JP7538924B2 - Tablet Printing Equipment - Google Patents

Description

The present invention relates to a tablet printing device that performs printing processes on tablets.

Traditionally, pharmaceutical tablets often have a code printed on them to identify the drug. Typically, the identification code printed on the tablet is, for example, a company code representing the manufacturer or a product code to distinguish the product. Such identification codes are primarily used for dispensing at medical institutions and pharmacies. Also, to prevent accidentally ingesting a tablet (for example, preventing an antihypertensive drug from being ingested instead of a vasopressor), a label that can be clearly recognized by the patient may be attached to the tablet. Furthermore, there is also a demand to assign a number to tablets for the purpose of pharmaceutical traceability.

Although such identification codes are sometimes engraved on the surface of tablets, there is an increasing need to print directly on tablets due to issues with visibility. Patent documents 1 and 2 propose printing technology on tablets using an inkjet printer.

Patent Document 1 discloses a method of capturing images of multiple randomly supplied workpieces (tablets) to detect information such as the position and posture of each workpiece, and creating a print pattern for each workpiece based on the workpiece information. Patent Document 2 discloses a method of capturing images of multiple randomly supplied tablets with a line sensor camera, and creating print data according to the orientation of the tablet's score line based on the image data.

JP 2011-20325 A JP 2013-121432 A

In the tablet printing technology disclosed in Patent Documents 1 and 2, printing is performed only on one side of the tablet (for example, the side on which the score line is formed in Patent Document 2), but it is also expected that printing will be performed on both the front and back sides of the tablet. When printing on both the front and back sides of a tablet, it is desirable to print in the same direction on both the front and back sides from the perspective of preventing counterfeiting of medicines, etc.

Furthermore, tablets (especially uncoated plain tablets) often have a score line engraved on them to split them in half. Patent Document 2 discloses printing that matches the direction of the score line, but if the front and back sides of the tablet are printed in different directions, there is a problem in that when the tablet is split in half along the score line, the printed information on the back side is divided and the information value is lost.

The present invention was made in consideration of the above problems, and aims to provide a tablet printing device that can perform printing processing on the back side of tablets that have marks on them.

In order to solve the above problem, the invention of claim 1 provides a tablet printing device that performs a printing process on tablets, comprising: a second conveying unit that adsorbs and holds one side of the tablet on a first conveying belt and conveys it; a third conveying unit that receives a tablet from the second conveying unit and conveys the other side of the tablet, which is the side opposite to the one side of the tablet, by adsorbing and holding it on the second conveying belt; a fourth conveying unit that receives a tablet from the third conveying unit and conveys the one side of the tablet by adsorbing and holding it on the third conveying belt; a blow mechanism that is provided within the first conveying belt and blows air into suction holes in the first conveying belt; a first printing unit that is disposed above the second conveying unit and performs a printing process and has a first inkjet head that ejects droplets of ink toward the other side of the tablet transported by the second conveying unit; The tablet conveying system comprises a second printing unit having a jet head for performing printing processing, a first heater arranged below the second conveying unit for heating and drying the tablet conveyed by the second conveying unit, a second heater arranged below the third conveying unit for heating and drying the tablet conveyed by the third conveying unit , a first inspection camera arranged downstream in the conveying direction from the first printing unit and the second printing unit for capturing an image of one side of the tablet, and a second inspection camera arranged downstream in the conveying direction from the first printing unit and the second printing unit for capturing an image of the other side of the tablet, and the tablet is transferred from the second conveying unit to the third conveying unit by blowing air from the blow mechanism into the suction holes at a position where the first conveying belt and the second conveying belt are closely opposed to each other to release the suction state on the tablet and applying negative pressure to the suction holes of the second conveying belt.

The invention of claim 2 is the tablet printing device of the invention of claim 1, further comprising a second imaging unit provided upstream of the first printing unit in the conveying direction and imaging the other side of the tablet, and a third imaging unit provided upstream of the second printing unit in the conveying direction and imaging the one side of the tablet.

In addition, the invention of claim 3 is the tablet printing device according to the invention of claim 1 or 2 , wherein the first heater and the second heater blow hot air onto the tablets being transported to dry the tablets.

According to the invention of claims 1 to 3 , since printing is performed on one side and the other side of the tablet, printing can also be performed on the back side of the tablet on which the mark is provided.

1 is a diagram showing an overall schematic configuration of a tablet printing apparatus according to the present invention; FIG. 2 is a perspective view showing the appearance of a transport drum and a first transport belt. 4 is a flowchart showing a procedure of a processing operation in the tablet printing device of FIG. 1 . 4 is a flowchart showing a procedure of a processing operation in the tablet printing device of FIG. 1 . FIG. FIG. 13 is a diagram showing an example of an imaging result by a first secant camera. FIG. 13 is a diagram showing an example of an imaging result by a second secant camera. FIG. 6 is a diagram showing an example of a result of a printing process performed by a first inkjet head. FIG. 13 is a diagram showing an example of an imaging result by a third secant camera. FIG. 11 is a diagram showing an example of a result of a printing process performed by a second inkjet head.

The following describes in detail the embodiment of the present invention with reference to the drawings.

Figure 1 is a diagram showing the overall schematic configuration of a tablet printing device 1 according to the present invention. This tablet printing device 1 is a device that performs printing processing on both the front and back sides of a tablet. In order to clarify the directional relationship between them, an XYZ Cartesian coordinate system is appropriately attached to Figures 1 and 2, in which the Z axis direction is the vertical direction and the XY plane is the horizontal plane. In addition, in Figure 1 and the subsequent figures, the dimensions and number of each part are exaggerated or simplified as necessary for ease of understanding.

The tablet printing device 1 includes, as its main components, a hopper 8, a conveying drum 10, a first conveying belt 20, a second conveying belt 30, a third conveying belt 40, a first scoring line camera 51, a second scoring line camera 52, a third scoring line camera 53, a first inkjet head 61, and a second inkjet head 62. The tablet printing device 1 also includes a control unit 3 that controls each drive unit provided in the device to progress the printing process on the tablets.

The hopper 8 is provided above the ceiling of the housing 5 of the tablet printing device 1. The hopper 8 is an input section for inputting a large number of tablets into the device all at once. The tablets input from the hopper 8 are guided to the conveying drum 10 by a slider 9. All elements except the hopper 8 are provided inside the housing 5 of the tablet printing device 1.

Figure 2 is a perspective view showing the appearance of the transport drum 10 and the first transport belt 20. The transport drum (first transport section) 10 has a substantially cylindrical shape, and is rotated clockwise on the paper surface of Figure 1 by a rotary drive motor (not shown) about a central axis along the Y-axis direction. As shown in Figure 2, a plurality of suction holes 11 are formed on the outer circumferential surface of the transport drum 10. In this embodiment, the suction holes 11 are formed in five rows at equal intervals along the central axis of the transport drum 10. In addition, a set of five rows of suction holes 11 are provided in multiple rows at equal intervals along the circumferential direction of the outer circumferential surface of the transport drum 10.

The shape of the suction hole 11 depends on the shape of the tablet to be printed. For example, in this embodiment, since a disk-shaped tablet is processed, the shape of the suction hole 11 is also circular. The size of the suction hole 11 is slightly larger than the size of the tablet. For example, if the diameter of the disk-shaped tablet is about 10 mm, the diameter of the suction hole 11 is about 12 mm.

Small holes smaller than the suction holes 11 are provided at the bottom of the multiple suction holes 11, and each of the multiple suction holes 11 communicates with a suction mechanism (not shown) provided inside the conveying drum 10 via the small holes. By operating the suction mechanism, a negative pressure lower than atmospheric pressure can be applied to each of the multiple suction holes 11. This allows each suction hole 11 of the conveying drum 10 to suction and hold one tablet.

In addition, a blow mechanism is provided inside the conveying drum 10 near the portion facing the first conveying belt 20. The blow mechanism blows pressurized air toward the small holes provided at the bottom of the suction holes 11. By blowing air, the blow mechanism can apply a pressure higher than atmospheric pressure to the suction holes 11. This allows the suction state of the tablets by the suction holes 11 to be released. In this way, while the suction mechanism applies suction force to all of the multiple suction holes 11 provided in the conveying drum 10, the blow mechanism can release the suction of the suction holes 11 in five columns and one row facing the first conveying belt 20.

The first conveyor belt (second conveyor section) 20 is constructed by connecting a number of holding plates 22 in a belt-like shape and hanging it over a pair of pulleys. The pair of pulleys are rotated by a drive motor (not shown), causing the belt-like body made up of the number of holding plates 22 to rotate in the direction indicated by the arrow in FIG. 1. The first conveyor belt 20 is installed so that a portion of the belt-like body made up of the number of holding plates 22 faces closely adjacent to the outer circumferential surface of the conveyor drum 10.

As shown in FIG. 2, each of the multiple holding plates 22 has multiple suction holes 21 formed at equal intervals along the belt width direction (Y-axis direction). In this embodiment, each holding plate 22 has five rows of suction holes 21 formed along the Y-axis direction. The shape and size of the suction holes 21 themselves in the first conveyor belt 20 are the same as the suction holes 11 in the conveyor drum 10. In addition, the spacing between the five rows of suction holes 21 in each holding plate 22 is also equal to the spacing between the five rows of suction holes 11 arranged along the central axis of the conveyor drum 10.

Similar to the suction holes 11, the bottoms of the multiple suction holes 21 are provided with small holes smaller than the suction holes 21, and each of the multiple suction holes 21 is connected to a suction mechanism provided inside the first conveyor belt 20 via the small holes. By operating the suction mechanism, a negative pressure lower than atmospheric pressure can be applied to each of the multiple suction holes 21. This allows each suction hole 21 of the first conveyor belt 20 to suction and hold one tablet.

In addition, a blow mechanism is provided inside the first conveyor belt 20 near the area facing the second conveyor belt 30 described below. The blow mechanism blows pressurized air toward the small holes provided at the bottom of the suction holes 21. By blowing air with the blow mechanism, a pressure higher than atmospheric pressure can be applied to the suction holes 21. This allows the tablet to be released from the suction state of the suction holes 21.

Next, the configuration of the second conveyor belt (third conveyor section) 30 and the third conveyor belt (fourth conveyor section) 40 is generally the same as that of the first conveyor belt 20. That is, both the second conveyor belt 30 and the third conveyor belt 40 are configured by connecting multiple holding plates in a belt shape and hanging them on a pair of pulleys. The pair of pulleys are rotated by a drive motor (not shown), so that the second conveyor belt 30 and the third conveyor belt 40 each run in the direction indicated by the arrow in FIG. 1. The second conveyor belt 30 is installed so that a portion of the belt-like body made of multiple holding plates faces closely to the first conveyor belt 20. Similarly, the third conveyor belt 40 is installed so that a portion of the belt-like body made of multiple holding plates faces closely to the second conveyor belt 30.

Each holding plate of the second conveyor belt 30 and the third conveyor belt 40 also has a plurality of suction holes (five rows in this embodiment) formed at equal intervals along the belt width direction (Y-axis direction). As described above, a negative pressure lower than atmospheric pressure can be applied to the suction holes of the second conveyor belt 30 by a suction mechanism provided inside the second conveyor belt 30. This allows each suction hole of the second conveyor belt 30 to suction and hold one tablet. In addition, a blow mechanism is provided inside the second conveyor belt 30 near the part facing the third conveyor belt 40. The blow mechanism blows air to apply a pressure higher than atmospheric pressure to the suction holes of the second conveyor belt 30, thereby releasing the suction state of the tablet by the suction hole.

Similarly, a negative pressure lower than atmospheric pressure can be applied to the suction holes of the third conveyor belt 40 by a suction mechanism provided inside the third conveyor belt 40. This allows each suction hole of the third conveyor belt 40 to suction and hold one tablet. In addition, a blow mechanism is provided at three locations inside the third conveyor belt 40. The blow mechanism blows air to apply a pressure higher than atmospheric pressure to the suction holes of the third conveyor belt 40, thereby releasing the suction state of the tablet through the suction hole.

The three blow mechanisms of the third conveyor belt 40 all blow air downward or diagonally downward. Therefore, the blow mechanism provided at the position facing the good duct 48 among the three blow mechanisms blows air, thereby releasing the tablet from the suction hole and discharging the tablet to the good duct 48. The tablets discharged to the good duct 48 are collected in the good collection box 58. In addition, the blow mechanism provided at the position facing the uninspected duct 47 blows air, thereby releasing the tablet from the suction hole and discharging the tablet to the uninspected duct 47. The tablets discharged to the uninspected duct 47 are collected in the uninspected box 57. In addition, the blow mechanism provided at the position facing the defective duct 46 blows air, thereby releasing the tablet from the suction hole and discharging the tablet to the defective duct 46. The tablets discharged to the defective duct 46 are collected in the defective box 56.

Next, the first dividing line camera (first imaging unit) 51, the second dividing line camera (second imaging unit) 52, and the third dividing line camera (third imaging unit) 53 are all imaging units for imaging a predetermined area, and are, for example, CCD cameras. The first dividing line camera 51 is installed facing the outer peripheral surface of the conveying drum 10 so that the imaging area is the outer peripheral surface of the conveying drum 10. The first dividing line camera 51 is also provided at a position where it can image the downstream side along the conveying direction of the conveying drum 10 from the slider 9. The first dividing line camera 51 images a plurality of tablets that are adsorbed and held in the suction holes 11 of the conveying drum 10 and conveyed. The size of the imaging area of the first dividing line camera 51 can be appropriately set, but since the cylindrical peripheral surface of the conveying drum 10 is imaged, it is difficult to focus over a wide range of the cylindrical peripheral surface. For this reason, the imaging area of the first dividing line camera 51 only needs to be large enough to image at least five columns and one row of tablets facing the first dividing line camera 51.

The second scoring camera 52 is installed facing the conveying surface of the first conveyor belt 20 so that the imaging area is the conveying surface of the first conveyor belt 20. The second scoring camera 52 is provided at a position downstream of the opposing position with the conveying drum 10 along the conveying direction of the first conveyor belt 20 and capable of imaging the upstream side of the first inkjet head 61. The second scoring camera 52 images a plurality of tablets that are adsorbed and held by the first conveyor belt 20 and conveyed. The size of the imaging area of the second scoring camera 52 can be appropriately determined, and it is sufficient that the size is large enough to image at least five columns and one row of tablets facing the second scoring camera 52. Unlike the conveying drum 10, the conveying surface of the first conveyor belt 20 is substantially flat, so that it is relatively easy to focus on the entire surface of the imaging area of the second scoring camera 52 even if the imaging area is wide.

The third dividing line camera 53 is installed facing the conveying surface of the second conveyor belt 30 so that the imaging area is the conveying surface of the second conveyor belt 30. The third dividing line camera 53 is provided at a position downstream of the opposing position with the first conveyor belt 20 along the conveying direction of the second conveyor belt 30 and capable of imaging the upstream side of the second inkjet head 62. The third dividing line camera 53 images a plurality of tablets that are adsorbed and held by the second conveyor belt 30 and conveyed. The size of the imaging area of the third dividing line camera 53 can be appropriately set, and it is sufficient that it is large enough to image at least five columns and one row of tablets facing the third dividing line camera 53. As with the second dividing line camera 52, the conveying surface of the second conveyor belt 30 is substantially flat, so that it is relatively easy to focus on the entire surface even if the imaging area of the third dividing line camera 53 is wide.

The first inkjet head 61 and the second inkjet head 62 are provided with a plurality of ejection nozzles, and eject ink droplets from the ejection nozzles by an inkjet method. The inkjet method may be a piezoelectric method in which a voltage is applied to a piezoelectric element (piezoelectric element) to deform it and eject ink droplets, or a thermal method in which electricity is applied to a heater to heat the ink and eject ink droplets. In this embodiment, in order to perform printing processing on pharmaceutical tablets, edible inks manufactured from raw materials approved by the Food Sanitation Act are used as the inks ejected from the first inkjet head 61 and the second inkjet head 62. In addition, the first inkjet head 61 and the second inkjet head 62 can eject four colors of ink: cyan (C), magenta (M), yellow (Y), and black (K), and color printing is possible by mixing these colors.

The first inkjet head 61 is provided downstream of the second dividing line camera 52 along the conveying direction of the first conveyor belt 20. The first inkjet head 61 performs a printing process on a plurality of tablets that are adsorbed and held by the first conveyor belt 20 and conveyed. The second inkjet head 62 is provided downstream of the third dividing line camera 53 along the conveying direction of the second conveyor belt 30. The second inkjet head 62 performs a printing process on a plurality of tablets that are adsorbed and held by the second conveyor belt 30 and conveyed. The first inkjet head 61 and the second inkjet head 62 are preferably full-line heads that cover the entire width of the first conveyor belt 20 and the second conveyor belt 30, respectively.

The tablet printing device 1 also includes a first inspection camera 71 and a second inspection camera 72. As the first inspection camera 71 and the second inspection camera 72, for example, a CCD camera can be used, as in the case of the score line camera described above. The first inspection camera 71 is installed facing the conveying surface of the second conveyor belt 30 so that the imaging area is the conveying surface of the second conveyor belt 30. The first inspection camera 71 is provided at a position where it can image the downstream side of the second inkjet head 62 along the conveying direction of the second conveyor belt 30. The first inspection camera 71 images a plurality of tablets that are adsorbed and held by the second conveyor belt 30 and conveyed. As shown in FIG. 1, the first inspection camera 71 is provided below the second conveyor belt 30, but since the second conveyor belt 30 adsorbs and holds the tablets and conveys them, the tablets are conveyed without falling even if they are facing downward (the suction holes are open toward the downward side).

The second inspection camera 72 is installed facing the conveying surface of the third conveyor belt 40 so that its imaging area corresponds to the conveying surface of the third conveyor belt 40. The second inspection camera 72 captures images of the tablets that are adsorbed, held, and conveyed by the third conveyor belt 40.

The tablet printing device 1 also includes a first heater 76 and a second heater 77. For example, the first heater 76 and the second heater 77 may be hot air drying heaters that blow hot air to heat and dry the tablets. The first heater 76 is provided downstream of the first inkjet head 61 along the conveying direction of the first conveyor belt 20. The first heater 76 blows hot air onto the tablets that have been printed by the first inkjet head 61 to dry them.

The second heater 77 is provided downstream of the second inkjet head 62 along the conveying direction of the second conveyor belt 30. The second heater 77 blows hot air onto the tablets that have been printed by the second inkjet head 62 to dry them. The first heater 76 and the second heater 77 are provided below the first conveyor belt 20 and the second conveyor belt 30, respectively. However, as described above, the first conveyor belt 20 and the second conveyor belt 30 adsorb and hold the tablets for conveyance, so that even if the tablet is facing downward, the tablet is conveyed without falling.

The tablet printing device 1 further includes four cleaning mechanisms 81, 82, 83, and 84. Powder generated from the tablets may adhere to the conveying drum 10, the first conveying belt 20, the second conveying belt 30, and the third conveying belt 40. The cleaning mechanisms 81, 82, 83, and 84 clean the powder adhering to the conveying drum 10, the first conveying belt 20, the second conveying belt 30, and the third conveying belt 40, respectively. The cleaning mechanisms 81, 82, 83, and 84 may be, for example, mechanisms that blow air to suck and collect the surrounding atmosphere.

The control unit 3 controls the various operating mechanisms provided in the tablet printing device 1. The hardware configuration of the control unit 3 is similar to that of a general computer. That is, the control unit 3 is configured with a CPU that performs various arithmetic processing, a ROM that is a read-only memory that stores basic programs, a RAM that is a readable and writable memory that stores various information, and a magnetic disk that stores control software, data, etc. The CPU of the control unit 3 executes a predetermined processing program, and the processing of tablets in the tablet printing device 1 proceeds. The control unit 3 also functions as a print control unit that controls the first inkjet head 61 and the second inkjet head 62 based on image data acquired by the first scoring line camera 51 and the second scoring line camera 52, etc.

Next, the processing operation in the tablet printing device 1 having the above configuration will be described. Figures 3 and 4 are flowcharts showing the procedure of the processing operation in the tablet printing device 1. First, multiple tablets are loaded into the hopper 8 of the tablet printing device 1 at once (step S1). The tablets may be loaded in bulk manually by an operator using a bucket or the like, or may be loaded automatically by a conveying mechanism separate from the tablet printing device 1. However, the multiple tablets loaded in bulk are all of the same type.

In this embodiment, multiple disk-shaped tablets 2 are fed into a hopper 8. FIG. 5 is a plan view of a tablet 2. A score line 7 for splitting the tablet 2 in half is engraved on one side of the tablet 2. The score line 7 is a groove engraved along the radial direction of the disk-shaped tablet 2. The score line 7 is engraved only on one side of the tablet 2.

In this embodiment, the surface on which the score line 7 is provided is the front surface of the tablet 2. The back surface of the tablet 2 does not have a score line 7. Note that there is no difference in medicinal properties between the front surface and back surface of the tablet 2, and the surface on which the score line 7 is provided is merely the front surface for the sake of distinction.

The tablets 2 fed into the hopper 8 are guided to the conveying drum 10 by the slider 9, and the tablets 2 are adsorbed and held one by one in the suction holes 11 of the conveying drum 10. The conveying drum 10 has five rows of suction holes 11 formed in a direction perpendicular to the conveying direction (circumferential direction of the conveying drum 10), that is, along the central axis of the conveying drum 10. Therefore, the conveying drum 10 conveys the tablets 2 in five rows, with five tablets aligned in a direction perpendicular to the conveying direction. In this specification, the unit of five tablets aligned in a direction perpendicular to the conveying direction of the conveying drum 10 is referred to as a "row". That is, the conveying drum 10 adsorbs and holds the tablets 2 individually in each suction hole 11, and conveys the tablets 2 aligned in five rows (step S2). In addition, an alignment mechanism that aligns and feeds the tablets 2 in groups of five may be attached to the hopper 8 so that the conveying drum 10 can smoothly adsorb and hold the tablets 2 fed from the hopper 8 in groups of five. An example of such an alignment mechanism is a ball holder type mechanism.

Next, the first dividing line camera 51 captures an image of the tablets 2 being conveyed by the conveying drum 10 (step S3). The tablets 2 are held by the suction holes 11 of the conveying drum 10 and conveyed clockwise on the paper surface of FIG. 1 along the circumferential direction of the conveying drum 10. Although the tablets 2 are aligned in five rows and conveyed, it is completely random whether the surface of each tablet 2 faces the inside of the conveying drum 10 (the center side of the conveying drum 10) or the outside. In addition, since the circular tablets 2 are held by the circular suction holes 11, the direction of the tablets 2 is arbitrary, and the direction of the dividing line 7 of each tablet 2 conveyed by the conveying drum 10 is also completely random. The first dividing line camera 51 captures the tablets 2 from the outside of the conveying drum 10. Therefore, the tablets 2 captured by the first dividing line camera 51 randomly include tablets facing the front side and tablets facing the back side to the first dividing line camera 51.

In other words, the first dividing line camera 51 captures one side of the tablets 2 being transported by the transport drum 10. Here, "one side" refers to the side of the tablets 2 that faces outward as they are transported by the transport drum 10, regardless of whether it is the front or back side of the tablets 2.

The first dividing line camera 51 also captures images of each row of five tablets arranged in a direction perpendicular to the conveying direction of the conveying drum 10. This is because the outer circumferential surface of the conveying drum 10 is cylindrical, making it difficult to focus the first dividing line camera 51 across multiple rows.

Figure 6 is a diagram showing an example of an image captured by the first dividing line camera 51. The first dividing line camera 51 captures one side of a plurality of tablets 2 transported by the transport drum 10. When each tablet 2 is adsorbed and held by the transport drum 10, whether the front side faces outward or inward is random, so the one side of the plurality of tablets 2 captured by the first dividing line camera 51 randomly includes the front side on which the dividing line 7 is formed and the reverse side, which is the opposite side. In the example of Figure 6, of the tablets 2 arranged in five rows, the front sides of the tablets 2 at the left end and in the center are captured, and the reverse sides of the other tablets 2 are captured by the first dividing line camera 51. The image data captured by the first dividing line camera 51 as shown in Figure 6 is transmitted to the control unit 3.

Next, the tablets 2 in the first row and five columns imaged by the first dividing line camera 51 are further transported by the transport drum 10 and reach a position adjacent to the first transport belt 20. At this time, the blow mechanism of the transport drum 10 blows air into the five suction holes 11 to which the tablets 2 in the first row and five columns are suction-held, thereby releasing the suction state of the tablets 2 in the first row and five columns. Meanwhile, a negative pressure is acting on the suction holes 21 of the holding plate 22 of the first transport belt 20 at a position adjacent to the transport drum 10. Therefore, the tablets 2 in the first row and five columns, whose suction state by the transport drum 10 has been released, are transferred from the suction holes 11 of the transport drum 10 to the suction holes 21 of the first transport belt 20 and are suction-held. In order to ensure the transfer of the tablets 2, the control unit 3 controls the transport speed of the transport drum 10 and the transport speed of the first transport belt 20 to be equal, and controls the operation of both transport units to be synchronized so that the suction holes 11 and suction holes 21 are accurately opposed to each other.

When the tablets 2 are transferred from the transport drum 10 to the first transport belt 20, the tablets 2 move as they are without rotating or otherwise moving. In other words, each tablet 2 is transferred from the transport drum 10 to the first transport belt 20 while maintaining the direction of the score line 7.

When the tablets 2 are transferred from the transport drum 10 to the first transport belt 20, each tablet 2 is turned over. That is, the tablets 2 that were adsorbed and held on the transport drum 10 with the front surface on which the score line 7 is formed facing outward are adsorbed and held in the suction holes 21 of the first transport belt 20 with the back surface facing outward. Conversely, the tablets 2 that were adsorbed and held on the transport drum 10 with the back surface facing outward are adsorbed and held on the first transport belt 20 with the front surface facing outward. Therefore, each tablet 2 that was being transported by the transport drum 10 is turned over while maintaining its orientation, and is delivered to the first transport belt 20 and transported (step S4).

Then, the second scoring camera 52 captures an image of the tablets 2 being conveyed by the first conveyor belt 20 (step S5). The first conveyor belt 20 conveys the tablets 2 received from the conveyor drum 10 with the tablets turned upside down, aligned in five rows in a direction perpendicular to the conveying direction. The second scoring camera 52 captures an image of the tablets 2 from the outside of the first conveyor belt 20. Thus, the tablets 2 captured by the second scoring camera 52 randomly include tablets with their front faces facing the second scoring camera 52 and tablets with their back faces facing the second scoring camera 52. However, since the tablets 2 are turned upside down when they are handed over from the conveyor drum 10 to the first conveyor belt 20, the front and back of each tablet 2 captured by the first scoring camera 51 are completely opposite to the front and back of the corresponding tablet 2 captured by the second scoring camera 52.

In other words, the second dividing line camera 52 captures the other side of the tablets 2 being transported by the first transport belt 20. Here, the "other side" means the side opposite to the one side mentioned above, and refers to the side facing outward of the tablets 2 being transported by the first transport belt 20, regardless of whether it is the front or back side of the tablets 2.

Because the conveying surface of the first conveyor belt 20 is substantially flat, the second scoring line camera 52 can also capture images of the tablets 2 across multiple rows. In this embodiment, however, the second scoring line camera 52 also captures images of each row of five tablets arranged in a direction perpendicular to the conveying direction of the first conveyor belt 20 so as to match the imaging range of the first scoring line camera 51.

Figure 7 is a diagram showing an example of an image captured by the second scoring line camera 52. The second scoring line camera 52 captures the other side of the multiple tablets 2 transported by the first transport belt 20. The other side is the side opposite to the one side of the multiple tablets 2 captured by the first scoring line camera 51. Therefore, for tablets 2 whose front side is captured by the first scoring line camera 51, the back side is captured by the second scoring line camera 52. Conversely, for tablets 2 whose back side is captured by the first scoring line camera 51, the front side is captured by the second scoring line camera 52.

In the example of FIG. 7, contrary to FIG. 6, of the tablets 2 arranged in five rows, the backsides of the tablets 2 at the left end and in the center are imaged, and the fronts of the other tablets 2 on which the score line 7 is formed are imaged by the second score line camera 52. The image data as shown in FIG. 7, which is the result of imaging by the second score line camera 52, is transmitted to the control unit 3. Note that in FIG. 7, the dotted line indicates the score line 7 on one side of the tablet 2 that is imaged and recognized by the first score line camera 51, and is not directly imaged by the second score line camera 52.

Next, the tablet 2 imaged by the second scoring line camera 52 is further transported by the first transport belt 20 to a position facing the first inkjet head 61. The first inkjet head 61 then performs a printing process on the tablet 2 (step S6). Here, the control unit 3 controls the printing process by the first inkjet head 61 based on the image data acquired by the first scoring line camera 51 and the second scoring line camera 52. FIG. 8 is a diagram showing an example of the result of the printing process by the first inkjet head 61.

As described above, the first dividing line camera 51 captures one side of the tablets 2 being conveyed by the conveying drum 10. When the tablets 2 are transferred from the conveying drum 10 to the first conveying belt 20, the front and back of all the tablets 2 are inverted. The second dividing line camera 52 captures the other side of the tablets 2 being conveyed by the first conveying belt 20. Therefore, the first dividing line camera 51 and the second dividing line camera 52 capture both the front and back of all the tablets 2, and image data is acquired. Specifically, for the tablets 2 whose front side is captured by the first dividing line camera 51, the back side is captured by the second dividing line camera 52 (the tablets 2 at the left end and in the center in the example of Figs. 6 and 7). Conversely, for the tablets 2 whose back side is captured by the first dividing line camera 51, the front side is captured by the second dividing line camera 52 (the second, fourth, and fifth tablets 2 from the left in the example of Figs. 6 and 7).

The first inkjet head 61 performs printing processing on the other side of the multiple tablets 2 transported by the first transport belt 20. The control unit 3 causes the first inkjet head 61 to perform front side printing processing based on front side printing data for tablets 2 whose other side is the front side among the multiple tablets 2 transported by the first transport belt 20 (the second, fourth, and fifth tablets 2 from the left in the example of Figures 7 and 8). Here, the front side printing data is, for example, character data of "ABCD."

The control unit 3 also causes the first inkjet head 61 to perform a surface printing process on the surface of the tablet 2 along a predetermined direction relative to the score line 7 engraved on the surface of the tablet 2. In this embodiment, the first inkjet head 61 performs a printing process along a direction parallel to the score line 7 on the surface of the tablet 2. The control unit 3 can recognize the direction of the score line 7 on the tablet 2 whose other surface is the surface among the multiple tablets 2 transported by the first transport belt 20 by performing image processing on the image data acquired by the second score line camera 52 (the direction of the score line 7 shown by the solid line in FIG. 8). As a result, as shown in FIG. 8, for the tablets 2 whose other surface is the surface among the multiple tablets 2 transported by the first transport belt 20, the character string "ABCD" is printed on the surface of the tablet 2 by the first inkjet head 61 along a direction parallel to the score line 7 engraved on the surface.

On the other hand, the control unit 3 causes the first inkjet head 61 to perform a back-side printing process based on the back-side printing data for tablets 2 whose other side is a back side (the tablets 2 on the left end and in the center in the example of Figures 7 and 8) among the multiple tablets 2 transported by the first transport belt 20. Here, the back-side printing data is, for example, character data of "1234".

The control unit 3 also causes the first inkjet head 61 to perform a backside printing process on the backside of the tablet 2 along the same direction as the above-mentioned predetermined direction with respect to the score line 7 engraved on the surface of the tablet 2. In this embodiment, the printing process is performed on the front side of the tablet 2 along a direction parallel to the score line 7, and the first inkjet head 61 also performs a printing process on the backside of the tablet 2 along a direction parallel to the score line 7 on the front side. The control unit 3 can recognize the direction of the score line 7 on the front side of the tablet 2 whose other side is the backside of the multiple tablets 2 transported by the first conveyor belt 20 by performing image processing on the image data acquired by the first score line camera 51 (the direction of the score line 7 shown by the dotted line in FIG. 8). As a result, as shown in FIG. 8, for the multiple tablets 2 transported by the first conveyor belt 20 whose other side is the backside of the multiple tablets 2, the character string "1234" is printed on the backside of the tablet 2 by the first inkjet head 61 along a direction parallel to the score line 7 engraved on the front side.

Furthermore, the control unit 3 fine-tunes (corrects) the printing position for each tablet 2 by the first inkjet head 61 based on the image data acquired by the second dividing line camera 52. Since the size of the suction holes 21 of the first conveyor belt 20 is slightly larger than the size of the tablets 2, when the tablets 2 are transferred from the conveyor drum 10 to the first conveyor belt 20, the directionality of each tablet 2 is maintained, but some positional variation occurs within the range of the suction holes 21. The control unit 3 detects the positional deviation of each tablet 2 within the suction holes 21 from the image data acquired by the second dividing line camera 52, and performs fine adjustment of the printing position based on the detection result. In this way, the printing process for the other sides of the multiple tablets 2 is performed.

Next, the tablet 2 having undergone printing processing on the other side is further transported by the first transport belt 20 and reaches a position facing the first heater 76. As shown in FIG. 1, the first heater 76 is installed below the first transport belt 20, and when the tablet 2 reaches a position facing the first heater 76, the tablet 2 is held facing downward by the first transport belt 20. The first transport belt 20 suction-holds the tablet 2 by applying negative pressure to the suction holes 21, so it is also possible to hold the tablet 2 facing downward.

The first heater 76 blows hot air onto the other side of the tablets 2 being transported by the first transport belt 20 to dry the tablets 2 (step S7). By performing such a drying process, the ink ejected from the first inkjet head 61 onto the tablets 2 can be quickly dried to prevent bleeding.

Next, the tablets 2 in the first row of five columns dried by the first heater 76 are further transported by the first conveyor belt 20 and reach a position adjacent to the second conveyor belt 30. At this time, the blow mechanism of the first conveyor belt 20 blows air into the five suction holes 21 in which the tablets 2 in the first row of five columns are suction-held, thereby releasing the suction state of the tablets 2 in the first row of five columns. Meanwhile, negative pressure is acting on the suction holes of the second conveyor belt 30 at a position adjacent to the first conveyor belt 20. Therefore, the tablets 2 in the first row of five columns, whose suction state by the first conveyor belt 20 has been released, are transferred from the suction holes 21 of the first conveyor belt 20 to the suction holes of the second conveyor belt 30 and are suction-held. In order to ensure such transfer of the tablets 2, the control unit 3 controls the conveying speed of the first conveyor belt 20 to be equal to the conveying speed of the second conveyor belt 30, and synchronizes the operations of both conveyor belts so that the suction holes of both conveyor belts are accurately opposed to each other.

When the tablet 2 is transferred from the first conveyor belt 20 to the second conveyor belt 30, the tablet 2 moves as is without rotating or otherwise. In other words, each tablet 2 is transferred from the first conveyor belt 20 to the second conveyor belt 30 while maintaining the direction of the score line 7.

When the tablets 2 are transferred from the first conveyor belt 20 to the second conveyor belt 30, each tablet 2 is turned over. That is, the tablet 2 that was adsorbed and held by the first conveyor belt 20 with the surface on which the score line 7 is formed facing outward is adsorbed and held by the second conveyor belt 30 with the back surface facing outward. Conversely, the tablet 2 that was adsorbed and held by the first conveyor belt 20 with the back surface facing outward is adsorbed and held by the second conveyor belt 30 with the front surface facing outward. Therefore, each tablet 2 that was being conveyed by the first conveyor belt 20 is turned over while maintaining its orientation, and is handed over to the second conveyor belt 30 for conveyance (step S8).

Next, the third dividing line camera 53 captures an image of the tablets 2 being conveyed by the second conveyor belt 30 (step S9). The second conveyor belt 30 conveys the tablets 2 received from the first conveyor belt 20 with the tablets turned upside down, aligned in five rows in a direction perpendicular to the conveying direction. The third dividing line camera 53 captures the tablets 2 from the outside of the second conveyor belt 30. Therefore, the front and back of each tablet 2 captured by the third dividing line camera 53 is completely opposite to the front and back of the corresponding tablet 2 captured by the second dividing line camera 52, while it is completely the same as the front and back of the corresponding tablet 2 captured by the first dividing line camera 51. That is, the third dividing line camera 53 captures one side of the tablets 2 being conveyed by the second conveyor belt 30, just like the first dividing line camera 51.

Since the conveying surface of the second conveyor belt 30 is substantially flat, the third dividing line camera 53 can also capture images of the tablets 2 across multiple rows. In this embodiment, however, the third dividing line camera 53 also captures images of each row of five tablets arranged in a direction perpendicular to the conveying direction of the second conveyor belt 30 so as to match the imaging range of the first dividing line camera 51.

Figure 9 is a diagram showing an example of the imaging results by the third dividing line camera 53. Like the first dividing line camera 51, the third dividing line camera 53 images one side of the multiple tablets 2 transported by the second transport belt 30. Therefore, the imaging results by the third dividing line camera 53 are generally the same as the imaging results by the first dividing line camera 51. In particular, the imaging results by the third dividing line camera 53 and the imaging results by the first dividing line camera 51 completely match with respect to the directionality of each of the multiple tablets 2.

In the example of FIG. 9, as in FIG. 6, of the tablets 2 arranged in five rows, the front side where the score line 7 is formed is imaged for the leftmost and central tablets 2, and the back side of the other tablets 2 is imaged by the third score line camera 53. The image data as shown in FIG. 9, which is the result of imaging by the third score line camera 53, is transmitted to the control unit 3. Note that in FIG. 9, the dotted line indicates the score line 7 on the other side of the tablet 2 that is imaged and recognized by the second score line camera 52, and is not directly imaged by the third score line camera 53.

However, the control unit 3 does not recognize the direction of the score line 7 engraved on the surface of the tablet 2 from the image data acquired by the third score line camera 53. This is because for tablets 2 whose one side is the front, the direction of the score line 7 has already been recognized from the image data acquired by the first score line camera 51, and there is no need to recognize it again. Rather, if the control unit 3 recognized the direction of the score line 7 from the image data acquired by the third score line camera 53, there is a possibility that it will be printed 180 degrees in the opposite direction during the printing process by the second inkjet head 62 described later.

The third dividing line camera 53 captures images in order to detect the variation in the positions of the multiple tablets 2 that are suction-held by the second conveyor belt 30. The control unit 3 detects the deviation in the position of each tablet 2 within the suction holes of the second conveyor belt 30 from the image data acquired by the third dividing line camera 53.

Next, the tablet 2 imaged by the third scoring line camera 53 is further transported by the second transport belt 30 and reaches a position facing the second inkjet head 62. The second inkjet head 62 then performs a printing process on the tablet 2 (step S10). Here, the control unit 3 controls the printing process by the second inkjet head 62 based on the image data acquired by the first scoring line camera 51 and the second scoring line camera 52. FIG. 10 is a diagram showing an example of the result of the printing process by the second inkjet head 62.

The second inkjet head 62 performs printing on one side of the tablets 2 transported by the second transport belt 30. The control unit 3 causes the second inkjet head 62 to perform front side printing based on the front side printing data for the tablets 2 that have a front side (the tablets 2 on the left and in the center in the example of Figures 9 and 10) among the tablets 2 transported by the second transport belt 30. Here, the front side printing data is the same character data of "ABCD" as above.

The control unit 3 also causes the second inkjet head 62 to perform a surface printing process on the surface along the above-mentioned predetermined direction relative to the score line 7 engraved on the surface of the tablet 2. In this embodiment, the second inkjet head 62 performs a printing process along a direction parallel to the score line 7 on the surface of the tablet 2. The control unit 3 can recognize the direction of the score line 7 on the tablet 2 whose one side is the surface among the multiple tablets 2 transported by the second transport belt 30 by performing image processing on the image data acquired by the first score line camera 51 (the direction of the score line 7 shown by the solid line in FIG. 10). As a result, as shown in FIG. 10, for the tablets 2 whose one side is the surface among the multiple tablets 2 transported by the second transport belt 30, the character string "ABCD" is printed on the surface of the tablet 2 by the second inkjet head 62 along a direction parallel to the score line 7 engraved on the surface.

On the other hand, the control unit 3 causes the second inkjet head 62 to perform a back-side printing process for tablets 2 whose one side is a back side (the second, fourth, and fifth tablets 2 from the left in the example of Figures 9 and 10) among the multiple tablets 2 transported by the second transport belt 30, based on the back-side printing data. In this case, the back-side printing data is the character data "1234" as described above.

The control unit 3 also causes the second inkjet head 62 to perform a backside printing process on the backside of the tablet 2 along the same direction as the above-mentioned predetermined direction with respect to the score line 7 engraved on the surface of the tablet 2. In this embodiment, the printing process is performed on the front side of the tablet 2 along a direction parallel to the score line 7, and the second inkjet head 62 also performs a printing process on the backside of the tablet 2 along a direction parallel to the score line 7 on the front side. The control unit 3 can recognize the direction of the score line 7 on the front side of the tablet 2 whose one side is the back side among the multiple tablets 2 transported by the second transport belt 30 by performing image processing on the image data acquired by the second score line camera 52 (the direction of the score line 7 shown by the dotted line in FIG. 10). As a result, as shown in FIG. 10, for the tablets 2 whose one side is the back side among the multiple tablets 2 transported by the second transport belt 30, the character string "1234" is printed on the backside of the tablet 2 by the second inkjet head 62 along a direction parallel to the score line 7 engraved on the front side.

Furthermore, the control unit 3 fine-tunes (corrects) the printing position of each tablet 2 by the second inkjet head 62 based on the image data acquired by the third dividing line camera 53. As described above, when the tablets 2 are transferred from the first conveyor belt 20 to the second conveyor belt 30, the directionality of each tablet 2 is maintained, but some positional variation occurs within the range of the suction hole. The control unit 3 detects the positional deviation of each tablet 2 within the suction hole of the second conveyor belt 30 from the image data acquired by the third dividing line camera 53, and performs fine adjustment of the printing position based on the detection result. In this way, the printing process is performed on one side of multiple tablets 2.

Next, the tablets 2 whose one side has been printed are further transported by the second transport belt 30 and reach a position facing the first inspection camera 71. The first inspection camera 71 images one side of the tablets 2 transported by the second transport belt 30, and images the results of the printing process performed by the second inkjet head 62 on one side of the tablets 2. The first inspection camera 71 transmits the acquired image data to the control unit 3. The control unit 3 checks the results of the printing process performed by the second inkjet head 62 on one side of the tablets 2 based on the image data acquired by the first inspection camera 71 (step S11).

Then, the tablets 2 whose one side has been inspected for the printing process result are further transported by the second transport belt 30 and reach a position facing the second heater 77. The second heater 77 blows hot air onto one side of the tablets 2 transported by the second transport belt 30 to dry the tablets 2 (step S12). By carrying out such a drying process, the ink ejected from the second inkjet head 62 onto the tablets 2 can be quickly dried to prevent bleeding.

Next, the tablets 2 in the 5th row and 1st row, which have been dried by the second heater 77, are further transported by the second transport belt 30 and reach a position adjacent to the third transport belt 40. At this time, the blow mechanism of the second transport belt 30 blows air into the five suction holes in which the tablets 2 in the 5th row and 1st row are suction-held, thereby releasing the suction state of the tablets 2 in the 5th row and 1st row. Meanwhile, negative pressure is acting on the suction holes of the third transport belt 40 at a position adjacent to the second transport belt 30. Therefore, the tablets 2 in the 5th row and 1st row, which have been released from the suction state by the second transport belt 30, are transferred from the suction holes of the second transport belt 30 to the suction holes of the third transport belt 40 and are suction-held. In order to ensure such transfer of the tablets 2, the control unit 3 controls the transport speed of the second transport belt 30 to be equal to the transport speed of the third transport belt 40, and synchronizes the operations of both transport belts so that the suction holes of both transport belts are accurately opposed to each other.

When the tablet 2 is transferred from the second conveyor belt 30 to the third conveyor belt 40, the tablet 2 moves as is without rotating or otherwise. In other words, each tablet 2 is transferred from the second conveyor belt 30 to the third conveyor belt 40 while maintaining the direction of the score line 7.

When the tablets 2 are transferred from the second conveyor belt 30 to the third conveyor belt 40, each tablet 2 is turned over. That is, the tablet 2 that was adsorbed and held by the second conveyor belt 30 with the surface on which the score line 7 is formed facing outward is adsorbed and held by the third conveyor belt 40 with the back surface facing outward. Conversely, the tablet 2 that was adsorbed and held by the second conveyor belt 30 with the back surface facing outward is adsorbed and held by the third conveyor belt 40 with the front surface facing outward. Therefore, each tablet 2 that was being conveyed by the second conveyor belt 30 is turned over while maintaining its orientation, and is handed over to the third conveyor belt 40 for conveyance (step S13).

Then, the second inspection camera 72 captures an image of the tablets 2 being transported by the third transport belt 40. The third transport belt 40, like the first transport belt 20, adsorbs and holds the tablets 2 with their other sides facing outward. Thus, the second inspection camera 72 captures the other sides of the tablets 2 being transported by the third transport belt 40, and captures the results of the printing process performed by the first inkjet head 61 on the other sides of the tablets 2. The second inspection camera 72 transmits the acquired image data to the control unit 3. The control unit 3 checks the results of the printing process performed by the first inkjet head 61 on the other sides of the tablets 2 based on the image data acquired by the second inspection camera 72 (step S14).

Finally, the tablets 2 after inspection on both sides are sorted (step S15). Tablets 2 for which the inspection results on both sides in steps S11 and S14 were satisfactory, i.e., good tablets 2, are fed into the good duct 48 by blowing air from the blowing mechanism. The tablets 2 discharged into the good duct 48 are collected in the good recovery box 58. On the other hand, tablets 2 for which the inspection results on either the front or back were satisfactory, i.e., defective tablets 2, are fed into the defective duct 46 by blowing air from the blowing mechanism. The tablets 2 discharged into the defective duct 46 are collected in the defective box 56. In this manner, the printing process on the tablets 2 in the tablet printing device 1 is completed.

In this embodiment, based on image data of the front and back surfaces of multiple tablets 2 acquired by the first scoring line camera 51 and the second scoring line camera 52, a front printing process is performed on the front surface of the tablet 2 along a predetermined direction relative to the front scoring line 7, and a back printing process is performed on the back surface of the tablet 2 along the same direction as the above-mentioned predetermined direction of the back surface. Therefore, printing can be performed on both the front and back surfaces of the tablet 2 in the same direction relative to the scoring line 7.

Although the embodiments of the present invention have been described above, various modifications to the present invention are possible without departing from the spirit of the invention. For example, in each of the above embodiments, printing is performed on both sides of the tablet 2 in a direction parallel to the score line 7, but this is not limited to this, and printing can be performed in any direction relative to the score line 7 as long as the front and back of the tablet 2 are printed in the same direction.

The reference for the printing process direction is not limited to the dividing line 7, but can be any mark that identifies the direction, such as an arrow engraved on the surface of the tablet 2. If the mark can identify the direction, the same printing process as in the above embodiment can be performed along a specific direction relative to the mark.

In addition, in the above embodiment, the score line 7 is engraved on the surface of the tablet 2, but as mentioned above, the surface on which the score line 7 is formed is merely the front surface for convenience, and the surface on which the score line 7 is formed may also be the back surface.

The shape of the tablet 2 is not limited to a disk shape, but may be other shapes such as an approximately oval shape or a rod shape. In this case, the suction holes of each conveying section correspond to the shape of the tablet 2.

In addition, in the above embodiment, the tablets 2 are transported in units of 5 columns and 1 row, but this is not limited to this, and the tablets 2 may be transported in a single row, or in multiple rows of 2 or more rows.

In the above embodiment, the tablets 2 are sorted into good and bad based on the inspection results from the first dividing line camera 51 and the second dividing line camera 52. However, the tablet printing device 1 can also select a mode in which only the printing process is performed without inspection. When such a mode is selected, all tablets 2 that have been printed are fed from the third conveyor belt 40 into the uninspected duct 47. The tablets 2 fed into the uninspected duct 47 are collected in the uninspected box 57. Furthermore, the tablet printing device 1 may be set to a mode in which only the inspection process is performed on uninspected tablets 2.

The tablet printing device of the present invention can be used effectively to print on both sides of pharmaceutical tablets that have a score line engraved on them.

REFERENCE SIGNS LIST 1 Tablet printing device 2 Tablet 3 Control unit 7 Scoring line 8 Hopper 10 Conveyor drum 20 First conveyor belt 30 Second conveyor belt 40 Third conveyor belt 51 First scoring line camera 52 Second scoring line camera 53 Third scoring line camera 61 First inkjet head 62 Second inkjet head 71 First inspection camera 72 Second inspection camera 76 First heater 77 Second heater

Claims (3)

A tablet printing device that performs printing processing on tablets,
A second conveying unit that adsorbs and holds one side of the tablet on the first conveying belt and conveys the tablet;
a third conveying unit that receives the tablet from the second conveying unit and conveys the tablet by adsorbing and holding the other side of the tablet, which is the side opposite to the one side, on a second conveying belt;
a fourth conveying unit that receives the tablet from the third conveying unit and conveys the tablet by adsorbing and holding the one side of the tablet on the third conveying belt;
a blow mechanism provided in the first conveyor belt and configured to blow air into suction holes of the first conveyor belt;
A first printing unit that is disposed above the second transport unit and has a first inkjet head that ejects ink droplets toward the other side of the tablet transported by the second transport unit and performs a printing process;
A second printing unit that is disposed above the third transport unit and has a second inkjet head that ejects ink droplets toward the one side of the tablet transported by the third transport unit and performs a printing process;
A first heater is disposed below the second conveying unit and heats and dries the tablet conveyed by the second conveying unit;
A second heater is disposed below the third conveying unit and heats and dries the tablet conveyed by the third conveying unit;
A first inspection camera is provided downstream of the first printing unit and the second printing unit in a conveying direction and captures an image of the one side of the tablet;
A second inspection camera is provided downstream of the first printing unit and the second printing unit in the conveying direction and captures the other side of the tablet.
Equipped with
In this tablet printing device, the tablet is transferred from the second conveying section to the third conveying section by blowing air from the blowing mechanism into the suction holes at a position where the first conveying belt and the second conveying belt are closely opposed to each other to release the suction state of the tablet and applying negative pressure to the suction holes of the second conveying belt. 2. The tablet printing apparatus according to claim 1,
A second imaging unit provided upstream of the first printing unit in the conveying direction and configured to image the other side of the tablet;
A third imaging unit provided upstream of the second printing unit in the conveying direction and configured to image the one side of the tablet;
The tablet printing apparatus further comprises: In the tablet printing apparatus according to claim 1 or 2 ,
The first heater and the second heater are a tablet printing device that blows hot air onto the tablets being transported to dry the tablets.

Images