.

In S611, it is a processing step when the tablet taking-out unit 1 performs the right row unpacking operation (at the time of retry). This operation is performed when the tablet 50 is not successfully taken out even after the normal unpacking operation. Since the unpacking operation at the time of retry is performed again at the unpacking position, it is defined as retry unpacking. Detailed hardware control in this processing step will be described in S111 to S122 of the flowchart of FIG. After retry depackaging according to S111 to S122 in the flowchart of FIG. 15, the process proceeds to S612.

In S612, the tablet supply device 10 or the medicine packaging device 5 determines whether the optical sensor 204 has detected (successfully extracted) one tablet based on the result of S611. If it is determined that the tablet 50 has been successfully taken out from the tablet pocket 52 within a predetermined time, the count update data for managing the total number of tablets taken out by the tablet take-out unit 1 is incremented by one, and the process goes to S601. move on. If it is determined that the extraction is not successful within the predetermined time, the process proceeds to S613.

In S613, it is a processing step when the tablet taking-out unit 1 changes the push-out position. This operation is performed when the tablet 50 is not successfully taken out even if the vibration operation at the time of retry described in FIG. 23 is performed a specified number of times. Since the unpacking operation at the time of retry described with reference to FIG. 23 is performed again after the PTP sheet 51 is moved to a different unpacking position, it is defined as retry conveyance. Detailed hardware control in this processing step will be described with reference to the flowchart of FIG. After the PTP sheet 51 is transported to a different unpacking position (forward or backward) according to the flowchart of FIG. 14, the process proceeds to S611.
FIG. 25 will be described.
FIG. 25 is a cross-sectional view showing the internal structure of the tablet dispensing unit 1. The conveyance of the tablet sheet 51 will be described.

Reference numeral 1501 denotes a lower roller (first transport mechanism) that transports the tablet sheets 51 placed on the input port 203 one by one. The tablet sheet 51 is fed forward from the loading port (sheet loading position), which is the back side of the multifeed prevention unit 1502, by the frictional force generated by rotating the lower roller.

Reference numeral 39 denotes a lower roller (second transport mechanism) that transports the tablet sheet 51 that has passed through the gap of the multifeed prevention unit 1502 to the unpacking position by the frictional force that rotates the lower roller.

Reference numeral 17 denotes an optical sensor (first detection mechanism) that detects the arrival of the tablet sheet 51 discharged from the gap at a position farther from the double feed prevention unit 1502. That is, since the presence or absence of the tablet storage unit is detected at a position (detection position) farther from the double feed prevention unit 1502, the success or failure of the arrival of one tablet sheet discharged from the gap is detected. Can do.
The PTP sheet from which all the pockets have been unpacked at the unpacking position is accumulated in the PTP sheet collection box that is connected to the discharge path through the PTP sheet discharge path.
FIG. 26 will be described.
FIG. 26 is an inclined view showing the internal structure of the tablet taking-out unit 1.
Reference numeral 1401 denotes a double feed prevention plate, which is a plate for blocking the upper part of the stacked PTP sheets from being conveyed to the back side (front) of the double feed prevention unit 1502.
FIG. 27 will be described.
Next, an example in which the tablet sheet 51 is caught by the double feed prevention unit 1502 will be described with reference to FIGS. 27 and 28.

The double feed prevention unit 1502 is provided at an insertion port into which a tablet sheet is inserted, and passes only one tablet sheet through the gap in order to transport only one tablet sheet to be transported to the unpacking position. It is to be transported.
The arrow of the conveyance roller 1501 indicates the rotation direction for conveying the tablet sheet 51 forward, which is the back side of the multifeed prevention unit 1502.

  The double feed prevention unit 1502 is a device for narrowing the gap with the conveyance path so that the plurality of tablet sheets 51 are not conveyed simultaneously. Between the lower part of the double feed prevention unit and the sheet conveyance path, a gap is formed at a height at which the tablet sheets should be discharged for each sheet in order to prevent a plurality of sheets from being fed out from the input port. .

  Further, a space is formed between the left and right sides of the double feed prevention unit and the sheet conveyance path so that the tablet storage units (two rows) can pass through the double feed prevention unit for each sheet. The double feed prevention unit is disposed at a position intermediate between the tablet storage units (two rows) passing therethrough.

The tablet sheets 51 set in the insertion port 203 are on the lower roller 1501 and are conveyed one by one in the direction of the double feed prevention unit 1502 when the roller 1501 is rotated. At that time, especially when the ears of the tablet sheet 51 are distorted or the ears are lifted, the head of the warped sheet collides with the multi-feed prevention unit 1502, so that even if the lower roller 1501 continues the sheet conveyance. Since the frictional force (grip force) is reduced and the lower roller starts to slide on the tablet sheet conveyance surface, the force of moving forward in the direction of the double feed prevention unit 1502 is also weakened and cannot pass through the gap well.
FIG. 29 will be described.
FIG. 29 is a flowchart for detecting a tablet sheet discharge error from the input port 203 using the optical sensor 17.

The processing of each step in the flowchart shown in FIG. 29 is executed by the CPU of the tablet supply device 10. FIG. 29 is executed when the tablet supply device 10 receives a tablet take-out operation start command from the packaging device 5. When the tablet supply device receives the tablet take-out operation command from the packaging device, the tablet supply device stores the setting data included in the tablet take-out operation command in the memory, and the designated tablet take-out unit 1 starts the sheet conveying operation.
In step S2901, the tablet supply device 10 measures the width of the PTP sheet set at the insertion port by a PTP sheet width detection sensor (not shown).

  Here, it is determined whether or not the PTP sheet is set in the insertion slot according to the measurement result by the PTP sheet width detection sensor. If it is determined that the PTP sheet is set in the insertion slot, the process proceeds to S2902, where the PTP sheet set in the insertion slot is rotated in the direction of the position where the tablet is taken out (rotation position direction). ), Only the lowest PTP sheet set at the insertion port is conveyed, so that the upper PTP sheets stacked and set at the insertion port sequentially fall below the insertion port.

  As described above, since the PTP sheet width is measured by the PTP sheet width detection sensor every time one sheet is conveyed, has the PTP sheet falling below the loading port been detected for each sheet conveyed? By determining whether or not, it is also possible to determine whether the PTP sheet conveyed in S2902 is the last PTP sheet remaining in the insertion slot among the plurality of PTP sheets set in the insertion slot.

In step S2902, the tablet supply device 10 rotates the lower roller 1501 to start sheet conveyance so that only one tablet sheet placed at the lowest position of the insertion port advances in the direction of the double feed prevention unit. To do.
In step S <b> 2903, the tablet supply device 10 detects a pocket (tablet storage unit) by the pocket position sensor 17.

  In step S2904, the tablet supply device 10 determines whether or not a pocket has been detected until a sufficient time has elapsed until one tablet sheet reaches the pocket position sensor 17 (within a predetermined time). Here, a sufficient time for the sheet to reach from the slot 203 to the pocket position sensor 17 is set in advance and stored in the memory (storage unit).

  If it is determined in S2904 that a pocket cannot be detected (No), the process proceeds to S2906. If it is determined in S2904 that a pocket has been detected (Yes), the process proceeds to S2905.

  If it is determined in step S2905 that the pocket has been detected (YES), the tablet supply device 10 performs a predetermined distance (distance to the unpacking position) from the pocket position detected by the pocket position sensor 17. By rotating 39, the PTP sheet is further conveyed in the direction of the position for taking out the tablet (the direction of the unpacking position). Thereafter, the process proceeds to the flowchart of the unpacking operation described with reference to FIG.

  In step S2906, the tablet supply apparatus 10 determines that the lowest PTP sheet to be conveyed is not normally conveyed by being blocked by the multifeed prevention unit, and temporarily waits as an error state of sheet conveyance. Therefore, the sheet conveyance due to the rotation of the lower roller 1501 is stopped.

In step S2907, the tablet supply device 10 determines whether or not a restart instruction (restart instruction) has been received. If it is determined that the restart instruction has been received (YES), the process returns to S2902 to resume sheet conveyance. To do.
FIG. 30 will be described.
FIG. 30 shows a flowchart for recovery to make a mistake in discharging the tablet sheet from the insertion port 203 using the optical sensor 17.

Processing of each step of the flowchart shown in FIG. 30 is executed by the CPU of the tablet supply device 10. FIG. 30 is executed when the tablet supply device 10 receives a tablet take-out operation start command from the packaging device 5. When the tablet supply device receives the tablet take-out operation command from the packaging device, the tablet supply device stores the setting data included in the tablet take-out operation command in the memory, and the designated tablet take-out unit 1 starts the sheet conveying operation.
In step S3001, the tablet supply device 10 measures the width of the PTP sheet set in the insertion port by a PTP sheet width detection sensor (not shown).

  Here, it is determined whether or not the PTP sheet is set in the insertion slot according to the measurement result by the PTP sheet width detection sensor. If it is determined that the PTP sheet is set in the insertion slot, the process proceeds to S3002, and the direction of the position where the tablet is taken out by rotating the roller 1501 of the PTP sheet set in the insertion slot (unpacking position direction). ), Only the lowest PTP sheet set at the insertion port is conveyed, so that the upper PTP sheets stacked and set at the insertion port sequentially fall below the insertion port.

  As described above, since the PTP sheet width is measured by the PTP sheet width detection sensor every time one sheet is conveyed, has the PTP sheet falling below the loading port been detected for each sheet conveyed? By determining whether or not, it is possible to determine whether the PTP sheet conveyed in S3002 is the last PTP sheet remaining in the insertion slot among the plurality of PTP sheets set in the insertion slot.

In step S3002, the tablet supply device 10 rotates the lower roller 1501 to start sheet conveyance so that only one tablet sheet placed at the lowest position of the insertion port advances in the direction of the double feed prevention unit. To do.
In step S <b> 3003, the tablet supply device 10 detects a pocket (tablet container) by the pocket position sensor 17.

  In step S3004, the tablet supply apparatus 10 determines whether or not a pocket has been detected until a sufficient time has elapsed until one tablet sheet reaches the pocket position sensor 17 (within a predetermined time). Here, a sufficient time for the sheet to reach from the slot 203 to the pocket position sensor 17 is set in advance and stored in the memory (storage unit).

  If it is determined in S3004 that a pocket cannot be detected (No), the process proceeds to S3006. If it is determined in S3004 that a pocket has been detected (Yes), the process proceeds to S3005.

  In step S3005, the tablet supply device 10 detects that the optical sensor 17 has arrived within a predetermined time after the start of sheet conveyance (success), whereas the lower roller 1501 is placed on the input port 203. The lower roller 1501 is controlled so that the transport to the back side position of the tablet sheet that has passed through the gap is completed by continuing the transport to the back side position of the double feed prevention unit (transport control means). ).

If it is determined that a pocket has been detected (YES), the roller 39 is rotated by a predetermined distance (distance to the unpacking position) from the pocket position detected by the pocket position sensor 17 to rotate the PTP sheet. It is further conveyed in the direction of the position for taking out the tablet (in the direction of unpacking position). Thereafter, the process proceeds to the flowchart of the unpacking operation described with reference to FIG.
In step S3006, the tablet supply device 10 determines whether the number of conveyance retries has reached a specified number in order to repeat the retry conveyance operation a predetermined number of times.

  If it is determined that the number of conveyance retries stored in the memory has reached the specified number (No), the process proceeds to S3009. If it is determined that the number of conveyance retries has not reached the specified number (Yes), the process proceeds to S3007.

  In step S3007, when the optical sensor 17 cannot detect the arrival within a predetermined time after the start of sheet conveyance (failure), the tablet supply device 10 waits for the lower roller 1501 to temporarily stop sheet conveyance, and then step S3007. Returning to S3002, the lower roller 1501 is controlled to automatically resume (start conveyance) (conveyance control means).

  That is, if it is determined that the number of conveyance retries stored in the memory is less than a predetermined number (for example, five times) (YES), the sheet conveyance is temporarily stopped here, and the process returns to S3002 to resume the sheet conveyance. . At this time, the conveyance is temporarily stopped. In general, the frictional force is greater on the contact surface than on the dynamic friction force, so that the friction coefficient acting on the contact surface between the lower roller 1501 and the PTP sheet 51 is forcibly temporarily stopped. Can be recovered and the possibility of successful transport of the PTP sheet can be increased.

  In step S3008, the tablet supply apparatus 10 returns to step S3002 and changes the physical position of the tablet sheet temporarily stopped on the lower roller 1501 before controlling the lower roller 1501 to resume automatically by the conveyance control means. For this purpose, a weak vibration is applied to the tablet sheet 51 on which the sheet conveyance by the lower roller 1501 has been temporarily stopped (vibration means).

  After the temporary stop, by applying vibration to the PTP sheet, the balance of the overlap of the PTP sheets stacked on the sheet insertion port can be broken. By resuming the conveyance of the PTP sheet after the balance is lost and the physical position is changed, there is an increased possibility that the PTP sheet that has been hooked up to now can successfully pass through the gap.

As a specific means for giving a weak vibration to the PTP sheet, first, a stepping motor that rotates the lower roller 1501 in sheet conveyance is used in a micro (micro) step mode.
Next, after the motor rotation is temporarily stopped, the current supply to the stepping motor is further interrupted, and the current supply may be resumed before the motor starts rotating.

  First, when the stepping motor is used in the micro step mode, the rotation angle that moves in one step is smaller than the rotation angle in the normal step mode, so that the motor can be rotated smoothly (in small increments).

  For example, in the normal step mode, the stepping motor makes one rotation in 200 steps, and in the micro step mode, it makes one rotation in 800 steps.

  When using the micro step mode, the stepping motor will not be able to stop in the normal step mode when the current stop position is different (different) when resuming the current supply to the motor. It has the property of automatically returning to the point where it should stop in the nearest normal step mode.

That is, even if the power supply for driving the lower roller 1501 is stopped once and then re-supplied, the position at which the lower roller 1501 resumes conveyance changes, so the position of the tablet sheet to be paused can be varied, The same effect as a minute vibration can be obtained.
Even if such an operation property of the stepping motor is utilized, minute vibrations can be applied to the PTP sheet.

  This can be implemented by cutting off the current supply to the stepping motor after the sheet conveyance operation is temporarily stopped and supplying the current to the stepping motor when the sheet conveyance is resumed.

In addition, the position of the tablet sheet to be paused can be changed only by reversely conveying the tablet sheet to which the lower roller 1501 pauses at least in the direction opposite to the sheet conveying direction. You can get an effect.
As another method for applying minute vibrations to the PTP sheet, the lower roller 1501 may repeat forward and reverse rotations (opposite directions) by a predetermined distance.

  In step S3009, the tablet supply device 10 gives up the sheet conveyance after repeating the control to the lower roller 1501 such that the sheet conveyance by the lower roller 1501 is temporarily stopped and then resumed automatically a predetermined number of times (five times). Stop completely (error stop means).

  That is, the lowermost PTP sheet to be conveyed is blocked by the multifeed prevention unit, so that it is determined that the sheet cannot be conveyed normally, and the lower roller 1501 is used to temporarily wait as a sheet conveyance error state. Completely stops the sheet conveyance.

  In step S3010, the tablet supply device 10 determines whether or not a restart instruction (restart instruction) has been received by a user operation. If it is determined that the restart instruction has been received (YES), the process proceeds to S3002. Return and resume sheet conveyance.

  Each means and each step constituting the embodiment of the present invention described above can be realized by operating a program stored in a RAM, a ROM, or the like of a computer. This program that can be read and executed by the apparatus (or unit) and a computer-readable recording medium that records the program are included in the present invention.

  In addition, the present invention can be implemented as, for example, a system, apparatus, method, program, or recording medium, and may be applied to an apparatus including one or more devices.

  The present invention supplies a software program for realizing the functions of the above-described embodiments directly or remotely to a system or apparatus. And the case where it is achieved also by reading and executing the supplied program code by the computer of the system or apparatus is included.

  Therefore, since the functions of the present invention are implemented by computer, the program code installed in the computer also implements the present invention. In other words, the present invention includes a computer program itself for realizing the functional processing of the present invention. In that case, as long as it has the function of a program, it may be in the form of object code, a program executed by an interpreter, script data supplied to the OS, or the like.

  Further, the functions of the above-described embodiments are realized by the computer executing the read program. Furthermore, based on the instructions of the program, an OS or the like running on the computer performs part or all of the actual processing, and the functions of the above-described embodiments can be realized by the processing.

  As another method, a program read from a recording medium is first written in a memory provided in a function expansion board inserted into the computer or a function expansion unit connected to the computer. Then, based on the instructions of the program, the CPU or the like provided in the function expansion board or function expansion unit performs part or all of the actual processing, and the functions of the above-described embodiments are also realized by the processing.

1 Tablet removal unit (tablet sheet transport unit)
5 Drug packaging device 10 Tablet supply device 17 Tablet sheet detection mechanism (first detection mechanism)
18 Mounting table 50 Tablet 51 Tablet sheet (PTP sheet)
52 Tablet storage (sheet pocket)
55 Sealing sheet (aluminum foil)
83 Inside pressing body (extrusion plate)
84 Outer pressing body (block)
98 Second lifting body (for extruded plate)
93 1st lifting body (for block)
99 cam (for extruded plate)
94 Cam (for block)
39 Tablet sheet transport mechanism (second transport mechanism)
24 Introduction chute (hopper)
203 Tablet sheet inlet 204 Tablet detection mechanism (second detection mechanism)
300 Unpacking position 301 Detection position 400 Tablet supply unit 701 Packaging unit 1501 Tablet sheet transport mechanism (first transport mechanism)
1502 Double feed prevention unit

Claims (12)

A transport mechanism for transporting the tablet sheet to a tablet take-out position for taking out the tablets of the tablet sheet from the input section on which a plurality of tablet sheets can be placed; and
A double feed prevention unit positioned with a gap through which one tablet sheet can pass with respect to the tablet sheet holding surface located on the lower side in the gravity direction of the tablet sheet conveyed by the conveying mechanism;
A detection mechanism for detecting the passage of the tablet sheet, provided on the downstream side in the conveyance direction of the tablet sheet from the multi-feed prevention unit;
Control means for controlling the transport mechanism so as to resume after stopping the transport operation for a predetermined time when the detection mechanism cannot detect the passage of the tablet sheet after starting the transport operation;
A tablet sheet conveying unit comprising: The tablet sheet transport unit according to claim 1, wherein the control unit controls the tablet operation to vibrate the tablet sheet to be transported by the transport mechanism during the stop period. The transport mechanism is a stepping motor;
The tablet sheet transport unit according to claim 2, wherein the control means controls the tablet sheet to be transported by the transport mechanism to vibrate when the current supply to the stepping motor is interrupted and restarted. Said control means, said a transport to the transport direction, the tablet sheet to be conveyed by the conveying mechanism by causing the transport of the conveying direction and the reverse direction is controlled to vibrate the transport mechanism The tablet sheet conveyance unit according to claim 2.   The control means controls to stop the transport operation when the detection mechanism fails to detect the passage of the tablet sheet even if the transport operation is stopped and restarted a predetermined number of times. The tablet sheet conveyance unit according to any one of claims 1 to 4. The tablet sheet has a plurality of tablet storage portions for storing tablets and a sealing seal for sealing the plurality of tablet storage portions,
The tablet sheet conveyance unit according to any one of claims 1 to 5, wherein a tablet sheet is loaded into the loading unit in a state where the sealing seal is in a gravity direction lower side.   The said control means is controlled so that a tablet sheet may be conveyed to the said extraction position, when passage of a tablet sheet is detected by the said detection mechanism. The tablet sheet conveyance unit according to 1. A transport mechanism for performing a transport operation for transporting the tablet sheet to a tablet take-out position where a tablet of the tablet sheet is taken out from an input section on which a plurality of tablet sheets can be placed, and the gravity direction of the tablet sheet transported by the transport mechanism Provided on the lower side of the tablet sheet holding surface with a gap through which one tablet sheet can pass, and provided on the downstream side in the tablet sheet conveyance direction with respect to the double feed prevention unit. A detection mechanism for detecting the passage of the tablet sheet, and a control method of the tablet sheet transport unit having:
A control step of controlling the transport mechanism so that the transport operation is stopped after a predetermined time and restarted when the detection mechanism cannot detect the passage of the tablet sheet after the transport operation is started; Control method to do. A transport mechanism for performing a transport operation for transporting the tablet sheet to a tablet take-out position where a tablet of the tablet sheet is taken out from an input section on which a plurality of tablet sheets can be placed, and the gravity direction of the tablet sheet transported by the transport mechanism Provided on the lower side of the tablet sheet holding surface with a gap through which one tablet sheet can pass, and provided on the downstream side in the tablet sheet conveyance direction with respect to the double feed prevention unit. A detection mechanism for detecting passage of a tablet sheet, and a tablet sheet transport unit having a reading and execution program,
The tablet sheet transport unit;
When the passage of the tablet sheet cannot be detected by the detection mechanism after the start of the transport operation, the transport mechanism is made to function as a control unit that controls the transport mechanism to resume after stopping for a predetermined time. Program. A transport mechanism for performing a transport operation for transporting the tablet sheet to a tablet take-out position where the tablet is taken out from an input portion on which a plurality of tablet sheets can be placed;
A double feed prevention unit positioned with a gap through which one tablet sheet can pass with respect to the tablet sheet holding surface located on the lower side in the gravity direction of the tablet sheet conveyed by the conveying mechanism;
A detection mechanism that is provided on the downstream side in the conveyance direction of the tablet sheet from the multifeed prevention unit, and detects the passage of the tablet sheet;
After starting the conveyance operation, if it can not detect the passage of the tablet sheet to be conveyed by the conveying mechanism by the detection mechanism, attempts conveyed by the conveying mechanism at said double feed preventing conveyance direction upstream side than the portion Control means for controlling the tablet sheet to vibrate;
A tablet sheet conveying unit comprising: A transport mechanism for performing a transport operation for transporting the tablet sheet to a tablet take-out position for taking out the tablets from a loading section on which a plurality of tablet sheets can be placed, and a lower side in the gravity direction of the tablet sheet transported by the transport mechanism A double feed prevention unit positioned with a gap through which one tablet sheet can pass with respect to the tablet sheet holding surface located; and provided on the downstream side in the conveyance direction of the tablet sheet from the double feed prevention unit, A detection mechanism for detecting the passage of a tablet sheet, and a control method of a tablet sheet transport unit having:
After starting the conveyance operation, if it can not detect the passage of the tablet sheet to be conveyed by the conveying mechanism by the detection mechanism, attempts conveyed by the conveying mechanism at said double feed preventing conveyance direction upstream side than the portion A control method comprising a control step of controlling the tablet sheet to vibrate. A transport mechanism for performing a transport operation for transporting the tablet sheet to a tablet take-out position for taking out the tablets from a loading section on which a plurality of tablet sheets can be placed, and a lower side in the gravity direction of the tablet sheet transported by the transport mechanism A double feed prevention unit positioned with a gap through which one tablet sheet can pass with respect to the tablet sheet holding surface located; and provided on the downstream side in the conveyance direction of the tablet sheet from the double feed prevention unit, A detection mechanism for detecting passage of a tablet sheet, and a tablet sheet transport unit having a program that can be read and executed,
The tablet sheet transport unit;
After starting the conveyance operation, if it can not detect the passage of the tablet sheet to be conveyed by the conveying mechanism by the detection mechanism, attempts conveyed by the conveying mechanism at said double feed preventing conveyance direction upstream side than the portion A program that functions as control means for controlling a tablet sheet to vibrate.

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