The present invention relates to a scanning apparatus and an image forming apparatus, and relates to the start-up control of the scanning apparatus used in the image forming apparatus, such as an electrophotography printer that performs image exposure by a laser beam.
Conventionally, as disclosed in, for example, the specification of U.S. Pat. No. 5,864,355, the technology is proposed that restricts an emission permission area for laser to a non-image area of the entire scan area at the time of start-up of a scanning apparatus that forms a latent image by emitting laser light on a photosensitive member. Additionally, as disclosed in, for example, Japanese Patent Application Laid-Open No. H08-183198, the technology is proposed that controls the rotation speed of a rotary polygon mirror of a scanning apparatus by using a horizontal synchronization signal period.
An aspect of the present invention is to provide a scanning apparatus in which the start-up time is reduced.
Another aspect of the present invention is to provide a scanning apparatus that is started up while laser light is emitted only in an area where a horizontal synchronization signal is generated.
A further aspect of the present invention is to provide a scanning apparatus including a light source configured to emit laser light for forming an electrostatic latent image according to image data onto a photosensitive member, a rotary polygon mirror configured to scan the laser light emitted from the light source by rotation, an output unit arranged in a second area except for a first area corresponding to an area in which the electrostatic latent image is formed in an area to which the laser light is scanned, the output unit being configured to output a signal in response to emission of the laser light, and a control unit configured to perform intermittent emission control in which the light source emits a laser light in the area in which the laser light is emitted to the output unit, based on a cycle of the signal output by the output unit, wherein the control unit switches the intermittent emission control based on the signal by a time the rotary polygon mirror reaches a target rotation speed.
A still further aspect of the present invention is to provide an image forming apparatus including a scanning apparatus, a photosensitive member on which an electrostatic latent image is formed by scanning laser light by the scanning apparatus, a developing unit configured to develop the electrostatic latent image formed on the photosensitive member with a toner, and to form a toner image, and a transfer unit configured to transfer the toner image formed by the developing unit to a recording material, the scanning apparatus including a light source configured to emit the laser light for forming the electrostatic latent image according to image data onto the photosensitive member, a rotary polygon mirror configured to scan the laser light emitted from the light source by rotation, an output unit arranged in a second area except for a first area corresponding to an area in which the electrostatic latent image is formed in an area to which the laser light is scanned, the output unit being configured to output a signal in response to emission of the laser light, and a control unit configured to perform intermittent emission control in which the light source emits a laser light in the area in which the laser light is emitted to the output unit, based on a cycle of the signal output by the output unit, wherein the control unit switches the intermittent emission control based on the signal by a time the rotary polygon mirror reaches a target rotation speed.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Preferred embodiments of the present invention will now be described in detail in accordance with the accompanying drawings.
Referring to the drawings, modes for carrying out the present invention are exemplarily described below in detail based on examples. However, the sizes, materials and shapes of components described in the embodiments and their relative arrangements should be properly modified according to the configuration of an apparatus to which the invention is applied and according to various conditions. That is, the present invention is not intended to be limited to the following embodiments.
(Configuration of Image Forming Apparatus)
As an example of an image forming apparatus, a laser beam printer is described as an example.
(Configuration of Laser Scanner Unit)
Note that, hereinafter, the horizontal synchronization signal 107 is expressed as a beam detection signal (hereinafter, the BD signal) 107, and the interval between the BD signals 107 is expressed as a “BD cycle” as the cycle of the BD signal. Additionally, the BD signal 107 is used as a reference signal for starting scanning in the main scanning direction, and is used as a writing starting position in the main scanning direction. A CPU 110 is an example of a control device, and every time the BD signal 107 is generated, updates the BD cycle and stores the BD cycle in a storing unit 117. The CPU 110 has a timer function, and is configured to calculate the time period after the BD signal 107 is detected until the next BD signal 107 is detected as the BD cycle. Additionally, the CPU 110 has a speed control function for converging a scanner motor 103 to a target rotation frequency (corresponding to a target rotation speed), based on a current BD cycle that is read from the storing unit 117. The CPU 110 controls the scanner motor 103 by a scanner motor driving signal 108 with the speed control function.
A laser drive circuit 113 adjusts the amount of light used as the reference for the laser light emitted during image formation, based on a detection result of a monitor element (not shown), such as a photodiode (PD) that receives the laser light emitted from the semiconductor laser 101. The laser drive circuit 113 adjusts the amount of light of the semiconductor laser 101 in the non-image area of the scan area of the laser light, and functions as an adjustment device. Additionally, the laser drive circuit 113 also performs control of turning on or turning off the semiconductor laser 101 according to the image data for performing image formation. The CPU 110 has a function of performing emission control of the semiconductor laser 101 by using a laser driving signal 109 via the laser drive circuit 113, based on the current BD cycle stored in the storing unit 117.
(Description of the Operation for Performing Start-Up from the State where the Scanner Motor 103 is Stopped)
Using
First, when the printer 300 receives a print instruction, the CPU 110 starts the start-up of the scanning apparatus 111 (start-up is started). The CPU 110 performs speed-up control by giving a speed-up instruction during a time period T1 until a time t1 to the scanner motor 103, by using the scanner motor driving signal 108 at a predetermined timing from the print instruction. After the time t1, continuous emission control is performed on the semiconductor laser 101 by the laser driving signal 109. Accordingly, the BD signal 107 is generated at the timing at which the laser light is input to the horizontal synchronization sensor 106, and the CPU 110 obtains the BD signal 107. Hereinafter, obtaining the BD signal 107 by the CPU 110 is referred to as detecting the BD signal 107. After the time t1, the BD cycle generated by the horizontal synchronization sensor 106 becomes short due to the speed-up of the scanner motor 103 (see T1 to T2 of
Subsequently, the intermittent emission control is described. In the period from the time t2 to a time t3 illustrated in
Time until emission end=the BD cycle at the last scan×K1 Formula (1)
Time until emission start=the BD cycle at the last scan×K2 Formula (2)
Next, after a time t3 in
Time until emission end=the BD cycle at the last scan×K3 Formula (3)
Time until emission start=the BD cycle at the last scan×K4 Formula (4)
Here, K3 and K4 are coefficients, and in Example 1, it is assumed that K3:0.011 (a third coefficient), and K4:0.97 (a fourth coefficient).
In Example 1, by making the coefficient K2<the coefficient K4 as described above, in the early stage of start-up of the scanner motor 103 in which the change in the BD cycle is large, the semiconductor laser 101 is controlled to be turned on with respect to a generation area of the BD signal 107 at an early timing. Accordingly, in the early stage of start-up of the scanner motor 103, emission to the horizontal synchronization sensor 106 can be positively performed. Additionally, by making the coefficient K1<coefficient K3, in the early stage of start-up of the scanner motor 103, after obtaining the BD signal 107, the semiconductor laser 101 is controlled to be turned off at an early timing. Accordingly, in the early stage of start-up of the scanner motor 103, the laser emission in the image area can be avoided. Further, switching of the calculation formulas may be performed multiple times during the start-up of the scanner motor 103. Additionally, the average value of the BD cycles obtained multiple times may be used as the threshold value. Further, although the coefficient K1 and the coefficient K3 are set to be different values, the coefficient K1 and the coefficient K3 may be the same value. That is, when the BD signal 107 is able to be detected irrespective of the rotation speed of the scanner motor 103, the semiconductor laser 101 may be controlled to be turned off quickly. For example, each of the coefficient K1 and the coefficient K3 may be set to 0.004.
(Description of the Operation of Restarting Up the Scanner Motor 103)
Using
First, when the printer 300 receives the print instruction, the CPU 110 starts the restart-up of the scanning apparatus 111 (restart-up). The CPU 110 performs speed-up control by giving a speed-up instruction to the scanner motor 103 by using the scanner motor driving signal 108 at a predetermined timing from the print instruction. The CPU 110 performs continuous emission control of the semiconductor laser 101 with the laser driving signal 109, together with the speed-up control of the scanner motor 103, and obtains the BD signal 107. In Example 1, as illustrated in
Subsequently, a description about the intermittent emission control is added. In the period from the time t8 to a time t9 illustrated in
Next, after the time t9 in
In this manner, even at the time of restart-up of the scanner motor 103, by switching the calculation formula for computing the emission timing of the semiconductor laser 101 according to the BD cycle, the emission to the horizontal synchronization sensor 106 is positively enabled. Note that, as for the coefficients K1 to K4, different values may be used for a case where the scanner motor 103 is restarted up, and a case where the scanner motor 103 is started up from a state where the scanner motor 103 is stopped.
(Description of Flowchart)
Next, using the flowchart of
When printing is instructed, the CPU 110 starts the processing after step (hereinafter referred to as S) 601. At S601, the CPU 110 starts speed-up of the scanner motor 103 with the scanner motor driving signal 108. At S602, the CPU 110 determines whether or not a time period has elapsed during which it is estimated that the scanner motor 103 is completely stopped after outputting the scanner motor driving signal 108 for stopping the scanner motor 103, by referring to the timer. In other words, the CPU 110 determines whether or not the scanner motor 103 is in a state where the scanner motor 103 is stopped (stop condition). It is assumed that the time period during which it is estimated that the scanner motor 103 is completely stopped after outputting the scanner motor driving signal 108 for stopping the scanner motor 103 is calculated in advance by, for example, an experiment, and is stored in the storing unit 117.
At S602, when the CPU 110 determines that the time period during which it is estimated that the scanner motor 103 is completely stopped has elapsed, that is, determines that the scanner motor 103 is stopped, the processing proceeds to S603. At S603, the CPU 110 determines whether or not the predetermined time period T1 (predetermined time period) has elapsed since starting the start-up of the scanner motor 103. At S603, when the CPU 110 determines that the predetermined time period T1 has elapsed, the processing proceeds to S604. At S603, when the CPU 110 determines that the predetermined time period T1 has not elapsed, the processing returns to S603. At S602, when the CPU 110 determines that the scanner motor 103 is not in the stop condition, that is, the scanner motor 103 is restarted up when still rotating, the processing proceeds to S604. At S604, the CPU 110 performs the continuous emission control of the semiconductor laser 101. The CPU 110 resets a counter (not shown) that counts the number of times the BD signal 107 is detected, and counts up the counter every time the BD signal 107 is detected.
At S605, the CPU 110 determines whether or not the BD signal 107 is detected three times, by referring to the counter. At S605, when the CPU 110 determines that the BD signal 107 is detected three times, the processing proceeds to S606, and when the CPU 110 determines that the BD signal 107 is not detected three times, the processing returns to S605. At S606, the CPU 110 moves to the intermittent emission control of the semiconductor laser 101. At S607, the CPU 110 determines whether or not the detected BD cycle is equal to or more than the threshold value. In the case of Example 1, as described above, 2000 μsec is used as the threshold value of the BD cycle.
At S607, when the CPU 110 determines that the BD cycle is equal to or more than 2000 μsec (equal to or more than the predetermined cycle), the processing proceeds to S608, and when the CPU 110 determines that the BD cycle is less than 2000 μsec (less than the predetermined cycle), the processing proceeds to S609. At S608, as indicated by Formulas (1) and (2), the CPU 110 computes the emission start and end timings of the semiconductor laser 101 with the coefficients K1 and K2, and controls the semiconductor laser 101. At S609, as indicated by Formulas (3) and (4), the CPU 110 computes the emission start and end timings of the semiconductor laser 101 with the coefficients K3 and K4, and controls the semiconductor laser 101.
At S610, the CPU 110 determines whether or not the BD cycle has reached the target cycle. At S610, when the CPU 110 determines that the BD cycle has reached the target cycle, the processing proceeds to S611, and when the CPU 110 determines that the BD cycle has not reached the target cycle, the processing returns to S607. At S611, the CPU 110 completes the start-up of the scanner motor 103, and the processing ends.
As described above, according to Example 1, the calculation formulas for computing the emission start and end timings of the semiconductor laser 101 are switched according to the BD cycle at the time of start-up of the scanner motor 103. Accordingly, even in the early stage of start-up of the scanner motor 103 in which the BD cycle is significantly changed, the emission to the horizontal synchronization sensor 106 can be positively performed. Additionally, a device to avoid the laser emission to the image area can be further provided in the early stage of start-up of the scanner motor 103.
As described above, according to Example 1, the laser can be turned on in the area in which the horizontal synchronization signal is generated at the time of start-up of the scanning apparatus.
In Example 2, the calculation formulas for computing the emission start and end timings of the semiconductor laser 101 are switched according to the amount of change of the BD cycle. Accordingly, even if the acceleration at the time of increasing the speed of the scanner motor 103 to a target rotation speed (hereinafter referred to as the speed increasing slope) is changed according to the environmental variation or the secular change, the emission of the laser light to the horizontal synchronization sensor 106 is enabled. Further, since the configuration of the laser scanner unit in Example 2 is similar to the configuration of the laser scanner unit in Example 1, a description is omitted.
(Description of the Operation of Performing Start-Up from the State where the Scanner Motor 103 is Stopped)
Using
Difference of the BD cycles=the BD cycle at the scan at the time before last−the time period of the BD cycle at the last scan Formula (5)
In contrast to Example 1, the switching of the computation formulas of the emission start and end timings of the semiconductor laser 101 at the time of the intermittent emission control is performed by using the difference of the BD cycle. A description is added below about the characteristic points in Example 2. In the period from the time t2 to a time t14 illustrated in
The time period until the emission end=(the BD cycle at the scan at the time before last−the BD cycle at the last scan)×K1 Formula (6)
The time period until the emission start=(the BD cycle at the scan at the time before last−the BD cycle at the last scan)×K2 Formula (7)
Here, K1 and K2 are coefficients, and as in Example 1, it is assumed that K1:0.004 and K2:0.93 in Example 2.
Next, after the time t14 from start-up of the scanner motor 103 in
The time period until the emission end=(the BD cycle at the scan at the time before last−the BD cycle at the last scan)×K3 Formula (8)
The time period until the emission start=(the BD cycle at the scan at the time before last−the BD cycle at the last scan)×K4 Formula (9)
Here, K3 and K4 are coefficients, and as in Example 1, it is assumed that K3:0.011 and K4:0.97 in Example 2. Further, switching of the calculation formulas may be performed multiple times during the start-up of the scanner motor 103. Additionally, the difference of the BD cycle may be obtained multiple times, and the average value of the differences in a plurality of obtained BD cycles may be used as the threshold value.
(Description of Flowchart)
Next, using the flowchart of
When the CPU 110 moves to the intermittent emission control from the continuous emission control in S606, the processing proceeds to S901. At S901, the CPU 110 calculates the difference between the BD cycle at the scan at the time before last and the BD cycle at the last scan as described above. The CPU 110 determines whether or not the calculated difference of the BD cycle is equal to or more than the threshold value. At S901, when the CPU 110 determines that the difference of the BD cycle is equal to or more than the threshold value (equal to or more than the predetermined difference), the processing proceeds to S902, and when the CPU 110 determines that that the difference of the BD cycle is less than the threshold value (less than the predetermined difference), the processing proceeds to S903.
At S902, as indicated by the above-described Formulas (6) and (7), the CPU 110 calculates the emission start and end timings (the time periods T16, T15) of the semiconductor laser 101 by using the coefficients K1 and K2, and performs the intermittent emission control. At S903, as indicated by the above-described Formulas (8) and (9), the CPU 110 calculates the emission start and end timings (T18, T17) of the semiconductor laser 101 by using the coefficients K3 and K4, and performs the intermittent emission control, and the processing proceeds to S610. Further, at S610, when the CPU 110 determines that the BD cycle has not reached the target cycle, the processing returns to S901.
As described above, by using the difference of the BD cycle, the emission start and end timings of the semiconductor laser 101 can be controlled according to the amount of change of the BD cycle. As a result, even if the speed increasing slope of the scanner motor 103 is varied due to the environmental variation or the secular change, the effects described in Example 1 can be obtained.
As described above, according to Example 2, the laser can be turned on in the area in which the horizontal synchronization signal is generated at the time of start-up of the scanning apparatus.
In Example 3, the control in a case where the semiconductor laser 101 includes two light sources is described. Further, since the configuration of the laser scanner unit in Example 3 is similar to the configuration of the laser scanner unit in Example 1, a description is omitted. Two semiconductor lasers 101 are referred to as a semiconductor laser 101a, which is a first light source, and a semiconductor laser 101b, which is a second light source. Additionally, since Example 3 is based on the control in Example 1, the difference between Example 1 and Example 3 is mainly described.
(Description of the Operation of Performing Start-Up from the State where the Scanner Motor 103 is Stopped)
Using
The semiconductor laser 101a driven by the laser driving signal 109a is turned on according to the generation area of the BD signal 107. Additionally, the semiconductor laser 101b driven by the laser driving signal 109b emits laser in the non-image area at the timing different from the driving timing of the semiconductor laser 101a. During the emission of the semiconductor laser 101b, the amount of light of the semiconductor laser 101b is adjusted by the laser drive circuit 113. A description is added below about the characteristic points in Example 3. In Example 3, the CPU 110 performs the control of the emission start and the emission end of the semiconductor laser 101a that is turned on for generating the BD signal 107, as well as the control of the emission start and the emission end of the semiconductor laser 101b, which is another light source.
In the period from the time t2 to the time t3 illustrated in
The time period until the emission start of the semiconductor laser 101b=the BD cycle at the last scan×K5 Formula (10)
The time period until the emission end of the semiconductor laser 101b=the BD cycle at the last scan×K6 Formula (11)
Here, K5 and K6 are coefficients, and it is assumed that K5:0.91 and K6:0.92 in Example 3. Additionally, as for the coefficients, values that are in the non-image area and do not overlap with the light-emitting timing of the semiconductor laser 101a are set. For example, setting is performed such that the coefficient K5<the coefficient K2, and the coefficient K6<the coefficient K2. Additionally, the setting is performed such that the coefficient K1<the coefficient K5, and the coefficient K1<the coefficient K6.
Next, after the time t3 from the start-up of the scanner motor 103 in
The time period until the emission start of the semiconductor laser 101b=the BD cycle at the last scan×K7 Formula (12)
The time period until the emission end of the semiconductor laser 101b=the BD cycle at the last scan×K5 Formula (13)
Here, K7 and K8 are coefficients, and it is assumed that K7:0.090 and K8:0.96 in Example 3. Additionally, as for the coefficients, values that are in the non-image area and do not overlap with the light-emitting timing of the semiconductor laser 101a are set. For example, setting is performed such that the coefficient K7<the coefficient K4, and the coefficient K5<the coefficient K4. Additionally, setting is performed such that the coefficient K3<the coefficient K7, and the coefficient K3<the coefficient K5.
In Example 3, the calculation formula of the emission end time of the semiconductor laser 101b is switched so as to match the timing at which the calculation formula of the emission start time of the semiconductor laser 101a is switched. Additionally, control is performed such that the coefficient K6<the coefficient K2, and the coefficient K8<the coefficient K4, in order to turn off the semiconductor laser 101b earlier than the emission start timing of the semiconductor laser 101a. Further, by making the coefficient K7<the coefficient K5, the emission area of the semiconductor laser 101b is controlled to be narrow in the early stage of start-up of the scanner motor 103, and the laser emission to the image area is avoided.
(Description of Flowchart)
Next, using the flowchart of
At S607, when the CPU 110 determines that the detected BD cycle is equal to or more than the threshold value, the processing proceeds to S1101, and when the CPU 110 determines that the BD cycle is less than the threshold value, the processing proceeds to S1102. At S1101, as indicated by Formulas (1) and (2), the CPU 110 calculates the emission start and end timings of the semiconductor laser 101a by using the coefficients K1 and K2, and performs the intermittent emission control. Further, as indicated by Formulas (10) and (11), the CPU 110 calculates the emission start and end timings of the semiconductor laser 101b by using the coefficient K5 and K6, and performs the intermittent emission control.
At S1102, as indicated by Formulas (3) and (4), the CPU 110 calculates the emission start and end timings of the semiconductor laser 101a by using the coefficients K3 and K4, and performs the intermittent emission control. Further, as indicated by Formulas (12) and (13), the CPU 110 calculates the emission start and end timings of the semiconductor laser 101b by using the coefficients K7 and K8 and performs the intermittent emission control, and the processing proceeds to S610.
As described above, according to Example 3, the calculation formulas for calculating the emission timings for the semiconductor laser 101b as well as the semiconductor laser 101a are switched according to the BD cycle at the time of start-up of the scanner motor 103. Accordingly, together with the effects in Example 1, the emission timings of the semiconductor laser 101a and the semiconductor laser 101b can be controlled so as not to overlap with each other, and further, the laser emission to the image area can be avoided also in the semiconductor laser 101b. Further, the configuration including the two semiconductor lasers 101a and 101b may be applied to Example 2 (the intermittent emission control based on the difference of the BD cycle).
As described above, according to Example 3, the laser can be turned on in the area in which the horizontal synchronization signal is generated at the time of start-up of the scanning apparatus.
In contrast to Example 3, in Example 4, the control in a case where the emission of the semiconductor laser 101b is performed after the emission of the semiconductor laser 101a is described. Further, since the configuration of the laser scanner unit in Example 4 is similar to the configuration of the laser scanner unit in Example 1, a description is omitted. Additionally, since Example 4 is based on the control in Example 1, the difference between Example 1 and Example 4 is mainly described.
(Description of the Operation of Performing Start-Up from the State where the Scanner Motor 103 is Stopped)
Using
Next, after the time t3 from the start-up of the scanner motor 103 of
The time period until emission start of the semiconductor laser 101b=the BD cycle at the last scan×K9 Formula (14)
The time period until emission end of the semiconductor laser 101b=the BD cycle at the last scan×K10 Formula (15)
Here, K9 and K10 are coefficients, and it is assumed that K9:0.015 and K10:0.1 in Example 4.
In Example 4, the emission control of the semiconductor laser 101b is switched so as to match the timing at which the calculation formula of the emission start time of the semiconductor laser 101a is switched. Additionally, in order to turn on the semiconductor laser 101b after turning off the semiconductor laser 101a, it is assumed that the coefficient K3<the coefficient K9. Further, by controlling the semiconductor laser 101b so as not to be turned on in the early stage of start-up of the scanner motor 103, the semiconductor laser 101b is prevented from being turned on in the image area.
(Description of Flowchart)
Next, using the flowchart of
At S607, the CPU 110 determines whether or not the BD cycle is equal to or more than the threshold value (for example, equal to or more than 2000 μsec), and when the CPU 110 determines that the BD cycle is equal to or more than the threshold value, the processing proceeds to S608, and when the CPU 110 determines that the BD cycle is less than the threshold value, the processing proceeds to S1301. At S608, as indicated by Formulas (1) and (2), the CPU 110 calculates the emission start and end timings of the semiconductor laser 101a by using the coefficients K1 and K2, and performs the intermittent emission control. Further, at S608, the CPU 110 controls the semiconductor laser 101b so as not to be turned on.
At S1301, as indicated by Formulas (3), (4), (14) and (15), the CPU 110 calculates the emission start and end timings of the semiconductor laser 101a and the semiconductor laser 101b with the coefficients K3, K4, K9 and K10. The CPU 110 performs the intermittent emission control according to the calculated timing, and the processing proceeds to S610.
As described above, according to Example 4, in a case where the semiconductor laser 101b is turned on after the semiconductor laser 101a, the semiconductor laser 101b is controlled to be turned on so as to match the emission end timing of the semiconductor laser 101a. Accordingly, together with the effects in Example 1, the emission timings of the semiconductor laser 101a and the semiconductor laser 101b can be controlled so as not to overlap with each other. Additionally, by controlling the semiconductor laser 101b so as not to be turned on in the early stage of start-up of the scanner motor 103, the laser emission to the image area can be avoided.
Additionally, although the case where the two semiconductor lasers 101a and 101b are provided is described in Examples 3 and 4, the number of the semiconductor lasers 101 may be more than two. In this case, the laser light emitted from one semiconductor laser is input to the horizontal synchronization sensor 106, and the laser light emitted from another semiconductor laser is not input to the horizontal synchronization sensor 106. Additionally, in a case where the number of the monitor elements included in the laser drive circuit 113 is one, the amount of light is adjusted in the state where only one semiconductor laser is turned on.
As described above, according to Example 4, the laser can be turned on in the area in which the horizontal synchronization signal is generated at the time of start-up of the scanning apparatus.
According to the present invention, the laser can be turned on in the area in which the horizontal synchronization signal is generated at the time of start-up of the scanning apparatus.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2018-096082, filed May 18, 2018, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2018-096082 | May 2018 | JP | national |