JP3943184B2 - Image forming apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention reduces the number of image forming apparatuses that form color images by using a plurality of photoconductors such as copying machines and laser printers, particularly the number of line buffers that store image data, thereby reducing the cost of the apparatus. It is about.
[0002]
[Prior art]
FIG. 11 shows the configuration of a conventional quadruple photosensitive drum type image forming apparatus that forms a color image by scanning a plurality of photosensitive drums with laser beams emitted from a plurality of laser emission sources. In this apparatus, an image data generation unit 2 that outputs image data 2K to 2C of each color of K (black), Y (yellow), M (magenta), and C (cyan) sent from a scanner or a host device or the like. , Four sets of line buffers 51 to 54 corresponding to the image data 2K to 2C of each color, an optical sensor 71, a print controller 72, a laser controller 73, a laser light source 74, a polygon mirror 75, and a photoreceptor 76.
[0003]
The line buffer 51 stores K (black) image data 2K sent from the image data generating unit 2, and sends out the stored image data 2K by a synchronous clock sent from the print control unit 72K. The optical sensor 72K is arranged in a non-printing area in the scanning area of the photosensitive drum 76K, detects the laser beam emitted from the laser light source 74K and reflected by the polygon mirror 75K, and sends out a synchronization signal. The print control unit 72K generates a synchronization clock according to the sent synchronization signal and sends it to the line buffer 51, and modulates and sends the image data 2K sent from the line buffer 51. The laser control unit 73K controls the laser light source 74K in accordance with the modulated image data 2K, and emits laser light including image data from the laser light source 74K. The polygon mirror 75K deflects and scans the laser beam emitted from the laser light source 74K. The photosensitive drum 76K writes image data by the incident laser beam. The image data written on the photosensitive drum 76K is transferred to the recording paper 8.
[0004]
In the above description, the image data 2K of K (black) has been described, but the image data 2Y to 2C of each color of Y (yellow), M (magenta), and C (cyan) sent from the image data generation unit 2 are also included. The data is stored in the line buffers 52 to 54 and written to the photosensitive drums 76Y to 76C. A color image is formed by transferring onto the recording paper 8 in the order of K (black), Y (yellow), M (magenta), and C (cyan). When the image data of each color is transferred to the recording paper 8, the image data of one color is output and then the image data of the next color is output at the output timing of the image data of each color in the sub-scanning direction. For this purpose, a certain delay time T1 is provided. As shown in FIG. 12, the delay time T1 is such that T1 = Lo / Vo when the conveying speed of the conveying belt 9 that conveys the recording paper 8 is Vo and the distance between the photoconductors 76K to 76C is Lo. Thus, color misregistration is prevented. For this reason, as shown in FIG. 13, each line buffer 51 to 54 has K (black), Y (yellow), M (magenta), and C (cyan) timings in accordance with the delay time T1 = Lo / Vo. Image data for each page is stored.
[0005]
[Problems to be solved by the invention]
In the conventional image forming apparatus, since line buffers are provided for each photosensitive drum in order to form a color image, the number of line buffers increases and the cost increases.
[0006]
The present invention has been made to eliminate such disadvantages, and an object thereof is to obtain an image forming apparatus in which the number of line buffers is reduced and the cost is reduced.
[0007]
[Means for Solving the Problems]
  The image forming apparatus according to the present invention is a time required for scanning one page of image data in an image forming apparatus that forms a color image by scanning a plurality of photoconductors with laser beams emitted from a plurality of laser emission sources. Is T, and the total number of photoconductors is N, the delay time T1 from the start of scanning of image data for each photoconductor to the start of scanning of image data for the next photoconductor and one page of image data for each photoconductor The delay times T2 from the end of scanning to the start of scanning of the next image data are T ≧ T1 ≧ T / (N−1) and T ≧ T2 ≧ T / (N−1), respectively.Thus, the image data for one page for scanning the first to Nth photoconductors is sequentially stored in (N−1) line buffers.An image is formed.
[0008]
  A second image forming apparatus according to the present invention scans image data of one page in an image forming apparatus that forms a color image by scanning a plurality of photoconductors with laser beams emitted from a plurality of laser emission sources. When the time required for T is T and the total number of photoconductors is N, the delay time T1 from the start of scanning of image data for each photoconductor to the start of scanning of image data for the next photoconductor and one page for each photoconductor The delay time T2 from the end of the scan of the image data to the start of the scan of the next image data is determined according to the timings T ≧ T1 ≧ T / (N−1) and T ≧ T2 ≧ T / (N−1), respectively. One page of image data for scanning the first to (N-1) th photoconductors is sequentially stored in different (N-1) line buffers, and the Nth photoconductors are stored. One page to scan By dividing the image data, wherein the image data scanning the other photosensitive bodies to form an image by sequentially stored to the line buffer to be sequentially stored.
[0009]
  According to a third image forming apparatus of the present invention, scanning of image data for one page is performed in an image forming apparatus that forms a color image by scanning a plurality of photoconductors with laser beams emitted from a plurality of laser emission sources. When the time required for T is T and the total number of photoconductors is N, the delay time T1 from the start of scanning of image data for each photoconductor to the start of scanning of image data for the next photoconductor and one page for each photoconductor The delay time T2 from the end of scanning of the next image data to the start of scanning of the next image data is in accordance with the timing when T ≧ T1 ≧ T / 2 and T ≧ T2 ≧ T, respectively, from the first stage to the Nth stage One page of image data for scanning the photoconductor is sequentially stored in (N-2) line buffers to form an image.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
The image forming apparatus according to the present invention includes a main control unit, an image data generation unit that outputs image data of four colors of black, yellow, magenta, and cyan sent from a scanner or host device, three input selectors, and buffer control. 4 sets of image data writing units for writing four color image data respectively. The main control unit outputs a plurality of gate signals indicating the timing of writing the four color image data in the three line buffers. The first input selector selects black image data output from the image data generation unit and sent to the first stage image data writing unit and cyan image data to be sent to the fourth stage image data writing unit. Store in the first line buffer. The second input selector selects the yellow image data and cyan image data output from the image data generation unit and sent to the second-stage image data writing unit, and stores them in the second line buffer. The third input selector selects magenta image data and cyan image data output from the image data generation unit and sent to the third-stage image data writing unit, and stores them in the third line buffer. The output selector sends the cyan image data stored in the first line buffer, the second line buffer, and the third line buffer to the fourth-stage image data writing unit.
[0011]
Each image data writing unit includes an optical sensor, a printing control unit, a laser control unit, a laser light source, a polygon mirror, and a photoconductor. Each print control unit generates a synchronization clock for each color in accordance with a synchronization signal for each color output from each optical sensor that detects the laser light emitted from each laser light source and reflected by the polygon mirror, and buffers it. Send to the control unit. Also, laser light including image data for each color sent from each line buffer is emitted from each laser light source, deflected and scanned by a polygon mirror to form a color-specific image on each photoconductor, and recorded on a recording sheet. Transcript.
[0012]
The timing of scanning each photoconductor with laser light is as follows: the time required for scanning one page of image data is T, and the total number of photoconductors is N = 4. The delay time T1 until the body scan is started and the delay time T2 from the end of the scan of the image data for one page of each photoconductor to the start of the scan of the next image data are respectively T ≧ T1 ≧ T / (N -1), T ≧ T2 ≧ T / (N−1). For this reason, the main control unit outputs a gate signal indicating the period inputted to each line buffer during one scanning time of image data for each color according to the delay time T1 and the delay time T2, and four color image data for each line buffer. Four types of gate signals indicating the input timing are output. Each input selector inputs cyan image data to each line buffer when a gate signal indicating the timing of inputting cyan image data to the line buffer is at a low level.
[0013]
  Then, when outputting the image data for each color sent from the scanner or the host device, the main control unit inputs it to each line buffer during one scanning time of the image data for each color according to the delay time T1 and the delay time T2. 4 types of gate signals indicating the timings of inputting the gate signals indicating the period to be input and the four color image data to the respective line buffers are output. The buffer controller generates a write enable signal for each line buffer from the input gate signal and sends it to each line buffer. Black, yellow, and magenta image data sent from the image data generation unit via the input selector by this write enable signal is sent to each line buffer for each page according to the delay time T1 and the delay time T2.Stored sequentially.The cyan image data is divided and stored in each line buffer. The first, second, and third stage image data is read by the color-specific read clock signal sent from the buffer control unit to the black, yellow, and magenta image data sequentially stored in each line buffer. The cyan image data respectively sent to the writing unit and sequentially stored in each line buffer is sent to the fourth-stage image data writing unit via the output selector, thereby forming an image of each color.
[0014]
As described above, when outputting the image data for each color, the timing of scanning the laser beam on each photoconductor is as follows: the time required for scanning one page of image data is T, and the total number of photoconductors is N = 4. In addition, the delay time T1 from the start of scanning of each photoconductor to the start of scanning of the next photoconductor and the end of scanning of one page of image data of each photoconductor to the start of scanning of the next image data. Since the delay times T2 are T ≧ T1 ≧ T / (N−1) and T ≧ T2 ≧ T / (N−1), respectively, the number is less than the number of image data writing units for writing four color image data. Four line image data can be stored using three line buffers.
[0015]
Further, by selecting and setting the delay times T1 and T2 within the above range, it is possible to store four color image data using two line buffers.
[0016]
Further, the delay times T1 and T2 are appropriately selected within the above range, and the delay time T1 from the start of scanning of each photosensitive member to the start of scanning of the next photosensitive member is set between other photosensitive members. By making it larger than the distance between the bodies, it is possible to store the image data of four colors using two line buffers and shorten the distance from the first-stage photoconductor to the fourth-stage photoconductor. it can.
[0017]
【Example】
FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention. As shown in the figure, the image forming apparatus uses the main control unit 1 and four-color image data 2K (black), 2Y (yellow), 2M (magenta), and 2C (cyan) sent from the scanner or the host device. Image data writing for writing the output image data generating unit 2, the three input selectors 31 to 33, the buffer control unit 4, the three line buffers 51 to 53, the output selector 6 and the image data 2K, 2Y, 2M, 2C Part 7K-7C.
[0018]
The main control unit 1 outputs gate signals 21L, 21K, 21Y, 21M, and 21C indicating the timing for writing the image data 2K to 2C in the line buffers 51 to 53. The image data generator 2 outputs the image data 2K to 2C of each color sent from the scanner or the host device. The input selector 31 receives the black image data 2K output from the image data generating unit 2 and sent to the first-stage image data writing unit 7K and the cyan image data 2C sent to the fourth-stage image data writing unit 7C. The line buffer 51 is selected and stored. The input selector 32 selects the yellow image data 2Y and the cyan image data 2C output from the image data generating unit 2 and sent to the second-stage image data writing unit 7Y, and stores them in the line buffer 52. The input selector 33 selects the magenta image data 2M and the cyan image data 2C output from the image data generator 2 and sent to the third-stage image data writing unit 7M and stores them in the line buffer 53. The output selector 6 sends the image data 2C stored in the line buffers 51 to 53 to the image data writing unit 7C.
[0019]
Each of the image data writing units 7K to 7C includes an optical sensor 71, a print control unit 72, a laser control unit 73, a laser light source 74, a polygon mirror 75, and a photoconductor 76, respectively. Each of the optical sensors 71K to 71C is disposed in a non-printing area within the scanning area of each of the photoconductors 76K to 76C, and detects the laser light emitted from the laser light sources 74K to 74C and reflected by the polygon mirrors 75K to 75C. Then, a synchronization signal for each color is sent to each of the print control units 72K to 72C. Each of the print control units 72K to 72C generates a synchronization clock 22K to 22C for each color according to the sent synchronization signal for each color and sends it to the buffer control unit 4. In addition, the image data 2K to 2C sent from the line buffers 51 to 53 are modulated and sent to the laser controllers 73K to 73C. The laser controllers 73K to 73C control the laser light sources 74K to 74C with the modulated image data 2K to 2C, and emit laser beams including the image data 2K to 2C from the laser light sources 74K to 74C. The polygon mirrors 75K to 75C deflect and scan the laser beams emitted from the laser light sources 74K to 74C. The photoreceptors 76K to 76C form an image with the scanned laser light and transfer it to the recording paper 8.
[0020]
The timing of scanning the laser beams on each of the photoconductors 76K to 76C is, for example, as shown in the time chart of FIG. 2A, T is the time required to scan one page of image data 2K to 2C, and the total number N of photoconductors. 4, a delay time T1 from the start of scanning of the photoconductors 76K, 76Y, and 76M to the start of scanning of the next photoconductors 76Y, 76M, and 76C, and one page image of each of the photoconductors 76K to 76C. Delay times T2 from the end of scanning of data 2K to 2C to the start of scanning of image data 2K to 2C of the next page are set to satisfy T ≧ T1 ≧ T / 3 and T ≧ T2 ≧ T / 3, respectively. Here, the reason why the upper limit of each of the delay times T1 and T2 is T is that the distance Lo between the respective photoconductors 76K to 76C is increased in proportion to each delay time, and the time for forming a color image is increased. This is to prevent it from becoming large.
[0021]
Therefore, the main control unit 1 determines a gate signal 21L or an image indicating a period input to the line buffers 51 to 53 during one scanning time of the image data 2K to 2C for each color according to the delay time T1 and the delay time T2. Gate signals 21K, 21Y, 21M, and 21C indicating the timing of inputting the data 2K to 2C to the line buffers 51 to 53 are output. The input selector 31 inputs the image data 2C to the line buffer 51 when the gate signal 21C indicating the timing for inputting the image data 2C to the line buffer 51 is at a low level and the gate signal 21K is at a high level. Similarly, the input selector 32 inputs the image data 2C to the line buffer 52 when the gate signal 21C is at a low level and the gate signal 21Y is at a high level, and the input selector 33 inputs the gate signal 21C at a low level and a gate. The image data 2C is input to the line buffer 53 when the signal 21M is at a high level.
[0022]
For example, as shown in FIG. 3, the buffer control unit 4 has a plurality of or gates, AND gates, and selectors, and each gate signal 21L, 21K, 21Y, 21M, 21C from the main control unit 1 Write enable signals 231 to 233 and image data indicating the timing of inputting the image data 2K to 2C to the line buffers 51 to 53 by inputting the synchronization clocks 22K to 22C for each color sent from the print control units 72K to 72C. A selector indicating the timing for outputting read clock signals 241 to 243 indicating the timing for reading 2K to 2C from the line buffers 51 to 53, and outputting the image data 2C stored in the line buffers 51 to 53 from the output selector 6 Signals 251 and 252 are output. That is, the image data 2K to 2C of each color are input to the line buffers 51 to 53 when the gate signal 21L and the gate signals 21K, 21Y, 21M, and 21C are at a low level. For example, the write enable signal 231 of the line buffer 51 is obtained by an OR operation of the gate signal 21K and the gate signal 21C and an AND operation of the gate signal 21L, and the write enable signal of the line buffer 52 is obtained. 232 is obtained by ORing the gate signal 21Y and the gate signal 21C and ANDing the gate signal 21L, and the write enable signal 233 of the line buffer 53 is obtained from the gate signal 21M and the gate signal 21M. -Obtained by ORing the gate signal 21C and ANDing the gate signal 21L. The selector signals 251 and 252 for selecting the image data 2C are composed of 2 bits in order to express four states. For example, when the output prohibition of the image data 2C is (0, 0), when outputting from the line buffer 51 (0, 1), when outputting from the line buffer 52 (1, 0), outputting from the line buffer 53 In some cases, it is defined as (1, 1), and the selector signals 251 and 252 can be generated by performing a logical operation on the gate signals 21Y, 21M, and 21C. Further, the lead clock signals 241 to 243 are selected from the synchronous clocks 22K to 22C for each color and the gate signal 21C sent from the print control units 72K to 72C.
[0023]
  In the image forming apparatus configured as described above, when outputting image data 2K (black), 2Y (yellow), 2M (magenta), and 2C (cyan) for each color sent from the scanner or the host device. As shown in FIG. 2B, the main controller 1 sets T as the time required to scan one page of image data 2K to 2C on each of the photoconductors 76K to 76C, and sets the photoconductors 76K, 76Y, and 76M. The delay time T1 from the start of scanning to the start of scanning of the next photoconductors 76Y, 76M, and 76C, and the image data 2K on the next page from the end of scanning of the image data 2K to 2C on one page of each photoconductor 76K to 76C. The delay time T2 until the start of scanning of 2C is T ≧ T1 ≧ T / 3 and T ≧ T2 ≧ T / 3, and the delay time T1 and the delay time T2 are used for the image data 2K to 2C for each color. Gate signals 21K, 21Y, 21M, and 21C indicating the timing at which the gate signals 21L and the image data 2K to 2C are input to the line buffers 51 to 53 during the scanning time are input to the line buffers 51 to 53. Output. The buffer control unit 4 generates the write enable signals 231 to 233 of the respective line buffers 51 to 53 shown in FIG. 2 (c) with the input gate signals 21L, 21K, 21Y, 21M, and 21C, thereby generating the line buffers. Send to 51-53. The image data 2K to 2M sent from the image data generator 2 through the input selectors 31 to 33 by the write enable signals 231 to 233 are line buffers for each page as shown in FIG. 51 to 53 depending on delay time T1 and delay time T2Stored sequentially.Further, since the line buffer 51 to 53 is switched by the write enable signals 231 to 233 in the image data 2C, the divided image data 2C1 to 2C3 are stored in the line buffers 51 to 53, respectively. The image data 2K to 2M sequentially stored in the line buffers 51 to 53 are sent to the print control units 72K to 72M by the read clock signals 241 to 243 sent from the buffer control unit 4, and are sent to the line buffers 51 to 53, respectively. The sequentially stored image data 2C1 to 2C3 are sent to the print controller 72C via the output selector 6 to form an image of each color. At this time, since the output selector 6 has data duplication portions in the image data 2C1 to 2C3 stored in the line buffers 51 to 53, the data duplication stored in the other line buffers 51 to 53 in accordance with the sent selector signals 251 and 252. By selecting one of the line buffers 51 to 53 so as to exclude the portion, the image data 2Ca, 2Cb, 2Cc excluding the overlapping portion indicated by the arrow range is output to the print control unit 72C.
[0024]
  Thus, when outputting the image data 2K to 2C for each color, the delay time T1 from the start of scanning of the photoconductors 76K, 76Y, and 76M to the start of scanning of the next photoconductors 76Y, 76M, and 76C, Delay times T2 from the end of scanning one page of image data 2K to 2C to the start of scanning of next page image data 2K to 2C are T ≧ T1 ≧ T / 3 and T ≧ T2 ≧ T /, respectively. The gate signal 21L and the image data 2K to 2C indicating the period inputted to the line buffers 51 to 53 in one scanning time of the image data 2K to 2C for each color according to the delay time T1 and the delay time T2 of 3 are obtained. Gate signals 21K, 21Y, 21M, and 21C indicating the timing of input to the line buffers 51 to 53 are provided.Because I tried to outputThe four color image data 2K to 2C can be stored by using three line buffers 51 to 53 which are smaller than the image data writing units 7K to 7C for writing the four color image data 2K to 2C.
[0025]
  In the above-described embodiment, the case where the image data 2C is divided and stored in the three line buffers 51 to 53 has been described. However, as shown in the block diagram of FIG. The color image data 2K to 2C are output from the input selectors 31 to 33 to the line buffers 51 to 53, and as shown in FIG. 5B, T ≧ T1 ≧ T / 3 and T ≧ T2 ≧ T / 3. When the image data 2K to 2C for one page is sequentially stored in the line buffers 51 to 53 by the gate signals 21K, 21Y, 21M, and 21C corresponding to the delay times T1 and T2, a line buffer 51 to 53 is shown in FIG. As described above, the image data 2C is not divided, and one page is stored in each of the three line buffers 51 to 53.Can be stored sequentially.In this case, the image data 2K to 2C sequentially stored in the line buffers 51 to 53 is sent to the respective print control units by the read clock signals determined by the respective synchronous clocks 22K to 22C sent from the respective print control units 72K to 72C. It is good to output to 72K-72C.
[0026]
In the above-described embodiment, the case where the four color image data 2K to 2C are stored in the three line buffers 51 to 53 has been described. However, from the start of scanning of the photosensitive members 76K, 76Y, and 76M, the next photosensitive members 76Y and 76M are stored. , 76C, and a delay time T2 from the end of scanning one page of image data 2K to 2C to the start of scanning of image data 2K to 2C on the next page. By setting T ≧ T1 ≧ T / 2 and T2 = T, the four color image data 2K to 2C can be stored in two line buffers.
[0027]
In this case, as shown in the block diagram of FIG. 6, the image data to be sent to the first-stage image data writing unit 7K among the four color image data 2K to 2C sent from the image data generating unit 2 is used. The image data 2M to be sent to the data 2K and the third stage image data writing unit 7M are stored in the line buffer 51, and the image data 2Y to be sent to the second stage image data writing unit 7Y and the fourth stage The image data 2C to be sent to the eye image data writing unit 7C is stored in the line buffer 52. Then, as shown in the time charts (a) and (b) of FIG. 7, the main control unit 1 sets the gate signal 21L corresponding to the delay times T1 and T2 of T ≧ T1 ≧ T / 2 and T2 = T. , 21K, 21Y, 21M, 21C are sent to the buffer control unit 4. As shown in the block diagram of FIG. 8, the buffer control unit 4 performs logical operation on the received gate signals 21L, 21K, 21Y, 21M, and 21C and inputs the image data 2K to 2C to the line buffers 51 and 52. Write enable signals 231 and 232 indicating the timing of the image generation, and the line signals of the image data 2K to 2C from the gate signals 21K and 21Y and the respective synchronous clocks 22K to 22C sent from the print control units 72K to 72C. Read clock signals 241 and 242 indicating the timing of reading from 51 and 52 are generated. For example, the write enable signal 231 of the line buffer 51 is obtained by an OR operation of the gate signal 21K and the gate signal 21M and an AND operation of the gate signal 21L, and the write enable signal of the line buffer 52 is obtained. 232 is obtained by performing an OR operation on the gate signal 21Y and the gate signal 21C and an AND operation on the gate signal 21L. The lead clock signal 241 is selected from the gate signal 21K and the synchronous clocks 22K and 22M, and the lead clock signal 242 is selected from the gate signal 21Y and the synchronous clocks 22Y and 22C. Then, a write enable signal 231 is sent to the line buffer 51 as shown in FIG. 7C, and the image data 2K and 2M are sequentially stored in the line buffer 51 as shown in FIG. The signal 232 is sent to the line buffer 52, and the image data 2Y and 2C are sequentially stored in the line buffer 52. The image data 2K to 2C sequentially stored in the line buffers 51 and 52 are sent to the print control units 72K to 72C by read clock signals 241 and 242, respectively.
[0028]
Thus, by setting the delay times T1 and T2 to T ≧ T1 ≧ T / 2 and T2 = T, the four color image data 2K to 2C can be stored in the two line buffers 51 and 52, and the circuit. The configuration can be simplified.
[0029]
In the above-described embodiment, the delay time T1 from the start of scanning of the photoconductors 76K, 76Y, and 76M to the start of scanning of the next photoconductors 76Y, 76M, and 76C is made the same, and two sets of four color image data 2K to 2C are obtained. Although the case where the data are stored in the line buffers 51 and 52 has been described, one of delay times T1 from the start of scanning of the photoconductors 76K, 76Y, and 76M to the start of scanning of the next photoconductors 76Y, 76M, and 76C. The image data 2K to 2C of the four colors can be stored in the two line buffers 51 and 52 by increasing the delay time T1 of the part.
[0030]
For example, as shown in the time chart of FIG. 9A, the delay time T1Y from the start of scanning of the photoconductor 76K to the start of scanning of the next photoconductor 76Y is set to T ≧ T1Y ≧ T / 3, and the photoconductor The delay time T1M from the start of scanning 76Y to the start of scanning of the next photoconductor 76M is set to T ≧ T1M ≧ 2T / 3, and the delay from the start of scanning of the photoconductor 76M to the start of scanning of the next photoconductor 76C. The time T1C is set to T ≧ T1C ≧ T / 3, the delay time T2 = T, and the gate signal corresponding to each delay time T1Y, T1M, T1C and the delay time T2 = T as shown in FIG. 9B. If 21K to 21C are output from the main control unit 1, the four color image data 2K to 2C can be sequentially stored in the two line buffers 51 and 52 as shown in FIG. If the delay times T1Y, T1M, and T1C are set to T1Y = T / 3, T1M = 2T / 3, and T1C = T / 3, as shown in FIG. The distance L to the photoreceptor 76C is L = 4T · Vo / 3, and can be made shorter than the distance L = 3T · Vo / 2 when each delay time T1 is equal to T1 = T · Vo / 2. Therefore, the apparatus can be reduced in size.
[0031]
【The invention's effect】
  As described above, in the present invention, when outputting image data for each color, the timing for scanning each photoconductor with laser light is T for the time required to scan one page of image data, and the total number of photoconductors. When N, each photoconductorScanning of image data forTo the next photoconductorScanning of image data forDelay time T1 and each photoconductorScanning of one page of image data forFrom the start of scanning of the next image dataDelay time T2 isSince T ≧ T1 ≧ T / (N−1) and T ≧ T2 ≧ T / (N−1), respectively, the number of line buffers is smaller than the number of image data writing units for writing image data of each color. The image data of each color can be stored by using it, and the cost can be reduced.
[0032]
Further, by appropriately selecting and setting the delay times T1 and T2 within the above range, the image data of each color can be stored, the number of line buffers can be further reduced, and the cost can be further reduced.
[0033]
Further, the delay times T1 and T2 are appropriately selected within the above range, and the delay time T1 from the start of scanning of each photosensitive member to the start of scanning of the next photosensitive member is set between other photosensitive members. By making it larger than between the bodies, the image data of each color can be stored, the number of line buffers can be reduced, and the distance from the first-stage photoconductor to the last-stage photoconductor can be shortened. Miniaturization can also be achieved.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment of the present invention.
FIG. 2 is a time chart showing the operation of the embodiment.
FIG. 3 is a configuration diagram of a buffer control unit of the embodiment.
FIG. 4 is a block diagram showing a configuration of a second embodiment.
FIG. 5 is a time chart showing the operation of the second embodiment.
FIG. 6 is a block diagram showing a configuration of a third embodiment.
FIG. 7 is a time chart showing the operation of the third embodiment.
FIG. 8 is a configuration diagram of a buffer control unit according to a third embodiment.
FIG. 9 is a time chart showing the operation of the fourth embodiment.
FIG. 10 is an explanatory diagram showing the arrangement of each photoconductor.
FIG. 11 is a block diagram showing a configuration of a conventional example.
FIG. 12 is a perspective view showing the arrangement of photoconductors.
FIG. 13 is a time chart showing the operation of the conventional example.
[Explanation of symbols]
1 Main control unit
2 Image data generator
31-33 Input selector
4 Buffer control unit
51-53 Line buffer
6 Output selector
7 Image data writing section
71 Optical sensor
72 Print controller
73 Laser controller
74 Laser light source
75 polygon mirror
76 photoconductor

Claims (3)

In an image forming apparatus for forming a color image by scanning a plurality of photoconductors with laser beams emitted from a plurality of laser emission sources,
When the time required for scanning one page of image data is T and the total number of photoconductors is N, the delay time T1 from the start of image data scan to each photoconductor to the start of image data scan for the next photoconductor. And delay times T2 from the end of scanning one page of image data to the start of scanning of the next image data for each photoconductor are T ≧ T1 ≧ T / (N−1) and T ≧ T2 ≧ T / (N−, respectively. 1) image data for one page for scanning the first to Nth photoconductors is sequentially stored in (N-1) line buffers to form an image at the timing of 1) . An image forming apparatus. In an image forming apparatus for forming a color image by scanning a plurality of photoconductors with laser beams emitted from a plurality of laser emission sources ,
When the time required for scanning one page of image data is T and the total number of photoconductors is N, the delay time T1 from the start of image data scan to each photoconductor to the start of image data scan for the next photoconductor. And delay times T2 from the end of scanning one page of image data to the start of scanning of the next image data for each photoconductor are T ≧ T1 ≧ T / (N−1) and T ≧ T2 ≧ T / (N−, respectively. 1), the image data for one page for scanning the first to (N-1) th photoconductors is sequentially stored in different (N-1) line buffers, respectively. The image data for one page for scanning the N-stage photoconductor is divided, and the image data for scanning the other photoconductors is sequentially stored in a line buffer that is sequentially stored to form an image. Image forming apparatus. In an image forming apparatus for forming a color image by scanning a plurality of photoconductors with laser beams emitted from a plurality of laser emission sources ,
When the time required for scanning one page of image data is T and the total number of photoconductors is N, the delay time T1 from the start of image data scan to each photoconductor to the start of image data scan for the next photoconductor. The delay time T2 from the end of scanning of one page of image data to the start of scanning of the next image data on each photoconductor is in accordance with the timing when T ≧ T1 ≧ T / 2 and T ≧ T2 ≧ T, respectively. An image forming apparatus comprising: (N-2) line buffers sequentially storing image data for one page for scanning the Nth photoconductor from the first to form an image.

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