Embodiments described herein relate generally to a tablet printing device and a tablet printing method.
Generally, a tablet printing device prints identification information such as letters or characters (e.g., alphabet, kana, and numeric) or marks (e.g., symbols and figures) on the surface of a tablet in order to identify the tablet. As the tablet printing device, an inkjet tablet printing device, which performs printing on a tablet in a noncontact manner, has been developed due to the ease of changing letters, characters or marks, high print quality, and the like. The inkjet tablet printing device ejects ink (e.g., edible ink) toward a tablet being conveyed by a conveyor belt or the like to print identification information on the surface of the tablet.
There are various types of tablets as a tablet to be printed. The various types of tablets include those having front and back sides. Examples of the tablets having the front and back sides include a tablet with a split line for dividing the tablet on one side. In this tablet, generally, a surface with a split line is regarded as the front side, and a surface without a split line is regarded as the back side. Identification information may be printed on the surface with a split line. Therefore, it is desirable to supply tablets on the conveyor belt with the front side (the surface with a split line) thereof facing up.
[Patent Document 1] Japanese Unexamined Patent Application Publication No. Hei7-81050
However, other process of aligning the front and back sides of the tablets is required so as to supply the tablets onto the conveyor belt with their front side facing up, leading to a decrease in the productivity and an increase in the cost. For this reason, tablets may be supplied onto the conveyor belt without aligning the front and back sides of the tablets. In this case, in order to print identification information on the front surfaces of the tablets, it is necessary to determine whether the upper surface of each tablet on the conveyor belt is the front surface, i.e., whether there is a split line on the upper surface of each tablet on the conveyor belt. A camera may be used to photograph the upper surface of the tablet on the conveyor belt to determine the presence or absence of a split line based on the image.
However, in the case of using a camera as described above, illumination is required for illuminating the upper surface of each tablet on the conveyor belt in addition to the camera for photographing the upper surface of the tablet. This causes the complication of the device and increase of the device cost. Besides, this requires image processing for determining the presence or absence of a split line based on an image captured by the camera, and the speed of determining the front/back of the tablet is delayed at least for the time taken for the image processing.
An object of the present invention is to provide a tablet printing device and a tablet printing method capable of realizing the simplification of the device, the reduction of the device cost, and an improvement in the speed of determining the front/back of tablets.
According to one embodiment, a tablet printing device includes: a conveyer configured to convey a tablet; a laser displacement meter configured to emit laser beams to the tablet conveyed by the conveyer and receive the laser beams reflected by the tablet; a determination unit configured to determine whether there is a split line on the upper surface of the tablet conveyed by the conveyer based on an output value of the laser displacement meter; and a printing unit configured to perform printing on the tablet conveyed by the conveyer based on a determination result obtained by the determination unit.
According to another embodiment, a tablet printing method includes: a first step in which a laser displacement meter emits laser beams to a tablet conveyed and receives the laser beams reflected by the tablet; a second step of determining whether there is a split line on the upper surface of the tablet conveyed based on an output value of the laser displacement meter; and a third step of performing printing on the tablet conveyed based on a determination result.
According to the embodiments, it is possible to realize the simplification of the device, the reduction of the device cost, and an improvement in the speed of determining the front/back of tablets.
A first embodiment will be described with reference to
As illustrated in
The conveyor 10 includes a plurality of conveyor belts 11, a first pulley 12, a second pulley 13, and a motor 14. The conveyor belts 11 are each formed to be endless and are wrapped around the first pulley 12 and the second pulley 13 in parallel. The first pulley 12 is connected to the motor 14 serving as a drive source, and functions as a drive pulley. The second pulley 13 functions as a driven pulley. The motor 14 is electrically connected to the control unit 80, and is driven under the control of the control unit 80.
In the conveyor 10, each of the conveyor belts 11 rotates with the second pulley 13 due to the rotation of the first pulley 12 by the motor 14, and conveys the tablets T thereon in the direction indicated by arrow A1 in
The supply unit 20 is located at the end of the conveyor 10, i.e., at the end of each of the conveyor belts 11 on the upstream side in the conveyance direction A1. The supply unit 20 is configured to be capable of containing a number of tablets T and supplying the tablets T to each of the conveyor belts 11 one by one at predetermined intervals. The supply unit 20 supplies the tablets T to the conveyor belts 11 regardless of the front and back sides of the tablets T. In the tablet T, a surface with a split line (e.g., groove) is the front side and a surface without a split line is the back side. The supply unit 20 is electrically connected to the control unit 80, and is driven under the control of the control unit 80.
The laser displacement meters 30 are located on the downstream side of the supply unit 20 in the conveyance direction A1. There are provided two laser displacement meters 30 above each of the conveyor belts 11. The two laser displacement meters 30 corresponding the conveyor belt 11 are arranged at a position where they can irradiate laser beams onto the upper surface of the tablet T conveyed by the conveyor belt 11, and are arranged in a direction intersecting (e.g., perpendicular to) the conveyance direction A1 in a horizontal plane. For example, various laser sensors such as reflection laser sensors can be used as the laser displacement meters 30. Examples of the shape of the laser beams include various shapes such as spot and line.
Each of the laser displacement meters 30 irradiates laser beams toward the tablet T on the conveyor belt 11, receives the laser beams reflected from the tablet T (reflected light), and sends the reflection intensity of the laser beams to the control unit 80 as an output value. The reflection intensity of the laser beams is information indicating the distance between the surface of the conveyor belt 11 or the upper surface of the tablet T on the conveyor belt 11 and the laser displacement meter 30. The output value is higher as the distance becomes shorter. In addition, the laser displacement meter 30 detects the presence or absence of the tablet T on the conveyor belt 11 by irradiating and receiving laser beams, thereby also functioning as a trigger sensor for the imaging unit 40 and the printing unit 50. Each of the laser displacement meters 30 is electrically connected to the control unit 80, and sends information on the reflection intensity of laser beams and a trigger signal to the control unit 80.
The imaging units 40 are located on the downstream side of the laser displacement meters 30 in the conveyance direction A1. There is provided one imaging unit 40 above each of the conveyor belts 11. The imaging units 40 are arranged in a direction intersecting (e.g., perpendicular to) the conveyance direction A1 in a horizontal plane. The imaging unit 40 performs imaging at the timing based on a trigger signal sent from the laser displacement meter 30, captures an image including the upper surface of the tablet T, and sends the image to the control unit 80. For example, various imaging units having an imaging element such as a charge-coupled device (CCD) or a complementary metal-oxide semiconductor (CMOS) can be used as the imaging units 40. Each of the imaging units 40 is electrically connected to the control unit 80, and is driven under the control of the control unit 80.
The printing unit 50 is an inkjet print head that ejects ink from a plurality of nozzles 51. The printing unit 50 is located on the downstream side of the imaging units 40 in the conveyance direction A1. The printing unit 50 is arranged above each of the conveyor belts 11 such that the arranging direction of the nozzles 51 are aligned in a direction intersecting (e.g., perpendicular to) the conveyance direction A1 in a horizontal plane. The printing unit 50 is configured to be capable of applying ink to the tablets T on each of the conveyor belts 11. Examples of the printing unit 50 include various types of inkjet print heads having a driving element such as a piezoelectric element, a heat generating element or a magnetostrictive element. The printing unit 50 is electrically connected to the control unit 80, and is driven under the control of the control unit 80.
The drying unit 60 is located on the downstream side of the printing unit 50 in the conveyance direction A1. The drying unit 60 is provided above each of the conveyor belts 11 so as to intersect with (e.g., be perpendicular to) the conveyance direction A1 in a horizontal plane. The drying unit 60 is configured to be capable of drying the ink applied to each of the tablets T on each of the conveyor belts 11. Examples of the drying unit 60 include various types of dryers such as a heater for drying an object to be dried by radiant heat or a blower for drying an object to be dried with warm air or hot air. The drying unit 60 is electrically connected to the control unit 80, and is driven under the control of the control unit 80.
The collecting unit 70 is located on the downstream side of the drying unit 60 in the conveyance direction A1. The collecting unit 70 is provided at the end of the conveyor 10, i.e., at the end of each of the conveyor belts 11 on the downstream side in the conveyance direction A1. The collecting unit 70 is configured to be capable of sequentially receiving the tablets T dropped as each of the conveyor belts 11 releases the holding thereof, and collect the tablets T. When each of the tablets T on each of the conveyor belts 11 reaches a desired position, e.g., the end of the conveyor belt 11 on the downstream side in the conveyance direction A1, the conveyor 10 releases the holding of the tablet T.
The tablets T are supplied onto each of the conveyor belts 11 regardless of the front and back sides thereof, and the printing unit 50 performs printing only when the tablet T faces up (the surface with a split line faces up). For this reason, printed tablets T and unprinted tablets T are present on each of the conveyor belts 11 on the downstream side of the printing unit 50. Therefore, the collecting unit 70 is configured to be capable of distinguishing between printed tablets T and unprinted tablets T and storing them. For example, the collecting unit 70 lets the printed tablets T drop and stores them in a first container in the collecting unit 70, while it blows air to the unprinted tablets T being dropped and stores them in a second container in the collecting unit 70.
The control unit 80 includes a microcomputer that intensively controls each unit and a storage unit that stores processing information, various programs and the like (both not illustrated). The control unit 80 controls the supply unit 20, the imaging units 40, the printing unit 50, and the drying unit 60 based on the processing information and the various programs. Further, the control unit 80 receives the reflection intensity of laser beams sent from each of the laser displacement meters 30, i.e., the reflection intensity information of the laser beams, images sent from the imaging units 40, and the like.
The control unit 80 includes a determination unit 81 that determines whether there is a split line on the upper surface of the tablet T. The determination unit 81 determines the presence or absence of a split line on the upper surface of the tablet T based on the reflection intensity information of each laser beam sent from each of the laser displacement meters 30. Hereinafter, for the sake of convenience, when it is required to distinguish the two laser displacement meters 30 corresponding to one conveyor belt 11, one of them is referred to as a first laser displacement meter 30, and the other is referred to as a second laser displacement meter 30.
As illustrated in
The output (reflection intensity of laser beams) B1 of the first laser displacement meter 30 varies according to the distance between the first laser displacement meter 30 and the surface of the conveyor belt 11 or the upper surface of the tablet T on the conveyor belt 11. For example, the output B1 becomes reflection intensity b1 when the tablet T is not present on the conveyor belt 11, i.e., when the laser spot S1 hits the surface of the conveyor belt 11. The output B1 becomes reflection intensity b2 when the laser spot S1 hits the upper surface in a split line (e.g., groove) of the tablet T on the conveyor belt 11. The output B1 becomes reflection intensity b3 when the laser spot S1 hits the upper surface other than the split line of the tablet T on the conveyor belt 11 (b1<b2<b3). Since the output B1 varies according to the change in the height of the tablet T on the conveyor belt 11, in other words, the first laser displacement meter 30 detects the height of the tablet T on the conveyor belt 11. Note that the output B2 of the second laser displacement meter 30 also varies in the same manner as described above except that the laser spot S1 is replaced by the laser spot S2.
The determination unit 81 determines whether there is a split line on the upper surface of the tablet T on the conveyor belt 11 based on the output B1 of the first laser displacement meter 30 and the output B2 of the second laser displacement meter 30. For example, when either one or both of the output B1 and the output B2 is the reflection intensity b2, the determination unit 81 determines that there is a split line on the upper surface of the tablet T on the conveyor belt 11. Otherwise, the determination unit 81 determines that there is no split line on the upper surface of the tablet T on the conveyor belt 11. As another determination example, a predetermined value between the reflection intensity b1 and the reflection intensity b2 may be set as a first threshold value, and a predetermined value between the reflection intensity b2 and the reflection intensity b3 may be set as a second threshold value. In this case, when either or both of the output B1 and the output B2 is larger than the first threshold value and smaller than the second threshold value, the determination unit 81 determines that there is a split line on the upper surface of the tablet T on the conveyor belt 11. Otherwise, the determination unit 81 determines that there is no split line on the upper surface of the tablet T on the conveyor belt 11.
Further, the determination unit 81 acquires information on the orientation of the tablet T (e.g., inclination of the split line of the tablet T in a horizontal plane) based on the output B1 of the first laser displacement meter 30 and the output B2 of the second laser displacement meter 30. For example, the determination unit 81 determines the inclination degree of the split line of the tablet T with respect to the conveyance direction A1, i.e., the orientation (angle and rotation direction) of the split line based on the waveform shapes of the output B1 and the output B2. The orientation of the split line of the tablet T is determined as follows: For example, when the second tablet T from the left in
Described next is a printing step (printing process) performed by the tablet printing device 1.
Each of the conveyor belts 11 of the conveyor 10 rotates in the conveyance direction A1 due to the rotation of the first pulley 12 and the second pulley 13 caused by the motor 14. The supply unit 20 sequentially supplies the tablets T onto each of the conveyor belts 11 at predetermined intervals while the conveyor belts 11 are rotating. As a result, the tablets T are conveyed in almost a line on each of the conveyor belts 11.
Each of the laser displacement meters 30 detects the arrival of each tablet T on each of the conveyor belts 11. Each of the laser displacement meters 30 also detects the height of each tablet T (first step). At this time, each of the laser displacement meters 30 acquires the reflection intensity information of laser beams, and sends it to the control unit 80. The determination unit 81 determines whether there is a split line on the upper surface of the tablet T on each of the conveyor belts 11 based on the reflection intensity information of the laser beams acquired by each of the laser displacement meters 30. When there is a split line on the tablet T, the determination unit 81 further determines the orientation (angle and rotation direction) of the split line (second step). When the determination unit 81 determines that there is a split line on the upper surface of the tablet T (the upper surface is the front), printing on the tablet T is permitted. On the other hand, when it is determined that there is no split line on the tablet T (the upper surface is the back), printing on the tablet T is prohibited. The orientation information indicating the orientation of the split line determined by the determination unit 81 is used for the printing process performed by the control unit 80.
Thereafter, each tablet T on each of the conveyor belts 11 is photographed by the imaging units 40 in each of the conveyor belts 11. The imaging unit 40 photographs the upper surface of each tablet T at the timing based on a trigger signal sent from the laser displacement meter 30, and sends the image captured to the control unit 80. The control unit 80 generates position information of the tablet T (e.g., the position of the tablet T in a horizontal plane) based on individual images sent from the imaging units 40. Since it is not necessary to capture an image of the tablet T on which printing is prohibited, the control unit 80 performs appropriately control of skipping the photographing for the tablet T on which printing is prohibited. However, when the image of the tablet T on which printing is prohibited is used in another process, the tablet T on which printing is prohibited may be photographed.
The printing unit 50 performs printing on each tablet T on each of the conveyor belts 11 based on the orientation information and the position information of the tablet T described above at the timing based on a trigger signal sent from the laser displacement meters 30 for each of the conveyor belts 11 (third step). Ink is appropriately ejected from each of the nozzles 51 of the printing unit 50 to print identification information, such as a letter or a character, a mark, or the like, on the upper surface of the tablet T so as to avoid the split line or along the split line. The control unit 80 performs appropriately control of skipping the printing on the tablet T on which printing is prohibited. In this manner, the printing unit 50 performs printing on the tablets T on each of the conveyor belts 11 based on the determination result (result of the determination as to the presence or absence of a split line and the orientation) obtained by the determination unit 81 and the position information of the tablets T.
The drying unit 60 dries the ink applied to each tablet T on each of the conveyor belts 11 while the tablet T is passing under the drying unit 60. When the tablet T with ink dried arrives at the downstream end of each of the conveyor belts 11, it is released from the state of being held by each of the conveyor belts 11. The tablet T drops from each of the conveyor belts 11 and is collected by the collecting unit 70. For example, the printed tablet T drops as it is and is stored in the first container in the collection unit 70, and the unprinted tablet T is blown by air while dropping and collected in the second container in the collection unit 70.
In such a printing process, the determination unit 81 determines the presence or absence of a split line on the upper surface of the tablet T, i.e., determines the front/back of the tablet T, based on the reflection intensity information of laser beams acquired by the laser displacement meters 30. Thus, the front/back of the tablet T can be determined from the reflection intensity information of laser beams without the need of special processing such as image processing, etc. In the case where a new camera is provided in place of the laser displacement meters 30 to determine the front/back of the tablet T, illumination is also required in addition to the camera. This causes the complication of the device and increase of the device cost. Although the imaging units 40 may be used without newly providing a camera, this requires image processing for determining the front/back of the tablet T. As a result, the speed of determining the front/back of the tablet T is delayed by the time taken for the image processing. By using the laser displacement meters 30 to determine the front/back of the tablet T, it is possible to improve the speed of determining the front/back of the tablet T as well as to achieve the simplification of the device and the reduction of the device cost.
Moreover, orientation information of the tablet T, i.e., the orientation (angle and rotation direction) of the tablet T can be acquired by using each of the laser displacement meters 30. This eliminates the need of image processing for acquiring the orientation of the tablet T from images captured by the imaging units 40, resulting in an improvement in the printing speed. Specifically, the angle of a split line with respect to the conveyance direction A1 can be detected from the width of the reflection intensity b3 and the width of the reflection intensity b2 at the output B1 of the laser displacement meter 30. However, the rotation direction of the split line (e.g., if the angle is 10°, whether it is +10° or −10°) cannot be determined from the output B1 of the laser displacement meter 30. By the combination of the outputs B1 and B2 of the laser displacement meters 30, it is possible to determine the rotation direction of the split line. Thus, the presence or absence of a split line on the tablet T and the orientation (angle and rotation direction) of the split line can be detected at high speed with only the two laser displacement meters 30.
As described above, according to the first embodiment, each of the laser displacement meters 30 irradiates laser beams toward the tablet T on the conveyor 10, and receives the laser beams reflected from the tablet T. Thereafter, the determination unit 81 determines whether there is a split line on the upper surface of the tablet T on the conveyor 10 based on the reflection intensity of the laser beams received. This enables a determination as to the front/back of the tablet T based on the reflection intensity information of the laser beams. Accordingly, there is no need of a camera, illumination, and image processing. Thus, it is possible to realize the simplification of the device, the reduction of the device cost, and an improvement in the speed of determining the front/back of tablets.
The laser displacement meters 30 are arranged so as to irradiate laser beams to the upper surface of the tablet T on the conveyor 10. The laser displacement meters 30 are arranged in a direction intersecting (e.g., perpendicular to) the conveyance direction A1 of the tablet T in a horizontal plane. This makes it possible to reliably determine the presence or absence of a split line on the upper surface of the tablet T as compared to the case of determining it by one laser displacement meter 30. Thus, the accuracy of determination as to the front/back of the tablet T can be improved. Further, since it is possible to detect the rotation direction as well as the angle of a split line of the tablet T, the orientation (angle and rotation direction) of the split line can be determined.
In the above description, the position information of the tablet T is obtained from images captured by the imaging units 40; however, it is not so limited. For example, the position of the tablet T on the conveyor belts 11 can be obtained by using each of the laser displacement meters 30. For example, as the center tablet T illustrated in
While two laser displacement meters 30 are provided for each of the conveyor belts 11, it is not so limited. For example, one laser displacement meter may be provided for each of the conveyor belts 11. As described above, the tablets T are conveyed in a line with their center located substantially on a predetermined line. Therefore, even with only the laser spot S1 in
When one laser displacement meter 30 is provided for each of the conveyor belts 11, as illustrated in
A second embodiment will be described with reference to
As illustrated in
Further, as illustrated in
As illustrated in
The determination unit 81 determines whether there is a split line on the upper surface of the tablet T on the conveyor belt 11 based on the output B3 of the laser displacement meter 30. For example, when the waveform shape of the output B3 is different from a predetermined waveform shape (the output B3 rises or falls smoothly as illustrated at the right end in
Besides, the determination unit 81 acquires the position information of the tablet T (e.g., the position of the tablet T in a horizontal plane) and the orientation information (e.g., the inclination of the split line of the tablet T in a horizontal plane) based on the output B3 of the laser displacement meter 30. For example, the determination unit 81 determines the position of the tablet T on the conveyor belt 11 from the separation distance between the tablet T on the conveyor belt 11 and the laser displacement meter 30 based on the waveform shape of the output B3. Further, the determination unit 81 determines the inclination angle of the split line of the tablet T with respect to the conveyance direction A1, i.e., the orientation (angle and rotation direction) of the split line, based on the waveform shape of the output B3. The orientation of the split line is determined in the same manner as described in the first embodiment. That is, the relationship between the waveform shapes of the output B3 and the orientation of the split line is obtained beforehand and stored in the determination unit 81. The determination unit 81 compares the waveform shape of the actual output B with the data stored to make a determination. The position information and the orientation information are used for the printing process performed by the control unit 80.
Even in the case where the direction in which the split line of the tablet T extends is perpendicular to the direction of laser beams irradiated from the laser displacement meter 30 (see the leftmost tablet T in
In this manner, the orientation information and the position information of the tablet T can be acquired by using the laser displacement meter 30. This eliminates the need of the imaging units 40, resulting in further simplification of the device and reduction of the device cost. Further, it is possible to omit image processing for acquiring the orientation information and the position information of the tablet T from images captured by the imaging units 40, resulting in an improvement in the printing speed.
As described above, according to the second embodiment, the same effects as those of the first embodiment can be achieved. Further, it is possible to acquire the orientation information and the position information of the tablet T using the laser displacement meter 30. This eliminates the need of the imaging units 40. As a result, it is possible to realize further simplification of the device, reduction of the device cost, and an improvement in the printing speed. In addition, only one laser displacement meter 30 is provided for each of the conveyor belts 11, and the number of the laser displacement meters 30 can be reduced. Thereby, the simplification of the device and the reduction of the device cost can be realized more reliably.
Although the laser displacement meter 30 is arranged so as to irradiate laser beams to the upper part of the side surface of the tablet T on the conveyor belt 11, it is not so limited. The laser displacement meter 30 may be arranged so as to irradiate laser beams to the lower part of the side surface of the tablet T on the conveyor belt 11. In this case, it is determined whether there is a split line on the lower surface of the tablet T. When there is a split line on the lower surface of the tablet T, it is determined that there is no split line on the upper surface of the tablet T. When there is no split line on the lower surface of the tablet T, it is determined that there is a split line on the upper surface of the tablet T. In this manner, it is possible to determine the presence or absence of a split line on the upper surface of the tablet T indirectly.
A third embodiment will be described with reference to
As illustrated in
As described above, according to the third embodiment, the same effects as those of the second embodiment can be achieved. Further, it is possible to directly detect the presence or absence of a split line on both the front and back surfaces of the tablet T, thereby improving the accuracy of determining the front/back of the tablet T. In addition, it is possible to acquire orientation information relating to the inclination of the split line on the lower surface of the tablet T by using the lower laser displacement meter 30.
There is a case where printing is performed on a surface having no split line except a surface having a split line. In this case, for example, printing may be performed on the surface with no split line along the split line on the opposite surface or so as to avoid a position corresponding to the split line on the opposite surface. For this reason, orientation information relating to the orientation of the split line on the lower surface of the tablet T is required. The orientation information can be acquired by the lower laser displacement meter 30. Thereby, printing can be performed on the surface with no split line along the split line on the opposite surface or so as to avoid a position corresponding to the split line on the opposite surface based on the orientation information.
A fourth embodiment will be described with reference to
As illustrated in
As described above, according to the fourth embodiment, the same effects as those of the second embodiment can be achieved. Further, it is possible to directly detect the presence or absence of a split line on both the front and back surfaces of the tablet T, thereby improving the accuracy of determining the front/back of the tablet T. In addition, it is possible to acquire orientation information relating to the orientation of the split line on the lower surface of the tablet T by using the lower laser displacement meter 30. The orientation of the split line on the lower surface of the tablet T can be obtained in the same manner as described in the second embodiment. Thus, as in the third embodiment, printing can be performed on the surface with no split line along the split line on the opposite surface or so as to avoid a position corresponding to the split line on the opposite surface based on the orientation information.
As the laser displacement meter 30 for irradiating laser beams to the full width of the side surface of the tablet T on the conveyor belt 11 in a direction intersecting the conveyance direction A1, any laser displacement meter may be used as long as it can irradiate laser beams to the full width of the side surface of the tablet T in a direction intersecting the conveyance direction A1. For example, various laser displacement meters such as the one that irradiates elongated line-shaped laser beams may be used instead of the above-described laser displacement meter that scans laser beams.
A fifth embodiment will be described with reference to
As illustrated in
As described above, according to the fifth embodiment, the same effects as those of the second embodiment can be achieved. Further, it is possible to detect the whole circumferential shape of the upper part of the tablet T. This makes it possible to reliably determine the presence or absence of a split line on the upper surface of the tablet T. As a result, the accuracy of determining the front/back of the tablet T can be improved. In addition, orientation information and position information of the tablet T can be obtained more accurately. Thus, the printing accuracy can be improved.
In the above embodiments, the two conveyor belts 11 are used, i.e., there are two conveying lanes; however, it is not so limited. For example, there may be one lane, three lanes, or four lanes. The number of conveying lanes is not particularly limited.
In the above embodiments, one print head is used as the printing unit 50; however, it is not so limited. For example, a plurality of print heads may be used. The number of print heads is not particularly limited. Besides, although a print head having a line of the nozzles 51 has been described as an example of the inkjet print head, it is not so limited. For example, a print head having a plurality of lines of the nozzles 51 may be used.
In the above embodiments, various arrangements of the laser displacement meters 30 are exemplified. However, the arrangement is not limited thereto, and the arrangements of the laser displacement meters 30 according to the first to fifth embodiments may be combined as appropriate. For example, any one of the second to fifth embodiments may be combined with the first embodiment, or either or both of the third and fourth embodiments may be combined with the fifth embodiment.
In the second to fifth embodiments, the laser displacement meter 30 is described as being arranged so as to emit laser beams toward the upstream side in the conveyance direction A1; however, it is not so limited. The laser displacement meter 30 may be arranged so as to emit laser beams toward the downstream side in the conveyance direction A1. When there are two laser displacement meters 30, one of them may be arranged so as to emit laser beams toward the upstream side in the conveyance direction A1 and the other may be arranged so as to emit laser beams toward the downstream side in the conveyance direction A1. Alternatively, both of them may be arranged so as to emit laser beams toward the downstream side in the conveyance direction A1.
In the above embodiments, a set including the conveyor 10, the laser displacement meters 30, the imaging units 40, the printing unit 50, and the drying unit 60 performs printing on the upper surface of the tablet T; however, it is not so limited. For example, there may be provided two sets of them to perform printing on both sides of the tablet T. In this case, as an example, a second conveyor 10 is arranged below a first conveyor 10. The second conveyor 10 is configured to be capable of receiving the tablet T from the first conveyor 10. For example, when the tablet T conveyed by the first conveyor 10 reaches a predetermined position under the first conveyor 10, the tablet T is released from the state of being held by the first conveyor 10 and drops. The tablet T is received by the second conveyor 10 located thereunder. On this occasion, both the tablet T having printing on its front surface and the tablet T having no printing are delivered from the first conveyor 10 to the second conveyor 10. At this time, the tablets T are reversed, and the printed front surface faces down, while the unprinted back surface faces up. The printing unit 50 on the side of the first conveyor 10 performs printing on the surface of the tablet T facing up.
For example, when information obtained by the imaging unit 40 on the side of the first conveyor 10 can be used in printing on the side of the second conveyor 10, the imaging unit 40 on the side of the second conveyor 10 is not required. Besides, for example, on the side of the second conveyor 10, only one of the laser displacement meters 30 and the imaging unit 40 may suffice. In addition, when both the front and back split lines can be detected on the side of the first conveyor 10, the detection result may be used on the side of the second conveyor 10. Further, printing may be performed on the back surface correspondingly to the orientation of the split line on the printed front surface.
The output of the laser displacement meter 30 is described as being based on the reflection intensity (received light amount); however, it is not so limited. The output of the laser displacement meter 30 may be based on the time from when laser beams are irradiated until when the laser beams reflected on the surface of the tablet T are received by the laser displacement meter.
The above-described tablets may include tablets for pharmaceutical use, edible use, cleaning, industrial use, and aromatic use. Examples of the tablet include a plain tablet (uncoated tablet), a sugar-coated tablet, a film-coated tablet, an enteric coated tablet, a gelatin coated tablet, a multilayered tablet, a dry-coated tablet, and the like. Examples of the tablet further include various capsule tablets such as hard capsules and soft capsules. The tablets may be in a variety of shapes such as, for example, a disk shape, a lens shape, a triangle shape, an oval shape, and the like.
In the case where tablets to be printed are for pharmaceutical use and edible use, edible ink is suitably used. Specifically, edible pigments such as Amaranth, Erythrosine, New Coccine (red), Tartrazine, Sunset Yellow FCF, β-Carotene, Crocin (yellow), Brilliant Blue FCF, Indigo Carmine (blue), or the like are dispersed or dissolved in a vehicle, and, if necessary, a pigment dispersant (surfactant) is blended therein, the resultant of which can be used. As the edible ink, any of synthetic dye ink, natural color ink, dye ink, and pigment ink may be used.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; further, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2015-114818 | Jun 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/064007 | 5/11/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/194565 | 12/8/2016 | WO | A |
Number | Name | Date | Kind |
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20150174916 | Hara et al. | Jun 2015 | A1 |
20150191028 | Hara et al. | Jul 2015 | A1 |
20160180515 | Seo et al. | Jun 2016 | A1 |
Number | Date | Country |
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7-81050 | Mar 1995 | JP |
2002-39957 | Feb 2002 | JP |
2004-219119 | Aug 2004 | JP |
2013-121432 | Jun 2013 | JP |
2014013974 | Jan 2014 | JP |
WO 0110464 | Feb 2001 | WO |
2015008742 | Jan 2015 | WO |
Entry |
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International Search Report dated Aug. 2, 2016, in PCT/JP2016/064007, filed May 11, 2016. |
Number | Date | Country | |
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20180170068 A1 | Jun 2018 | US |