JP2009109026A - Drying device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drying device of high thermal efficiency. <P>SOLUTION: A drying portion 60 comprises a conveying portion 61 for conveying printing paper in a housing 73, a porous duct 74 for supplying the heated air toward a conveying path by the conveying portion 61, and a circulating mechanism for circulating the air WA supplied by the porous duct 74 to the porous duct 74, and not circulating the air WB supplied toward the conveying path, to the porous duct 74. A partitioning member 79 having a horizontal wall portion 79a disposed corresponding to between pores 74a of lower four stages and pores 74a of upper three stages of the porous duct 74, is disposed at a side opposite to the porous duct 74 with respect to the conveying path in the housing 73. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a drying apparatus that performs a drying process on a medium in a photographic processing apparatus.

In the photographic processing apparatus, development, fixing, washing, and the like are performed while transporting a medium such as a film or photographic paper, and then the medium is sent to a drying device disposed downstream in the transport direction of the photographic processing apparatus. In this drying apparatus, the medium subjected to processing such as development is blown with hot air while being transported along the transport path of the transport section, and then discharged onto the conveyor. When measuring the density of the image formed on the medium, the medium dried by the drying device is sent to a density measuring device arranged adjacent to the drying device (see, for example, Patent Document 1). . Here, in the drying apparatus, the heated air blown out toward the conveyance path of the medium is configured to circulate to the blowing portion by a blower such as a fan (for example, see Patent Document 2).
JP 2007-171313 A JP 2002-40622 A

  However, in the above drying apparatus, the heated air blown out toward the conveyance path circulates while being mixed with the air in the drying apparatus. Therefore, particularly when the volume of the drying apparatus is large, the temperature of the circulating air decreases. Large, it takes time to raise the temperature, and the thermal efficiency becomes very poor. Further, when the density measuring device is disposed adjacent to the drying device, the density measuring device accurately measures the density of the image formed on the medium under the influence of heat from within the drying device. There are times when you can't.

  Therefore, an object of the present invention is to provide a drying apparatus with good thermal efficiency.

Means for Solving the Problems and Effects of the Invention

  The drying apparatus of the present invention is directed to a part of the transport path by the transport unit that transports the medium in the housing, the air blowing unit that blows out heated air toward the transport path by the transport unit, and the air blowing unit. And a circulation mechanism that does not circulate the air blown toward the other part of the conveyance path to the air blowing part.

  According to this configuration, when the medium is not transported, only the air blown toward a part of the transport path circulates to the air blowing part, so the air blown toward a part of the transport path is It will circulate without mixing with other air. Therefore, the temperature drop of the circulating air can be reduced to shorten the temperature raising time, and the thermal efficiency of the drying apparatus can be improved. In addition, when the medium is being transported, the air blown from the air blowing portion toward the transport path gets wet by hitting the surface of the medium, and then circulates after diffusing in the vicinity of the surface. . In the above configuration, the humid air circulates only in a part of the transport path in the housing, so that it is possible to suppress a decrease in the drying efficiency of the drying device.

  In the drying apparatus of the present invention, the air blowing section is disposed on one surface side of the transport path in the casing, and is disposed on the other surface side of the transport path in the casing, and the part of the transport path. And a partition member having a wall portion corresponding to a boundary between the first portion and the other portion.

  According to this configuration, the air blown to a part of the conveyance path and the air blown to other parts of the conveyance path are not mixed by the partition member. Only the generated air can be easily circulated to the air blowing section.

  In the drying apparatus of the present invention, the other part of the transport path may be a part corresponding to the downstream side in the transport direction with respect to the part.

  The drying apparatus of the present invention includes a density measuring device that is disposed outside the housing and on the opposite side of the air blowing portion with respect to the transport path, and measures the density of an image formed on the medium. In addition, a heat insulating material may be disposed in the vicinity of the end portion on the concentration measuring device side in the housing.

  According to this configuration, since the heat from the inside of the drying device can be suppressed by the heat insulating material, the thermal efficiency can be improved. In addition, since heat from the inside of the drying device can be prevented from reaching the density measuring device arranged outside the drying device, the density measuring device accurately measures the density of the image formed on the medium. be able to.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic configuration diagram of a photographic processing apparatus provided with a drying unit (drying apparatus) according to an embodiment of the present invention.

  The photographic processing apparatus 1 provided with the drying unit 60 according to the present embodiment is a photographic processing apparatus employing a digital scanning exposure method using a laser beam, as shown in FIG. A printing unit 50, a drying unit 60, and a density measuring unit (density measuring apparatus) 80 are provided.

  The image input unit 20 reads an image recorded on each frame of the developed film, performs a digital conversion process on the read image data, reads a digital image data recorded on an image recording medium such as a flash memory, and the like. Various processes are performed, and the read image data is transmitted to the printing unit 50. In the printing unit 50, mainly photographic paper (medium) 2 is subjected to processing such as exposure processing, development processing, and bleach-fixing processing based on the image data received from the image input unit 20, and is sent to the drying unit 60. It is done. In the drying unit 60, the photographic paper 2 discharged from the printing unit 50 is dried, and the photographic paper 2 discharged from the discharge port is sorted for each order. Further, the density measuring unit 80 can appropriately measure the density of the image formed on the surface of the photographic paper 2.

  As shown in FIG. 1, the image input unit 20 includes a monitor 21, a keyboard 22, a mouse 23, a computer unit 30, and a scanner 40.

  On the monitor 21, a GUI (Graphical User Interface) for various controls and an image to be processed are displayed, and various information regarding the photographic processing apparatus 1 is displayed and notified to the operator. The keyboard 22 and the mouse 23 are used for performing an input operation on the photo processing apparatus 1.

  The computer unit 30 is connected to the monitor 21, the keyboard 22, and the mouse 23, and controls the operation of each unit included in the scanner 40 and the print unit 50, and the input / output of image data. The image data stored in the image recording medium such as is read through a media reader (not shown).

  In the scanner 40, an image reading process recorded on each frame of the developed film and a digital conversion process on the read image data are performed, and the read image data is transmitted to the computer unit 30.

  As shown in FIG. 1, the print unit 50 includes two photographic paper magazines 51, a sheet cutter 52, a back print unit 53, a print exposure unit 54, a pressure-conveying conveyance roller pair 57, and a chucker-type conveyance unit 58. And a treatment tank unit 55 and a squeeze rack 59.

  The two photographic paper magazines 51 are provided inside the printing unit 50, and each roll-shaped photographic paper 2 is accommodated one by one, and a necessary amount of the photographic paper 2 is appropriately drawn out by the pressure-conveying roller pair 57. The sheet cutter 52 is disposed on the downstream side of the plurality of press-contact conveyance roller pairs 57 that draw out the photographic paper 2 from the photographic paper magazine 51, and cuts the photographic paper 2 drawn out from the photographic paper magazine 51 into a desired print size. .

  The back print unit 53 is disposed on the downstream side of the sheet cutter 52, and print processing information such as color correction information and a frame number is provided on the back side of the photographic paper 2 cut to a desired print size by the sheet cutter 52. To print.

  The print exposure unit 54 is arranged so as to be adjacent to the chucker type conveyance unit 58 arranged on the downstream side of the back print unit 53, and is on the surface side of the photographic paper 2 cut to a desired print size or a test print size. Next, the image is exposed.

  The pressure-conveying and conveying roller pair 57 pulls out the roll-shaped photographic paper 2 stored in the photographic paper magazine 51 disposed inside the printing unit 50, and the chucker-type conveying unit 58 prints the printed image cut to a desired size or the like. The paper 2 is conveyed at a conveyance speed corresponding to various processes. The pressure-conveying roller pair 57 is configured by combining two rollers, and presses the photographic paper 2 while the two rollers rotate, so that the photographic paper 2 passes through the gap between the two rollers and moves downstream. Be transported. The chucker-type transport unit 58 transports the photographic paper 2 that has been cut to a desired size or the like by pinching the downstream end (front end side).

  The processing tank unit 55 is arranged adjacent to a plurality of pressure-contacting roller pairs 57 arranged on the downstream side of the print exposure unit 54, and stores a color developing tank 55a for storing the color developing processing liquid and a bleach-fixing processing liquid. It has a bleach-fixing tank 55b for storing and a stable processing tank 55c for storing a stable processing liquid. The exposed photographic paper 2 is conveyed through the color developing tank 55a, the bleach-fixing tank 55b, and the stabilization processing tank 55c in this order, so that a desired image is printed on the photographic paper. 2 formed on the surface.

  The squeeze rack 59 is disposed between the processing tank unit 55 and the drying unit 60, and has a function of removing moisture on the surface of the photographic paper 2 attached during conveyance of the processing tank unit 55.

  The drying unit 60 is disposed on the downstream side of the processing tank unit 55, and is transported by the transport unit 61 that transports the photographic paper 2 processed in the housing 73 along the transport path, and the transport unit 61. The heating unit 62 for heating the photographic paper 2 (see FIG. 4), the conveyor 56 for conveying the photographic paper 2 dried by the heating unit 62, and the photographic paper 2 conveyed by the conveyor 56 are sorted in order units. And a sorter (not shown). The drying unit 60 of the present embodiment blows warm air generated by a blower or the like onto the photographic paper 2 that has been immersed in various processing liquids and processed in the processing tank unit 55 and then passed through the squeeze rack 59. The photographic paper 2 is dried. Thereafter, the dried photographic paper 2 is dropped and conveyed from the carry-out port onto the conveyor 56 and conveyed toward the sorter.

  The density measuring unit 80 is disposed below the conveyor 56, and includes a casing 81, a density meter 82, a conveyance roller pair 83, and a discharge unit 84. The casing 81 is provided to keep the temperature and brightness in the concentration measuring unit 80 in a constant state, and is formed of, for example, a synthetic resin member. The densitometer 82 includes a filter and a CCD designed to have a transmission characteristic for light of a specific wavelength, and transmits the density measurement result of the photographic paper 2 to the computer unit 30. The transport roller pair 83 transports the densitometer 82 so that the density of the photographic paper 2 can be measured. Then, the photographic paper 2 for which the density measurement by the densitometer 82 is completed is transported to the discharge unit 84 by the transport roller pair 83.

  Next, a schematic configuration of the drying unit 60 of the photographic processing apparatus 1 will be described with reference to FIGS. FIG. 2 is a cross-sectional view of a drying unit and a density measurement unit provided in the photographic processing apparatus of FIG. FIG. 3 is a cross-sectional view taken along the line AA in the drying unit of FIG. FIG. 4 is a cross-sectional view taken along line BB in the drying unit of FIG.

  As shown in FIG. 2, the transport unit 61 has two transport roller pairs 63 and 64, a turn roller 65, a first roller 66, and a second roller from the upstream side in the transport direction toward the downstream side in the transport direction. The housing 73 includes a roller 67, a plurality of conveyance roller pairs 68, a turn mechanism 69, a carry-out roller pair 71, and a plurality of conveyance roller pairs 72.

  The two conveyance roller pairs 63 and 64 are each composed of two drive rollers arranged with a gap serving as a conveyance path for the photographic paper 2. The photographic paper 2 sent to the drying unit 60 is conveyed to a turn roller 65 on the downstream side in the conveying direction by a pair of conveying rollers 63 and 64 that are rotationally driven. The surfaces of the conveyance roller pairs 63 and 64 are covered with, for example, foam or cloth.

  The turn roller 65 is for changing the conveyance direction of the photographic paper 2 and conveying it downstream. As shown in FIG. 2, the turn roller 65 changes the conveyance direction of the photographic paper 2 downstream of the conveyance roller pair 64 in the conveyance direction. Change vertically upwards. The turn roller 65 is a roller having a diameter larger than that of the first roller 66 and the second roller 67, and is rotationally driven by a drive unit (not shown). Thus, the drying unit 60 can be dried while changing the transport direction of the photographic paper 2 by providing the turn roller 65 therein, so that the drying device performs a drying process while transporting the photographic paper 2 only in one direction. In comparison, the size of the drying device can be reduced.

  The first roller 66 is used as a pair with the turn roller 65 to change the conveyance direction of the photographic paper 2, and between the turn roller 65 and the photographic paper 2 conveyed from the upstream side in the conveyance direction. It arrange | positions closely so that the clearance gap which a front-end | tip enters may be formed.

  The second roller 67 is paired with the turn roller 65 to change the conveyance direction of the photographic paper 2 and is conveyed between the second roller 67 and the turn roller 65 at the downstream side of the first roller 66 in the conveyance direction. It arrange | positions so that the clearance gap in which the front-end | tip of the photographic paper 2 conveyed from a direction upstream may approach may be formed.

  The plurality of transport roller pairs 68 are for transporting the photographic paper 2 that has passed through the gap between the turn roller 65 and the second roller 67 upward in the vertical direction. The surfaces of the conveyance roller pair 68 are covered with, for example, foam material, cloth, or the like.

  The turn mechanism 69 is for changing the conveyance direction of the photographic paper 2 and conveying the photographic paper 2 to the downstream side. Above the plurality of conveyance roller pairs 68, the turn paper 69 is placed on the conveyor by a direction change guide (not shown). In the case of discharging, the conveyance direction of the photographic paper 2 is changed to a substantially horizontal direction (direction toward the carry-out roller pair 71), while in the case of conveying the photographic paper 2 to the density measuring unit 80, the conveyance direction of the photographic paper 2 Is changed downward in the vertical direction (direction toward the conveying roller pair 72). The turn mechanism 69 includes a large-diameter roller 69a and a plurality of small-diameter rollers 69b, and the photographic paper 2 passes through the gaps between the rollers 69a and 69b.

  The carry-out roller pair 71 is for discharging the photographic paper 2 dried in the drying unit 60 onto the conveyor 56. The plurality of conveyance roller pairs 72 convey the photographic paper 2 dried in the drying unit 60 toward the hole 79c of the partition member 79 for discharging the photographic paper 2 to the density measuring unit 80. The surfaces of the conveyance roller pair 68 are covered with, for example, foam material, cloth, or the like. The casing 73 has a discharge port 73a on the downstream side of the conveyance path (upper left side in FIG. 2), and the photographic paper 2 is discharged onto the conveyor 56 through the discharge port 73a.

  As shown in FIG. 3, the heating unit 62 includes a perforated duct (air blowing unit) 74 and a circulation mechanism 75.

  The perforated duct 74 is for blowing air toward the conveyance path of the photographic paper 2, and is disposed on the one surface side (right side in FIG. 2) in the housing 73, and has a heating chamber 78 (described later). The conveyance unit 61 is partitioned. Further, the perforated duct 74 has a plurality of holes 74a, and in this embodiment, as shown in FIG. . The heated air is blown out from the plurality of holes 74a of the perforated duct 74 toward the conveyance path.

  The circulation mechanism 75 includes a heater unit 76 that dries the photographic paper 2 being conveyed, a blower 77, a heating chamber 78, and a partition member 79. The circulation mechanism 75 circulates the air blown out from the four-stage holes 74a on the lower side of the perforated duct 74 toward the conveying path in the casing 73 of the drying unit 60 to the perforated duct 74, and The air blown out from the upper three-stage holes 74 a of the perforated duct 74 toward the conveyance path is not circulated to the perforated duct 74. In other words, the circulation mechanism 75 circulates only the air blown toward the upstream side (a part of the conveyance path) of the conveyance path in the casing 73 to the perforated duct 74 and the downstream side (conveyance path). The air blown out toward the other part is not circulated through the perforated duct 74.

  The heater unit 76 and the blower 77 are arranged in parallel on one side of the drying unit 60. The upper portion of the heater unit 76 is positioned between the third-stage hole 74 a and the fourth-stage hole 74 a from above the perforated duct 74, and the lower part is below the lowermost hole 74 a of the perforated duct 74. positioned. The heater unit 76 is disposed upstream of the suction side of the blower 77 and heats the air sucked by the blower 77. The blower 77 has substantially the same height as the heater unit 76 and is blown out from the perforated duct 74 toward the conveyance path of the photographic paper 2 and then sucks the air WA heated by the heater unit 76. Air is blown to the heating chamber 78.

  The heating chamber 78 is on one side (right side in FIG. 2) of the conveyance path in the housing 73, is on the opposite side of the conveyance path with respect to the perforated duct 74, and is heated air sucked by the blower 77. Is about to be sent. Here, as shown in FIG. 3, the heating chamber 78 is formed so that its cross-sectional area decreases as the distance from the blower 77 increases.

  In FIG. 3, the partition member 79 is disposed on the opposite side of the perforated duct 74 (the other side of the transport path) with respect to the transport path in the housing 73. The partition member 79 has a horizontal wall portion 79a and a vertical wall portion 79b. The horizontal wall portion 79 a is disposed so as to correspond between the lower four-stage holes 74 a of the perforated duct 74 and the upper three-stage holes 74 a, and the lower four-stage holes 74 a of the perforated duct 74. The air blown out from the holes 74 a and the air blown out from the three-stage holes 74 a on the upper side of the perforated duct 74 are restrained from being mixed. The vertical wall portion 79 b has a hole 79 c through which the photographic paper 2 passes when being conveyed to the density measuring unit 80. In addition, a heat insulating material is disposed on the entire partition member 79. In addition, in FIG. 4, the partition member 79 is shown with the dashed-dotted line.

  The conveyor 56 is disposed above the printing unit 50 and conveys the photographic paper 2 discharged after being dried by the heating unit 62 in the direction of the sorter. The sorter has a plurality of trays arranged in the vertical direction on the front side of the printing unit 50, and distributes the photographic paper 2 conveyed by the conveyor 56 to each tray, for example, in order units.

  Next, the flow of air in the drying unit 60 of the present embodiment will be described with reference to FIG. FIG. 5 is a view for explaining the flow of air in the drying section in the section taken along the line CC of FIG.

  When the photographic paper 2 is not transported by the transport unit 61, the air WA blown out from the four-stage holes 74a on the lower side of the perforated duct passes through the transport path and passes through the horizontal wall of the partition member 79. It flows in the space below the portion 79a. Then, the air WA is heated by passing through the heater unit 76 by the suction force of the blower 77, and then is sent into the heating chamber 78 through the heating chamber entrance 78 a. Thereafter, the heated air sent into the heating chamber 78 is circulated by being blown out from the hole 74a of the perforated duct 74 toward the conveyance path.

  On the other hand, the air WB blown out from the three-stage holes 74 a on the upper side of the perforated duct passes through the transport path and flows into the space above the horizontal wall 79 a of the partition member 79. Thereafter, the air WB is discharged to the outside of the housing 73 through the discharge port 73a of the housing 73.

  On the other hand, when the photographic paper 2 is transported by the transport unit 61, the air WA blown out from the four-stage holes 74a on the lower side of the perforated duct is processed by the transported photographic paper 2. Moisturizes the surface. The moist air WA diffuses in the vicinity of the surface of the photographic paper 2 and then flows into the space below the horizontal wall 79 a while wrapping around the photographic paper 2. After that, the moist air WA is heated by passing through the heater unit 76 by the suction force of the blower 77, and after the moisture previously contained is removed, it passes through the heating chamber entrance 78a and enters the heating chamber 78. It is sent. Thereby, the heated air sent into the heating chamber 78 is blown out from the hole 74a of the perforated duct 74 toward the conveyance path.

  On the other hand, the air WB blown out from the three-stage holes 74a on the upper side of the perforated duct hits the surface on which the processing of the transported photographic paper 2 is performed, and gets wet. The humid air WB diffuses in the vicinity of the surface of the photographic paper 2 and then flows into the space above the horizontal wall 79 a of the partition member 79. Thereafter, the humid air WB is discharged to the outside of the housing 73 through the discharge port 73 a of the housing 73.

  As described above, when the photographic paper 2 is not transported, only the air WA blown toward a part of the transport path is circulated to the perforated duct 74, so that it blows toward a part of the transport path. The air WA thus circulated without being mixed much with other air WB. Accordingly, the temperature drop of the circulating air can be reduced to shorten the temperature raising time, and the thermal efficiency of the drying unit 60 can be improved. Further, when the photographic paper 2 is being transported, the air WA blown out from the perforated duct 74 toward the transport path is dampened by hitting the surface of the photographic paper 2, and thereafter, the air WA Circulate after spreading. In the above configuration, since the humid air WA circulates only in a part of the conveyance path in the housing 73, it is possible to suppress a decrease in the drying efficiency of the drying unit 60.

  Further, the air WA blown to a part of the transport path and the air WB blown to the other part of the transport path are not mixed by the partition member 79, and thus blown out to a part of the transport path. Only the generated air WA can be easily circulated to the perforated duct 74.

  Moreover, since it can suppress by the heat insulating material that the heat | fever from the inside of the drying part 60 is discharge | released outside, thermal efficiency can be improved. Further, since heat from the inside of the drying unit 60 can be prevented from reaching the density measuring unit 80 disposed outside the drying device, the density of the image formed on the photographic paper 2 is determined in the density measuring unit 80. Can be measured accurately.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various design changes can be made as long as they are described in the claims. For example, in the above-described embodiment, the heat insulating material is disposed on the entire partition member 79, but may be disposed on only a part thereof. Further, the heat insulating material may be disposed on another member separate from the partition member 79.

It is a schematic block diagram of the photographic processing apparatus provided with the drying part (drying apparatus) which concerns on embodiment of this invention. FIG. 2 is a cross-sectional view of a drying unit and a concentration measurement unit (density measurement device) provided in the photographic processing apparatus of FIG. It is the sectional view on the AA line in the drying part of FIG. FIG. 3 is a cross-sectional view taken along line BB in the drying unit of FIG. 2. It is a figure explaining the flow of the air in the drying part in the CC sectional view of FIG.

Explanation of symbols

1 Photo processing device 2 Printing paper (medium)
60 Drying section (drying equipment)
61 Conveying unit 62 Heating unit 74 Perforated duct (air blowing unit)
75 Circulating mechanism 79 Partition member 79a Wall 80 Concentration measuring unit (concentration measuring device)

Claims (4)

A transport unit for transporting the medium in the housing;
An air blowing section that blows out heated air toward the conveyance path by the conveyance section;
Circulation that circulates air blown toward a part of the conveying path by the air blowing part to the air blowing part and does not circulate air blown toward the other part of the conveying path to the air blowing part. A drying device comprising a mechanism. The air blowing portion is disposed on one surface side of the conveyance path in the housing,
The partition member which is arrange | positioned in the other surface side of the said conveyance path | route in the said housing | casing, and has a wall part corresponding to the boundary of the said part of the said conveyance path | route and the said other part is provided. Drying equipment.   The drying apparatus according to claim 1, wherein the other part of the transport path is a part corresponding to a downstream side in the transport direction with respect to the part. A density measuring device that is disposed outside the housing and opposite to the air blowing portion with respect to the transport path, and that measures the density of an image formed on the medium;
The drying apparatus according to any one of claims 1 to 3, wherein a heat insulating material is disposed in the vicinity of an end portion on the concentration measuring device side in the housing.

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