JP3755439B2 - Exposure apparatus and photographic processing apparatus provided with the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an exposure apparatus that exposes a photosensitive material such as photographic paper, and a photographic processing apparatus including the exposure apparatus.
[0002]
[Prior art]
  Conventionally, in the printing of photographs, analog exposure is performed in which printing is performed by irradiating light onto a photographic film on which an original image is recorded and irradiating the photographic paper with light transmitted through the photographic film. In recent years, red, blue, and green monochromatic light has been applied to each pixel based on digital image data obtained by reading an image on a photographic film with a scanner or digital image data obtained by photographing with a digital camera. Digital exposure for printing is performed by irradiating the photographic paper every time.
[0003]
  Various configurations for performing this digital exposure have been proposed. As an example, light from a light source is irradiated to an LCS (Liquid Crystal Shutter) that controls transmission and blocking of light according to image data. However, there is a configuration in which the image is exposed by irradiating the photographic paper with light transmitted through the LCS.
[0004]
  FIG. 5 is an explanatory view showing an example of such a digital exposure printing apparatus. This printing apparatus includes a light source 51R / 51G / 51B, an LCS array 52, and a rod lens plate 53.
[0005]
  The light sources 51R, 51G, and 51B are light sources that emit red, green, and blue monochromatic lights, respectively. As the light sources 51R and 51G that emit red and green light, for example, a light source provided with LEDs (Light Emitting Diodes) on a line is used. For example, an FL tube is used as the light source 51B that emits blue light.
[0006]
  The LCS array 52 controls the amount of monochromatic light applied to the photographic paper by transmitting or blocking the monochromatic light emitted from the light sources 51R, 51G, and 51B.
[0007]
  The rod lens plate 53 is a projection means in which refractive index distribution type rod lenses, for example, SELFOC (registered trademark) lenses manufactured by Nippon Sheet Glass Co., Ltd. are bundled and arranged on the surface. With this rod lens plate 53, the monochromatic light transmitted through the LCS array 52 is imaged on the photographic paper P.
[0008]
  The printing apparatus emits monochromatic light from the light sources 51R, 51G, and 51B while relatively moving the photographic paper P, the light sources 51R, 51G, and 51B, the LCS array 52, and the rod lens plate 53. The image is printed on the photographic paper P by controlling the light transmission state in the LCS array 52 according to the image data.
[0009]
  As shown in FIG. 6, the LCS array 52 includes an R pixel unit 54R that controls transmission / blocking of light according to image data of a red component, a green component, and a blue component on a single substrate. Pixel portions 54G ... and B pixel portions 54B ... are provided. Each pixel part is composed of two transparent electrodes arranged opposite to each other and a liquid crystal layer provided between the transparent electrodes, and changes the voltage applied from the two transparent electrodes to the liquid crystal layer. By doing so, transmission / blocking of light is controlled.
[0010]
  The R pixel unit 54R, G pixel unit 54G, and B pixel unit 54B are provided so as to be alternately arranged in two columns in the main scanning direction. Further, the region composed of the columns of the R pixel portions 54R..., The region composed of the columns of the G pixel portions 54G..., And the region composed of the columns of the B pixel portions 54B. Each region is irradiated with red light, green light, and blue light independently.
[0011]
  The LCS array 52 is provided with driver ICs 55A and 55B for driving each pixel unit. The driver IC 55A is provided on the outer side in the sub-scanning direction than the region of the R pixel portions 54R ..., and drives the pixel portions in the columns on the R pixel portion 54R ... side in the R pixel portions 54R ... and the G pixel portions 54G ... ing. Further, the driver IC 55B is provided on the outer side in the sub-scanning direction with respect to the region of the B pixel portion 54B... And the pixel portion of the column on the B pixel portion 54B... Side in the B pixel portion 54B. Is driving.
[0012]
[Problems to be solved by the invention]
  In the printing apparatus, an LED array and an FL tube are used as the light source. When the light source is composed of LEDs, almost no heat is generated during light emission, but when the light source is composed of an FL tube, a certain amount of heat is generated during light emission.
[0013]
  Thus, when the FL tube generates heat, the light emission luminance in the FL tube changes due to the temperature rise of the FL tube itself, and the amount of light irradiated to the LCS array changes. That is, the density change occurs in the printed image on the photographic paper according to the temperature change of the FL tube.
[0014]
  Further, the temperature of the LCS array also rises due to the heat generated by the FL tube. Since the LCS array has the characteristic that the transmittance varies depending on the temperature state of the liquid crystal, the density change occurs in the printed image on the photographic paper even if the temperature of the LCS array changes.
[0015]
  Furthermore, the temperature of the LED array also rises due to the heat generated by the FL tube. Since the LED has a characteristic that the wavelength component of the emitted light changes depending on the temperature change of the light emitting portion, when the temperature change occurs in the LED, the color of the printed image on the photographic paper changes. .
[0016]
  As described above, when the LED array and the FL tube are both used as the light source, the influence of the heat generated by the FL tube extends not only to the FL tube itself but also to the LCS array and the LED array. There is a problem that the image quality of the printed image on the photographic paper is remarkably deteriorated.
[0017]
  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide another light source by heat from a light source that generates a large amount of heat during light emission in an exposure apparatus having a plurality of types of light sources. Another object of the present invention is to provide an exposure apparatus capable of suppressing the influence on other configurations and a photographic processing apparatus including the exposure apparatus.
[0018]
[Means for Solving the Problems]
  To solve the above problem,The present inventionThe exposure apparatus is an exposure apparatus that performs scanning exposure by relatively moving a photosensitive material, and includes a plurality of light sources that respectively emit monochromatic light having different wavelengths, and transmission / reception of light according to image information. A pixel region including a plurality of pixel units for controlling blocking, and a light modulation unit provided corresponding to the plurality of light sources, wherein the plurality of light sources are divided into a plurality of light source groups according to a heat generation amount during light emission. And the light source groups are spatially separated from each other.All light sources with the same light emission principle are included in the same light source group.It is characterized by.
[0019]
  The exposure operation in the exposure apparatus configured as described above is performed as follows. First, monochromatic light emitted from each light source enters the light modulation means, and transmission / cutoff is controlled in accordance with image information in a plurality of pixel units constituting a pixel region corresponding to each monochromatic light. Scanning exposure is performed by irradiating the light emitted from the light modulation means to the relatively moving photosensitive material.
[0020]
  In such a configuration, each light source is divided into a plurality of light source groups according to the amount of heat generated during light emission, and the light source groups are spatially separated from each other. Thereby, for example, heat from a light source having a relatively high heat generation amount during light transmission is transmitted to a light source having a relatively low heat generation amount during light emission, and adverse effects are suppressed. Therefore, even if a plurality of light sources having greatly different amounts of heat generated at the time of light emission are provided, it is possible to prevent changes in light emission performance caused by the influence of heat generated on each other, and a homogeneous image can be formed on the photosensitive material. It becomes possible to expose.
[0021]
  Further, since the spatial separation is performed in units of light sources, for example, the number of spatial separations can be reduced compared to a configuration in which each light source is spatially separated. Therefore, it is possible to suppress a decrease in the degree of freedom of arrangement of each component due to spatial separation, and it is possible to realize, for example, downsizing of the apparatus.
[0022]
  Furthermore, in the present invention,All light sources with the same emission principle are included in the same light source group.ing.
[0023]
  According to said structure, if each light source has the same light emission principle, it will be contained in the same light source group, even if the wavelength of the light emitted differs. Therefore, since the spatial separation is not performed more than necessary, it is possible to suppress a decrease in the degree of freedom of arrangement of each configuration by preventing the influence of heat generation.
[0024]
  The exposure apparatus of the present invention isA temperature adjusting means for adjusting the temperature in the space is provided in the space including the light source groups.
[0025]
  According to said structure, the temperature containing the light source groups classified according to the emitted-heat amount at the time of light emission is each temperature-adjusted by the temperature adjustment means. Therefore, since it is possible to perform optimum temperature adjustment for each light source group according to the amount of heat generated, temperature control of each light source can be performed with high accuracy.
[0026]
  In the exposure apparatus of the present invention, the temperature adjusting means is a Peltier element that moves heat from one surface side to the other surface side when an electric current is applied.
[0027]
  In the exposure apparatus of the present invention, the Peltier element is characterized in that a heat radiating member is provided on a surface opposite to the space.
[0028]
  In addition, the present inventionThe exposure equipment ofAny one of the aboveIn the configuration described above, the plurality of light sources are arranged in one housing, and a shielding plate is provided between spaces including each light source group.
[0029]
  According to said structure, each light source is arrange | positioned in one housing | casing, and each light source group will be spatially divided | segmented by the shielding board. Accordingly, each light source can be housed in one unit, and for example, a configuration in which the exposure apparatus is moved in the sub-scanning direction while the photosensitive material is stationary during scanning exposure can be easily realized. It becomes possible.
[0030]
  In addition, the present inventionThe exposure equipment ofAny one of the aboveIn the configuration described above, a temperature adjusting means for adjusting the temperature in the space is provided in the space including the light source groups.
[0031]
  According to said structure, the temperature containing the light source groups classified according to the emitted-heat amount at the time of light emission is each temperature-adjusted by the temperature adjustment means. Therefore, since it is possible to perform optimum temperature adjustment for each light source group according to the amount of heat generated, temperature control of each light source can be performed with high accuracy.
[0032]
  In addition, the present inventionThe exposure equipment ofSaidThe configuration described in any one of the above is characterized in that a light source group including a light source configured by LEDs and a light source group including a light source configured by an FL tube are provided.
[0033]
  In the above configuration, the light source configured by the LED and the light source configured by the FL tube are provided, and these are included in different light source groups, and both are spatially divided. As a result, heat from the FL tube having a relatively large calorific value is prevented from being transmitted to the LED having a relatively small calorific value, and the light emission characteristics of the light source constituted by the LED can be kept constant. It becomes.
[0034]
  The present inventionThe exposure equipment ofSaidIn the configuration according to any one of the above, the light modulation unit is divided into a plurality of substrates, and each pixel region is provided on a separate substrate for each light source group including a corresponding light source. It is a feature.
[0035]
  According to the above configuration, since each pixel region in the light modulation unit is provided on a separate substrate for each light source group including the corresponding light source, for example, light from a light source with a relatively large amount of heat generation is irradiated. It is possible to suppress the temperature rise in the pixel area to be propagated to the pixel area irradiated with light from the light source having a relatively small amount of heat generation. Therefore, the temperature adjustment in the light modulation means can be performed independently for each substrate, so that such temperature adjustment becomes easy and the accuracy of temperature adjustment can be improved.
[0036]
  The present inventionThe exposure equipment ofSaidIn the above structure, each substrate of the light modulation means is arranged in a space including a corresponding light source group.
[0037]
  According to the above configuration, each light source group is spatially divided, and each substrate in the light modulation unit is also spatially divided corresponding to the corresponding light source group. Therefore, since the movement of heat between the substrates is almost completely prevented, the temperature of each substrate in the light modulation means can be adjusted more easily and accurately.
[0038]
  The present inventionThe exposure equipment ofSaidIn the configuration described in any one of the above, the projector further includes a projecting unit that projects the light emitted from the light modulating unit onto the photosensitive material, and the projecting unit exists on the incident-side focal length. The light from the pixel part in the modulation means is projected onto a photosensitive material arranged on the focal length on the emission side without changing the relative position.
[0039]
  According to the above configuration, as the means for projecting the light emitted from the light modulation means onto the photosensitive material, the light present on the focal length on the incident side can be changed without changing the relative position thereof. Projection means for projecting onto the photosensitive material disposed above is used. Thereby, it is possible to accurately irradiate the photosensitive material with the light emitted from each pixel portion, and it is possible to provide an exposure image in which image distortion or deviation due to projection does not occur.
[0040]
  In addition, the present inventionThe photo processing equipmentSaidThe exposure apparatus according to any one of the above, a developing unit that develops the photosensitive material exposed by the exposure apparatus by using a developing solution, and a photosensitive that has been developed in the developing unit. And a drying section for drying the material.
[0041]
  According to the above configuration, the exposure processing, development processing, and drying processing for the photosensitive material can be performed continuously under a unified management, so that a large number of photographs can be taken without placing an operational burden on the user. Can be printed continuously.
[0042]
DETAILED DESCRIPTION OF THE INVENTION
  An embodiment of the present invention will be described below with reference to FIGS.
[0043]
  The photographic processing apparatus according to this embodiment is a digital photographic printer that prints an original image on a photosensitive material by printing, developing and drying the photosensitive material based on the image data of the original image.
[0044]
  FIG. 2 is an explanatory diagram showing the configuration of the photographic processing apparatus. As shown in FIG. 2, the photographic processing apparatus includes an exposure unit 1, a photographic paper storage unit 2, a development unit 3, a drying unit 4, and a PC (Personal Computer) 5.
[0045]
  The photographic paper storage unit 2 stores photographic paper as a photosensitive material, and supplies the photographic paper to the exposure unit 1 during printing. The exposure unit 1 performs image printing by performing scanning exposure on the photographic paper supplied from the photographic paper storage unit 2 according to the image data of the original image. Details of the exposure unit 1 will be described later.
[0046]
  The developing unit 3 develops an image by transporting the photographic paper that has been subjected to the printing process while being dipped in various development processing solutions. The drying unit 4 is for drying photographic paper that has been subjected to development processing. The PC 5 functions as a control unit that controls various operations in the photo processing apparatus, and also has a function of storing image data of an original image, a function of performing data processing on the image data, and the like. .
[0047]
  Next, the configuration of the exposure unit 1 will be described. FIG. 3 is an explanatory diagram showing the configuration of the exposure unit 1 and the photographic paper storage unit 2. As shown in FIG. 3, the photographic paper storage unit 2 positioned above the exposure unit 1 includes two paper magazines 2 a and 2 b for storing roll-shaped photographic paper P. Each of the paper magazines 2a and 2b stores photographic paper P having different sizes, and is set so that the photographic paper P to be supplied can be switched according to the size of the output image required by the user.
[0048]
  As described above, the exposure unit 1 performs scanning exposure on the photographic paper P supplied from the photographic paper storage unit 2, and includes a printing unit (exposure device) 6 and conveying rollers R1 to R5. I have.
[0049]
  The printing unit 6 irradiates the photographic printing paper P conveyed by the conveying rollers R1 to R5 with light for exposure. The conveyance rollers R1 to R5 are for feeding the photographic paper P supplied from the photographic paper storage unit 2 to the developing unit 3 via the printing unit 6.
[0050]
  Next, the configuration of the printing unit 6 will be described. FIG. 1 is a perspective view showing a schematic configuration of a printing unit 6 in the present embodiment. As shown in FIG. 1, the printing unit 6 includes light sources 11R, 11G, and 11B, LCS arrays (light modulation means) 12A and 12B, a rod lens plate (projection means) 13, a reflection mirror 19, and a temperature controller (temperature adjustment means). ) 20A and 20B and the shielding plate 21 are provided inside the housing 22.
[0051]
  A rod lens plate 13 is provided on the light emission side of the housing 22, and a space surrounded by the housing 22 and the rod lens plate 13 is divided into two spaces SA and SB by the shielding plate 21. The light sources 11R and 11G, the LCS array 12A, the reflection mirror 19, and the temperature controller 20A are disposed in the one space SA, and the light source 11B, the LCS array 12B, and the temperature controller 20B are disposed in the other space SB. Has been placed.
[0052]
  The light emitted from the light sources 11R and 11G passes through the LCS array 12A and the rod lens plate 13 in this order, and is irradiated onto the photographic paper P. The light emitted from the light source 11B passes through the LCS array 12B and the rod lens plate 13 in this order, and is irradiated onto the photographic paper P. In FIG. 1, the scanning exposure is performed by conveying the photographic paper P in the left-right direction. Here, instead of transporting the photographic paper P, the scanning exposure may be performed by moving the printing unit 6 in the left-right direction while the photographic paper P is stationary.
[0053]
  The light sources 11R and 11G are light sources configured by LED arrays in which LEDs (Light Emitting Diodes) are arranged in a line in the main scanning direction, in other words, in the horizontal width direction of the photographic paper P, and emit red light and green light, respectively. To do. The light source 11B is a light source configured by an FL tube whose longitudinal direction is arranged in the main scanning direction, and emits blue light. The light source 11B is composed of an FL tube and a reflector provided around the FL tube.
[0054]
  The reflection mirror 19 is a mirror that reflects the light emitted from the light source 11R in the direction in which the LCS array 12A is disposed. Note that the reflection mirror 19 is unnecessary if the arrangement configuration is such that light can be directly emitted from the light source 11R to the LCS array 12A. Further, a configuration may be employed in which a reflection mirror that reflects light emitted from the light source 11G in the direction in which the LCS array 12A is disposed is provided.
[0055]
  The LCS arrays 12A and 12B control the amount of monochromatic light applied to the photographic paper P by transmitting or blocking the monochromatic light emitted from the light sources 11R, 11G, and 11B. Details of the configuration of the LCS arrays 12A and 12B will be described later.
[0056]
  The rod lens plate 13 is a projection unit in which a plurality of gradient index rod lenses, for example, SELFOC (registered trademark) lenses manufactured by Nippon Sheet Glass Co., Ltd. are bundled and arranged on the surface. The rod lens is a solid lens having a cylindrical shape, and has a refractive index that increases toward the center in a cross section perpendicular to the axial direction of the cylinder. The light emitted from one point at a focal length that is conjugate with the rod lens is converged to one point on the imaging plane, and the position thereof does not change. That is, the position of the light emission point and the position of the imaging point correspond one-to-one without being affected by the relative position between the light emission point and the rod lens. In the present embodiment, all light of R, G, and B components emitted from the LCS arrays 12A and 12B are irradiated onto different regions of one rod lens plate 13 and projected onto the photographic paper P. It has become.
[0057]
  The temperature controllers 20A and 20B are members that adjust the temperature of the spaces SA and SB in the housing 22, respectively. The temperature controllers 20A and 20B are configured by, for example, Peltier elements. When the temperature controllers 20 </ b> A and 20 </ b> B are configured by Peltier elements, the Peltier elements are arranged so as to be in contact with the outer surface side of the housing 22. The Peltier element is an element having a function of transferring heat from one surface side to the other surface side when an electric current is applied. That is, the temperature of the spaces SA and SB in the housing 22 can be adjusted by appropriately applying a current to the Peltier element and moving the heat from the housing 22 to the outside. Here, the heat exchange effect in the Peltier element can be improved by providing a heat dissipation member such as a heat sink on the surface of the Peltier element opposite to the surface in contact with the housing 22.
[0058]
  In addition, it is good also as a structure by which heating means, such as a rubber heater, was affixed to parts other than the light transmission area | region in LCS array 12A * 12B. The rubber heater is a rubber-like member that generates heat when energized. By providing such a heating means, when the temperature of the LCS arrays 12A and 12B is low immediately after startup or the like, it can be rapidly heated to an optimum temperature as an operating temperature. .
[0059]
  As described above, the shielding plate 21 is a member that divides the space SA and the space SB in the housing 22 and is preferably made of a material having a heat insulating function. In this case, it is possible to prevent heat generated in the space SA from being transmitted to the space SB.
[0060]
  With the configuration described above, monochromatic light is emitted from the light sources 11R, 11G, and 11B while the printing unit 6 and the photographic paper P are relatively moved, and light is transmitted through the LCS arrays 12A and 12B according to the image data. By controlling the state, the image is printed on the photographic paper P.
[0061]
  Next, the configuration of the LCS arrays 12A and 12B will be described with reference to FIG. As shown in the figure, the LCS array 12A includes an R pixel unit 14R, a driver IC (driving means) 15R, an FPC (Flexible Printed Circuit) cable 16R, a G pixel unit 14G, and a driver IC on a substrate 17A. (Drive means) 15G and FPC cable 16G are provided. Further, the LCS array 12B has a configuration in which a B pixel portion 14B, a driver IC (driving means) 15B, and an FPC cable 16B are provided on a substrate 17B.
[0062]
  The R pixel unit 14R, G pixel unit 14G, and B pixel unit 14B are members that control transmission / reception of light according to image data of a red component, a green component, and a blue component, respectively. Each pixel part is composed of two transparent electrodes arranged opposite to each other and a liquid crystal layer provided between the transparent electrodes, and changes the voltage applied from the two transparent electrodes to the liquid crystal layer. By doing so, transmission / blocking of light is controlled. For example, ITO (Indium Tin Oxide) is used as the transparent electrode.
[0063]
  In each pixel unit, control is performed by binary of whether light is transmitted or blocked, and gradation expression is performed by changing the time for transmitting light, and gradation is performed by so-called pulse width modulation. Will be expressed. Note that the light transmittance itself may be modulated by changing the voltage applied to the liquid crystal layer according to the gradation.
[0064]
  The R pixel portions 14R, G pixel portions 14G, and B pixel portions 14B are provided so as to be alternately arranged in two rows in the main scanning direction. The direction of the column by each pixel portion is the main scanning direction in scanning exposure, that is, the horizontal width direction of the photographic paper P.
[0065]
  Thus, by providing each pixel portion so as to be alternately arranged in two rows, when scanning exposure is performed on the photographic printing paper P, exposure is performed so that the end portions of adjacent pixels overlap each other. Can do. That is, the light-shielding region between the pixel portions in each row is not burned onto the photographic paper P as an unexposed portion. Therefore, even when an LCS having a relatively small aperture ratio is used, baking can be performed without any problem, so that cost can be reduced.
[0066]
  In addition, the region composed of the columns of the R pixel portions 14R, the region composed of the columns of the G pixel portions 14G, and the region composed of the columns of the B pixel portions 14B, respectively, are R pixel region 18R, G pixel region 18G, and B, respectively. A pixel region 18B is formed. As described above, the R pixel region 18R and the G pixel region 18G are provided in the LCS array 12A, and the B pixel region 18B is provided in the LCS array 12B. In each of the regions, red light, green light, and blue light are independently irradiated.
[0067]
  In the sub-scanning direction, the distance between the R pixel area 18R and the G pixel area 18G and the distance between the G pixel area 18G and the B pixel area 18B are preferably designed to be equal to each other. In this case, since the scanning line for red light, the scanning line for green light, and the scanning line for blue light are positioned at equal intervals on the photographic paper P, the irradiation timing for each color when exposing the same line The delay time can be made equal. More specifically, in FIG. 4, for example, when scanning exposure is performed by relatively moving a photographic paper P (not shown) from top to bottom, the same line is first exposed with red light, and the photographic paper P With the movement, exposure of green light and blue light is performed with a time difference. Here, as described above, if the scanning lines for red light, green light, and blue light are positioned at equal intervals, the green light exposure delay time for the red light exposure and the green light exposure The delay time of the blue light exposure should be set equal. Thereby, control of exposure timing can be simplified.
[0068]
  The LCS array 12A is provided with driver ICs 15R and 15G for driving the R pixel portions 14R and G pixel portions 14G, respectively. The LCS array 12B is provided with a driver IC 15B for driving the B pixel portions 14B. Is provided.
[0069]
  In the LCS array 12A, the driver IC 15R is disposed on the opposite side to the G pixel region 18G side with respect to the R pixel region 18R, and a wiring for driving each of the R pixel units 14R. It is provided for each part 14R. The driver IC 15R is connected to an FPC 16R for inputting a data signal corresponding to the image data of each pixel.
[0070]
  The driver IC 15G is arranged on the LCS array 12B side with respect to the G pixel region 18R in the LCS array 12A, and wiring for driving each of the G pixel units 14G... Is provided for each G pixel unit 14G. It has been. The driver IC 15G is connected to an FPC 16G for inputting a data signal corresponding to the image data of each pixel.
[0071]
  In the LCS array 12B, the driver IC 15B is arranged on the opposite side to the LCS array 12A side with respect to the B pixel region 18B, and wiring for driving each of the B pixel units 14B. It is provided for every 14B. The driver IC 15B is connected to an FPC 16B for inputting a data signal corresponding to the image data of each pixel.
[0072]
  Note that the arrangement positions of the driver ICs 15R, 15G, and 15B are not limited to the above example, and may be arranged on either side of the pixel area as long as they are close to the corresponding color pixel area. . However, if two driver ICs are arranged between adjacent pixel areas, the distance between the pixel areas may be too wide. It is preferable to arrange the IC.
[0073]
  Here, for example, in the LCS array 12A, one driver IC drives both the R pixel unit 14R and the G pixel unit 14G, and the driver IC is connected to the R pixel region 18R and the G pixel region 18G. It is good also as a structure arrange | positioned between. In the case of this configuration, the number of driver ICs provided in the LCS array 12A can be reduced, so that the configuration can be simplified. In practice, however, wiring is drawn from both sides of the driver IC toward each pixel portion. Therefore, there is a high possibility that the connection of the FPC for inputting the data signal becomes difficult.
[0074]
  As described above, according to the LCS arrays 12A and 12B having the above-described configuration, the driver IC and the pixel group of each color have a one-to-one correspondence, and the driver IC and the corresponding color pixel. No other color pixel portion is provided between the subgroups. Therefore, since there is no wiring for driving the pixel portions of other colors at positions close to each pixel portion, the influence of the electric field from such wiring is affected by the alignment state of the liquid crystal layer of the pixel portion. No longer reach. Therefore, it is possible to appropriately transmit / block light in each pixel unit, and it is possible to prevent deterioration of the image quality of the exposure image.
[0075]
  In addition, the wiring in the LCS arrays 12A and 12B is basically only a straight line connecting the driver IC and each pixel portion, and the spacing between the wirings and the spacing between the wiring and the pixel portion are relatively wide. Further, since it is not necessary to make the width of the wiring so thin, the manufacturing is relatively easy and the yield is not reduced. Therefore, it is possible to provide the printing unit 6 capable of preventing the deterioration of the image quality of the exposure image without increasing the manufacturing cost.
[0076]
  As described above, the printing unit 6 of the present embodiment has the light source 11R / 11G configured by the LED array and the light source 11B configured by the FL tube divided by the shielding plate 21 in the internal space of the housing 22. Are arranged in the two spaces SA and SB, and the temperature controllers 20A and 20B are provided in the spaces SA and SB. That is, the printing unit 6 has a configuration in which the light source is arranged in a different space for each type and the temperature can be adjusted for each space. This makes it possible to adjust the temperature of a light source that generates a large amount of heat during light emission, such as an FL tube, and a light source that generates a small amount of heat during light emission, such as an LED array, in different spaces.
[0077]
  Accordingly, the light sources 11R and 11G are not affected by the heat from the light source 11B, so that the temperature adjustment by the temperature controller 20A can be accurately performed. Therefore, it is possible to accurately control the temperature of the LED arrays themselves constituting the light sources 11R and 11G, and light having a constant wavelength can always be emitted.
[0078]
  For the light source 11B side, the temperature adjustment by the temperature controller 20B only needs to be performed considering only the temperature of the FL tube constituting the light source 11B. Here, for example, in the configuration shown in FIG. 1, when the shielding plate 21 is not provided and the temperature adjustment is performed on a space including all of the light sources 11R and 11G and the light source 11B, Temperature adjustment must be performed in consideration of the temperatures of all these light sources, resulting in a problem of complicated control. On the other hand, if it is a structure like this embodiment, what is necessary is just to adjust temperature with the temperature controller 20B for exclusive use with respect to space SB containing only the FL pipe | tube used as a main heat generation source. More accurate temperature adjustment can be performed. Thereby, it becomes possible to always emit light having a constant light quantity from the light source 11B.
[0079]
  In addition, the printing unit 6 of the present embodiment divides the LCS array into two, and converts the LCS array 12A provided with the R pixel region 18R and the G pixel region 18G that modulates the light from the light sources 11R and 11G into the space SA. The LCS array 12B provided with the B pixel region 18B for modulating the light from the light source 11B is arranged in the space SB. Thus, an LCS array that modulates light from a light source that generates a large amount of heat during light emission, such as an FL tube, and an LCS array that modulates light from a light source that generates a small amount of heat during light emission, such as an LED array, The temperature can be adjusted in another space.
[0080]
  Therefore, for the LCS array 12A side, it is separated from the LCS array 12B irradiated with the light from the light source 11B made of the FL tube, and is also spatially separated by the shielding plate 21. Thus, heat from the LCS array 12B whose temperature has been increased by the heat of is prevented from being transmitted to the LCS array 12A. Therefore, it becomes easy to always control the temperature of the LCS array 12A to be constant, so that it is possible to prevent fluctuations in the wavelength characteristics of transmitted light due to temperature fluctuations of the liquid crystal.
[0081]
  Further, for the LCS array 12B side, it is only necessary to control the temperature of the LCS array 12B without considering the movement of heat with respect to the LCS array 12A. Can be performed accurately and quickly.
[0082]
  Next, position adjustment in the LCS arrays 12A and 12B will be described. As in the above configuration, in the case where a pixel portion arranged in the main scanning direction is provided for each color, the position of each pixel portion of each color is set so that the exposure images of the respective color components coincide on the printing paper P. It is necessary to set it correctly.
[0083]
  In this embodiment, as shown in FIG. 4, the LCS array 12A provided with the R pixel portions 14R and G pixel portions 14G and the LCS array 12B provided with the B pixel portions 14B are separated from each other. It is comprised from the board | substrate. The R pixel portions 14R and G pixel portions 14G provided on the same substrate can be dealt with by ensuring positional accuracy when forming each pixel portion, but the B pixel portions 14B. The positional relationship between the R pixel unit 14R and the G pixel unit 14G depends on the arrangement position accuracy of the LCS array 12A and the LCS array 12B.
[0084]
  Therefore, in the present embodiment, at least one of the LCS array 12A and the LCS array 12B is configured so that the arrangement position can be finely adjusted. Specifically, for example, the LCS array 12A is arranged on a stage provided with a micrometer, and the micrometer is adjusted to finely adjust the position and inclination of the LCS array 12A.
[0085]
  As a position adjustment procedure, the following method can be cited. First, as a test image, a black image, that is, an image in which each color component has the maximum value is printed on the printing paper P for one scanning line. Then, the image printed on the photographic paper P is observed with a magnifying glass or the like, and the shift amount of the image of each color component is measured. Here, according to the configuration of the present embodiment, it is assumed that the R pixel units 14R and G pixel units 14G provided on the same substrate have positional accuracy secured when the LCS 12A is created. The images of these color components should match. Therefore, the position of the LCS array 12A is adjusted so that the red and green component images coincide with the blue component image. Then, the test image as described above is printed again to check whether or not there is a shift, and the position adjustment as described above is repeated until there is no shift. By performing such adjustment, the image of each color component can be exposed at the same position on the photographic paper P, and an image with good image quality in which no color misregistration occurs can be printed.
[0086]
  In the configuration of the present embodiment, the LCS array is divided into two LCS arrays 12A and 12B. For example, the LCS array is divided into three LCS arrays, and one color component is assigned to each LCS array. A configuration in which a pixel portion is provided is also conceivable. In other words, in this configuration, three LCS arrays corresponding to the LCS array 12A are provided. However, in the case of such a configuration, it is necessary to perform the position adjustment as described above for each color component. That is, at least two LCS arrays are configured to be able to finely adjust their positions, and the positions of these at least two LCS arrays are adjusted simultaneously while observing the state of the test image. Therefore, in such a configuration, there is a problem that the position adjustment of each LCS array becomes complicated, and the time and labor required for the position adjustment increase.
[0087]
  On the other hand, according to the configuration of the present embodiment, since the position of at least one of the two LCS arrays 12A and 12B may be adjusted, the position adjustment is performed as compared with the configuration in which the LCS array is divided into three. Can be done easily.
[0088]
  In the configuration shown in FIG. 1, the space surrounded by the housing 22 and the rod lens plate 13 is divided into two spaces SA and SB by the shielding plate 21. It is also possible to divide into two parts, a part through which light of R component and G component is transmitted and a part through which light of B component is transmitted, and to divide the two rod lens plates by the shielding plate 21. According to this configuration, in addition to the light source and the LCS array, the rod lens plate can be arranged in different spaces depending on the type of the corresponding light source, so that the heat insulation between the two spaces SA and SB is achieved. Can be increased.
[0089]
  However, since the rod lens plate has characteristics that hardly change in performance due to temperature fluctuations and heat transfer is not high, the rod lens plate is divided as shown in the configuration shown in FIG. Even if it is the structure which does not carry out, it is possible to show an effect as mentioned above enough.
[0090]
  Further, when the rod lens plate is divided into two, it is necessary to adjust the arrangement position and inclination of each rod lens plate. Therefore, there is a problem that a configuration for performing such adjustment is required, and maintenance work is required. Therefore, considering these, the rod lens plate as in the configuration shown in FIG. It can be said that a configuration without division is preferable.
[0091]
  In addition, as a member which comprises light source 11R * 11G and light source 11B, it is not limited to said example, If light source 11R * 11G and the light source 11B are comprised by the light source of a respectively different type, Any thing may be used.
[0092]
  The exposure apparatus of the present invention is characterized in that each pixel portion in the light modulation means controls light transmission / blocking by changing a voltage applied to the liquid crystal.
[0093]
  According to the above configuration, since the light modulation means is constituted by a liquid crystal display element having a high technical level, the exposure image can be controlled with high accuracy, and an exposure image with excellent image quality can be obtained. It becomes possible to provide.
[0094]
【The invention's effect】
  As aboveBookAn exposure apparatus according to the present invention is an exposure apparatus that performs scanning exposure by relatively moving a photosensitive material, and includes a plurality of light sources that respectively emit monochromatic light having different wavelengths, and light according to image information. A plurality of light sources corresponding to the plurality of light sources, wherein the plurality of light sources correspond to the amount of heat generated during light emission. It is divided into groups and the light source groups are spatially separated from each other.All light sources with the same light emission principle are included in the same light source groupIt is a configuration.
[0095]
  Thereby, for example, heat from a light source having a relatively high heat generation amount during light transmission is transmitted to a light source having a relatively low heat generation amount during light emission, and adverse effects are suppressed. Therefore, even if a plurality of light sources having greatly different amounts of heat generated at the time of light emission are provided, it is possible to prevent changes in light emission performance caused by the influence of heat generated on each other, and a homogeneous image can be formed on the photosensitive material. There is an effect that exposure is possible.
[0096]
  Further, since the spatial separation is performed in units of light sources, for example, the number of spatial separations can be reduced compared to a configuration in which each light source is spatially separated. Therefore, it is possible to suppress a decrease in the degree of freedom of arrangement of the respective components due to spatial separation, and it is possible to realize, for example, downsizing of the apparatus.
[0097]
  Also,Since the spatial separation is not performed more than necessary, it is possible to suppress a decrease in the degree of freedom in the arrangement of each component by adopting a configuration that prevents the influence of heat generation.
[0098]
  In the exposure apparatus according to the present invention, the temperature adjusting means is a Peltier element that moves heat from one surface side to the other surface side when an electric current is applied.
[0099]
  In the exposure apparatus according to the present invention, the Peltier element is configured such that a heat radiating member is provided on a surface opposite to the inside of the space.
[0100]
  BookThe exposure apparatus according to the present invention has a configuration in which the plurality of light sources are arranged in one housing, and a shielding plate is provided between spaces including each light source group.
[0101]
  ThisSaidofAny one ofIn addition to the effect of the configuration, each light source can be housed in one unit. For example, in scanning exposure, the exposure apparatus is moved in the sub-scanning direction while the photosensitive material is stationary. It is possible to easily realize the above.
[0102]
  BookThe exposure apparatus according to the present invention has a configuration in which temperature adjusting means for adjusting the temperature in the space is provided in the space including the light source groups.
[0103]
  ThisSaidofAny one ofIn addition to the effect of the configuration, it is possible to adjust the temperature optimally for each light source group according to the amount of heat generated, so that the temperature control of each light source can be accurately performed. .
[0104]
  BookThe exposure apparatus according to the invention has a configuration including a light source group including a light source configured by LEDs and a light source group including a light source configured by an FL tube.
[0105]
  ThisSaidIn addition to the effect of the configuration of any one of the above, the heat from the FL tube having a relatively large calorific value is prevented from being transmitted to the LED having a relatively small calorific value, and the light source configured by the LED There is an effect that it becomes possible to keep the light emission characteristics constant.
[0106]
  BookIn the exposure apparatus according to the present invention, the light modulation means is divided into a plurality of substrates, and each pixel region is provided on a separate substrate for each light source group including a corresponding light source.
[0107]
  ThisSaidIn addition to the effect of the configuration of any one of the above, since temperature adjustment in the light modulation means can be performed independently for each substrate, such temperature adjustment becomes easy and accuracy of temperature adjustment The effect that can be improved.
[0108]
  BookThe exposure apparatus according to the present invention has a configuration in which each substrate of the light modulation means is arranged in a space including a corresponding light source group.
[0109]
  ThisSaidIn addition to the effect of the configuration, since the movement of heat between the substrates is almost completely prevented, the temperature adjustment of each substrate in the light modulation means can be performed more easily and accurately. Play.
[0110]
  BookThe exposure apparatus according to the invention has a configuration in which each pixel portion in the light modulation unit controls transmission / blocking of light by changing a voltage applied to the liquid crystal.
[0111]
  ThisSaidIn addition to the effect of the configuration of any one of the above, the exposure image can be controlled with high accuracy, and an exposure image with excellent image quality can be provided.
[0112]
  The present inventionThe photo processing equipmentSaidThe exposure apparatus according to any one of the above, a developing unit that develops the photosensitive material exposed by the exposure apparatus by using a developing solution, and a photosensitive that has been developed in the developing unit. And a drying unit that dries the material.
[0113]
  As a result, exposure processing, development processing, and drying processing for photosensitive materials can be performed continuously under a centralized control, so a large number of photos can be printed continuously without burdening the user. There is an effect that can be done.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing a schematic configuration of a printing unit provided in a photographic processing apparatus according to an embodiment of the present invention.
FIG. 2 is a perspective view showing a schematic configuration of the photographic processing apparatus.
FIG. 3 is an explanatory diagram showing a schematic configuration of an exposure unit and a photographic paper storage unit included in the photographic apparatus.
FIG. 4 is a plan view showing a schematic configuration of an LCS array provided in the printing section.
FIG. 5 is a perspective view showing a schematic configuration of a conventional printing apparatus.
FIG. 6 is a plan view showing a schematic configuration of an LCS array provided in a conventional printing apparatus.
[Explanation of symbols]
    1 Exposure section
    2 photographic paper storage
    3 Development section
    4 Drying section
    5 PC
    6 Printing section (exposure equipment)
  11R / 11G / 11B Light source
  12A / 12B LCS array (light modulation means)
  13 Rod lens plate (projection means)
  14R / 14G / 14B R pixel unit / G pixel unit / B pixel unit
  15R / 15G / 15B Driver IC
  18R / 18G / 18B R pixel area / G pixel area / B pixel area
  19 Reflection mirror
  20A / 20B Temperature controller (temperature adjustment means)
  21 Shield plate
  22 Case

Claims (10)

An exposure apparatus that performs scanning exposure by relatively moving a photosensitive material,
A plurality of light sources each emitting monochromatic light having different wavelengths,
A light modulation unit provided with a pixel region formed of a plurality of pixel units for controlling transmission / blocking of light according to image information, corresponding to the plurality of light sources,
The plurality of light sources are divided into a plurality of light source groups according to the amount of heat generated during light emission, and the light source groups are spatially separated from each other .
An exposure apparatus characterized in that all light sources having the same light emission principle are included in the same light source group . 2. An exposure apparatus according to claim 1, wherein temperature adjusting means for adjusting the temperature in the space is provided in the space including the light source groups. 3. The exposure apparatus according to claim 1, wherein the temperature adjusting means is a Peltier element that moves heat from one surface side to the other surface side when an electric current is applied. 4. The exposure apparatus according to claim 3, wherein the Peltier element is provided with a heat radiating member on a surface opposite to the space. 5. The exposure apparatus according to claim 1, wherein the plurality of light sources are arranged in one housing, and a shielding plate is provided between spaces in which the light source groups are included. 6. The exposure apparatus according to claim 1, further comprising: a light source group including a light source configured by LEDs; and a light source group including a light source configured by an FL tube. 7. The light modulation unit according to claim 1, wherein the light modulation unit is divided into a plurality of substrates, and each pixel region is provided on a separate substrate for each light source group including a corresponding light source. The exposure apparatus according to one item. 8. An exposure apparatus according to claim 7, wherein each substrate of said light modulation means is arranged in a space including a corresponding light source group.   Projection means for projecting the light emitted from the light modulation means onto the photosensitive material, and the projection means emits light from the pixel portion in the light modulation means existing on the incident-side focal length. The exposure apparatus according to any one of claims 1 to 8, wherein projection is performed on a photosensitive material disposed on a focal length on an emission side without changing a relative position. 10. A developing unit that develops a photosensitive material exposed by the exposure apparatus according to claim 1 by using a developing solution, and a photosensitive that is developed in the developing unit. A photographic processing apparatus comprising a drying unit for drying the material.

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