The present application claims priority under 35 U.S.C. § 119 to Japanese Patent Application No. 2017-239846 filed Dec. 14, 2017, the contents of which are hereby incorporated herein by reference in their entirety.
The present disclosure relates to a sheet type determining device and an image forming device, particularly to a technology which increases an accuracy in determining the sheet type while suppressing occurrence of failures when thin paper is used for recording sheets.
Recently, for electrographic image forming devices, image forming is being performed using various types of recording sheets. For example, when thick paper is used, as heat capacities of the recording sheets are large and heat-fixings of toner images take time, system speeds slow down compared to when regular paper is used. As the image forming needs to be controlled according to the sheet types of the recording sheets, the sheet types of the recording sheets must be determined before starting the image forming.
The sheet types of the recording sheets can be designated by a user, for example, by selecting a paper feed cassette housing the recording sheets. However, if the selected paper feed cassette houses a sheet type different from the recording sheet the user intends to choose, the image forming for the designated sheet type cannot be performed. Moreover, checking the sheet types of the recording sheets housed in the paper feed cassette for designating sheet types is not convenient for the user.
In view of this problem, a technology has been proposed in which ultrasonic waves or laser light are radiated on the recording sheets, so that the sheet types are automatically determined by detecting transmittance and reflectance of the recording sheets. Thus, the image forming according to the sheet types is performed without troubling the user.
However, switching controls for the image forming according to the sheet types of the recording sheets requires some time, and thus, preferably, the sheet types are determined immediately after the recording sheets are fed out from the paper feed cassette so as to maintain productivity of the image forming processing without decreasing the number of the recording sheets printed per unit time.
Recently, multi-function peripherals (MFPs) which include multiple paper feed cassettes and can also feed the recording sheets from a manual feed tray have become popular. In these MFPs, the recording sheets enter a sheet conveyance path from various directions, and thus positional relationships between the recording sheet and an ultrasonic sensor or a photosensor are not always constant in the sheet conveyance path. This may lead to erroneous determinations of the sheet types.
In view of this problem, a structure is proposed in which a pressing member such as an arm is in pressure contact with a sheet guide which forms the sheet conveyance path, and sheets are fed between the pressing member and the sheet guide in pressure contact, so that the recording sheet moving through the sheet conveyance path is pressed against the sheet guide (see JP2016-117560). By taking such a measure to regulate a conveyance position of the recording sheet at a sensor position on the sheet conveyance path, the positional relationship between the sensor and the recording sheet is stabilized, and thus occurrences of the erroneous determinations of the sheet types are reduced.
However, with the above described configuration, when thin paper having little firmness is used for the recording sheet, if a pressure contact force applied to the pressing member and the sheet guide is excessive, the recording sheet cannot enter between the pressing member and the sheet guide, and thus a sheet jam may occur. Naturally, the sheet jam prevents the recording sheet from moving to the sensor position, and thus the sheet type of the recording sheet cannot be identified.
Alternatively, when the pressure contact force applied to the pressing member and the sheet guide is insufficient, and when thick paper is used for the recording sheet, the conveyance position of the recording sheet cannot be fully regulated because of rigidity of thick paper, and thus the occurrences of the erroneous determinations of the sheet types cannot be reduced.
The present disclosure has been made in consideration of the above-described problems, and an object of the present disclosure is to provide a sheet type determining device and an image forming device which increase a determination accuracy of the sheet types while suppressing occurrence of failures when thin paper is used for recording sheets.
In order to achieve the above mentioned object, a sheet type determining device reflecting one aspect of the present disclosure is a sheet type determining device including a guide that guides a sheet along a sheet conveyance path to a destination, the sheet conveyance path being between a first guide surface and a second guide surface disposed facing each other across an interval; a determiner that determines a sheet type when the sheet is in the sheet conveyance path, without having contact with the sheet in conveyance; and one or more regulators, each of the regulators regulating a displacement range of the sheet in a direction of the interval between the first and the second guide surfaces, at a detection position (determining position) in the sheet conveyance path where the determiner determines the sheet type, wherein each of the regulators is a member that protrudes in an arc shape from the first or the second guide surface toward the guide surface opposite, and each of the regulators is spaced from the guide surface or another one of the regulators opposite in a direction perpendicular to a surface of the sheet.
The advantages and features provided by one or more embodiments of the invention will become more fully understood from the detailed description given hereinbelow and the appended drawings which are given by way of illustration only, and thus are not intended as a definition of the limits of the invention. In the drawings:
Hereinafter, one or more embodiments of the present disclosure will be described with reference to the drawings. However, the scope of the invention is not limited to the disclosed embodiments.
First, a configuration of an image forming device according to the present embodiment will be described.
As in
The image forming unit 100 includes a controller 120. The controller 120 performs image processing on the polychromatic image data generated by the image reading unit 150, and makes the image forming unit 100 perform polychromatic image forming processing using the polychromatic image data. The controller 120 may accept a print job from an external device such as a personal computer (PC) to perform the image forming processing.
The image forming processing is performed by forming yellow (Y), magenta (M), cyan (C) and black (K) toner images respectively by four imaging units 130Y, 130M, 130C, and 130K. The imaging units 130Y, 130M, 130C, and 130K respectively include photosensitive drums 131Y, 131M, 131C and 131K, laser scanning optical units 132Y, 132M, 132C and 132K, and developing units 133Y, 133M, 133C, and 133K. Each of the imaging units 130Y, 130M, 130C, and 130K further include a charging unit (not illustrated) and a cleaning unit (not illustrated).
The charging unit uniformly charges outer circumferential surfaces of the photosensitive drums 131Y, 131M, 131C, and 131K, and the laser scanning optical units 132Y, 132M, 132C, and 132K apply laser lights modulated according to digital image data for each color component to the outer circumferential surfaces of the photosensitive drums 131Y, 131M, 131C, and 131K. As a result, electrostatic latent images are formed.
The developing units 133Y, 133M, 133C, and 133K respectively supply Y, M, C, and K toners and develop the electrostatic latent images to form Y, M, C, and K toner images. The imaging units 130Y, 130M, 130C, and 130K are disposed directly under and along an intermediate transfer belt 121.
Primary transfer rollers 134Y, 134M, 134C, and 134K are respectively disposed in positions facing the photosensitive drums 131Y, 131M, 131C, and 131K, having the intermediate transfer belt 121 disposed therebetween. A primary transfer voltage is applied to the primary transfer rollers 134Y, 134M, 134C, and 134K, and causes the toner images carried on the photosensitive drums 131Y, 131M, 131C, and 131K to be electrostatically transferred (primary transfer) onto the belt 121 such that the toner images overlap each other. As a result, a polychromatic toner image is formed.
The intermediate transfer belt 121 is an endless belt, which is tensioned by a driving roller 122, a driven roller 123, and the primary transfer rollers 134Y, 134M, 134C, and 134K. The intermediate transfer belt 121 is driven by a motor 124 driving the driving roller 122 to rotate in a direction indicated by an arrow A. A secondary transfer roller 125 is in pressure contact with the driving roller 122 via the intermediate transfer belt 121 to form a secondary transfer nip 126 therebetween.
Paper feed cassettes 141a and 141b which store the recording sheets S in stacks are installed in a lower part of the image forming unit 100. Sheet feed rollers 142a and 142b respectively feed out the recording sheets S from the paper feed cassettes 141a and 141b. Handling rollers 143a and 143b prevent double feeding when the recording sheets S are fed out.
The recording sheets S fed out from the paper feed cassettes 141a and 141b are conveyed to sheet conveyance path 145 respectively via sheet conveyance paths 211a and 211b. The recording sheets S supplied from a manual feed tray (not illustrated) are conveyed from sheet conveyance path 212 to sheet conveyance path 145 by a manual feed roller 213. When each one of the recording sheets S in conveyance thus reaches a resistance roller pair 144, the recording sheet S is stopped by the resistance roller pair 144 which is stationary, which buckles the recording sheet S so that a skew is corrected.
Then, matching the timing with which the polychromatic toner image is conveyed to the secondary transfer nip 126 by the rotation of the intermediate transfer belt 121, the resistance roller pair 144 rotates to convey the recording sheet S to the secondary transfer nip 126. A secondary transfer voltage is applied to the secondary transfer roller 125, and the polychromatic toner image is electrostatically transferred (secondary transfer) from the intermediate transfer belt 121 onto the recording sheet S.
After the secondary transfer, residual toners on the intermediate transfer belt 121 are scraped off and disposed by a cleaning unit 135. The recording sheet S is conveyed to a fixing unit 25. The fixing unit 25 includes a heating roller 136, a fixing belt 137, a fixing roller 138, and a pressure roller 139. The heating roller 136 is heated by a heater (not illustrated), and heats the fixing belt 137 to a fixing temperature.
The fixing belt 137 is an endless belt and is rotated by the fixing roller 138. The fixing roller 138 is rotationally driven by a motor (not illustrated). The pressure roller 139 is in pressure contact with the fixing roller 138 via the fixing belt 137 to form a fixing nip therebetween. The polychromatic toner image is thermally fixed on the recording sheet S when the recording sheet S is fed through the fixing nip.
After the polychromatic toner image is fixed on, the recording sheet S is discharged to a discharge tray 129 above the image forming unit 100 by discharge rollers 128. In a case of duplex printing, the sheet conveyance direction of the recording sheet S is reversed by the discharge rollers 128, and the recording sheet S is conveyed to a sheet inversion path 146 by a hook portion 221, and then to the resistance roller pair 144 by pairs of conveyance rollers 223 and 224. Then, the secondary transfer of the polychromatic toner image is performed on the reverse side of the recording sheet S at the secondary transfer nip 126.
In addition, the image forming unit 100 includes an operation panel 140 which presents information to users of the image forming device 1 and receives input of instructions from the users.
Next, a configuration for determining sheet types will be described.
As in
As in
Hereinafter, a passing position 310 of the recording sheet S on an optical path which is a path of light emitted from the light emitting element 301 of the first sensor 201t and being from the first light emitting element 301 of the first sensor 201t to the light receiving element 303 of the second sensor 201r, is referred to as a sheet detection position 310.
For each of the recording sheets S, while a leading end of the recording sheet S passes through the sheet detection position 310 and reaches the resistance roller pair 144, the photosensor 201 uses the light receiving element 302 of the first sensor 201t to detect for multiple times an amount of reflected light of emitted light reflected by the recording sheet S. The controller 120 determines an average value referring to detected values of the amount of reflected light.
Similarly, for each of the recording sheets S, while a leading end of the recording sheet S passes through the sheet detection position 310 and reaches the resistance roller pair 144, the photosensor 201 uses the light receiving element 303 of the second sensor 201t to detect for multiple times an amount of transmitted light of the emitted light transmitted through the recording sheet S. The controller 120 determines an average value referring to detected values of the amount of transmitted light.
The controller 120 determines the sheet type from the average value of the amount of reflected light and the average value of the amount of transmitted light.
Rollers 200 are disposed at both sides of the second sensor 201r in a width direction of the recording sheet S (a direction on a plane of the recording sheet S which is orthogonal to a conveyance direction of the recording sheet S, hereinafter referred to as “CD direction”) so as to protrude from the guide surface 202r. Rotation axes of the rollers 200 are disposed parallel to the CD direction. As in
As the interval 202g between the guide surface 202t and the rollers 200 is 1 mm or more, and the rollers 200 are rotated following the recording sheet S in conveyance, the recording sheet S can easily pass between the guide surface 202t and the rollers 200 even if the recording sheet S is thin and has low rigidity. Further, the rollers 200, in the CD direction, do not extend to end portions of the recording sheet S in the CD direction, regulate a conveyance position of the recording sheet S only in a vicinity of the second sensor 201r, and do not interfere with the recording sheet S in areas outside of the rollers 200 in the CD direction. The rollers 200 do not hinder conveyance of thin paper in this sense as well.
In at least one embodiment, each of the rollers 200 are 1 cm in length in the CD direction (hereinafter referred to as “CD length”), but the CD length of the rollers 200 is not limited to 1 cm and may be in a different length.
In such a configuration, when the recording sheet S is fed out from the paper feed cassette 141a to the sheet conveyance path 211a and enters the sheet conveyance path 145, the recording sheet S comes into contact with the guide surface 202r due to rigidity of the recording sheet S itself, and moves along the guide surface 202r toward the resistance roller pair 144. However, an area of a sheet surface of the recording sheet S which is in the vicinity of the photosensor 201 in the CD direction is pushed by the rollers 200 to a side having the guide surface 202t. Thus, the conveyance position of the recording sheet S fed out from the paper feed cassette 141a is regulated to a side closer to the first sensor 201t.
When the recording sheet S is fed out from the paper feed cassette 141b to the sheet conveyance path 211b, the recording sheet S is arbitrarily conveyed at a side closer to either the guide surface 202r or the guide surface 202t as the sheet conveyance path 145 is substantially an extension of the sheet conveyance path 211b. However, an area of the sheet surface of the recording sheet S in the vicinity of the photosensor 201 in the CD direction is pushed by the rollers 200 toward a side having the guide surface 202t, and thus a displacement range of the conveyance position is regulated.
When the recording sheet S fed out from the manual feed tray to the sheet conveyance path 212 enters the sheet conveyance path 145, the recording sheet S comes into contact with the guide surface 202t due to rigidity of the recording sheet S itself, and moves along the surface 202t toward the resistance roller pair 144. Therefore, the recording sheet S moves along a side having the guide surface 202t without being regulated by the rollers 200.
In any of the cases, the interval is provided between the guide surface 202t and the rollers 200, and thus the recording sheet S can move toward the resistance roller pair 144 without being hindered by the rollers 200. The rollers 200 are disposed at the upstream side of the resistance roller pair 144 in the sheet conveyance path 145 and at the upstream side of the position where the sheet inversion path 146 joins the sheet conveyance path 145.
Moreover, a beam diameter of an emitted beam of the light emitting element 301 increases with a distance from the light emitting element 301. Accordingly, when the distance between the first sensor 201t and the recording sheet S is short, as in
However, a variation range of the distance between the first sensor 201t and the recording sheet S is reduced by the rollers 200, which thus stabilizes the amount of light received by the light receiving element 302 and increases the determination accuracy of the sheet types.
Next, sheet type determination processing performed by the controller 120 will be described.
As in
Further, the CPU 600 measures times using a timer 604 so as to determine timings to execute the processing. The CPU 600 uses a Network Interface Card (NIC) 605 to mutually communicate with an external device such as a Personal Computer (PC) via a Local Area Network (LAN) or the like. This allows the CPU 600 to accept the print job from the external device and to execute the accepted print job.
The light emitting element 301 and the light receiving elements 302 and 303 are connected to the CPU 600. The CPU 600 controls turning on/off the light emitting element 301, and refers to detection signals of the light receiving elements 302 and 303.
In order to determine the sheet types of the recording sheets S one by one, the CPU 600 executes processing as in
Next, when the CPU 600 detects a decrease in the amount of light received by the light receiving element 303 which indicates a leading end of the recording sheet S reaching the sheet detection position 310 (S704: YES), the CPU 600 initializes to 0 a value of a work variable n which indicates the number of times that the amount of the received light by the light receiving elements 302 and 303 have been referred to (S705), and then sets the timer to make interruptions after every lapse of time P (S706). For example, when obtaining an average value by referring to the amount of light received by the light receiving elements 302 and 303 for N times, when T expresses a time from which the leading end of the recording sheet S reaches the sheet detection position 310 to which the leading end of the recording sheet S reaches the pair of resistance roller pair 144, time P is obtained as in a mathematic expression below.
P=T÷N (1)
When a time out by the timer interruption is detected (S707: YES), the CPU 600 refers to the amount of light received by the light receiving elements 302 and 303 (S708), and records in the RAM 602 the amount of reflected light which is the amount of light received by the light receiving element 302 and the amount of transmitted light which is the amount of light received by the light receiving element 303 (S709), and increases the value of the work variable n by 1 (S710). If the value of the work variable n is less than a defined number of trials N (S711: NO), the CPU 600 proceeds to step S707 and repeats the processing above.
When the value of the work variable n is the defined number of trials N or more (S711: YES), the CPU 600 resets the timer 604 to stop making the interruptions (S712), reads out N numbers of the amount of reflected light and N numbers of the amount of transmitted light from the RAM 602 (S713), and then calculates the average values for the amount of reflected light and the amount of transmitted light (S714). Finally, the CPU 600 determines the sheet type from the average value of the amount of reflected light and the average value of the amount of transmitted light (S715), and ends the processing.
The present disclosure has been described as above based on the embodiments, but the present disclosure is not limited to the embodiments above, and the following modifications may be implemented.
(4-1) At least one embodiment above describes an example in which the rollers 200 are disposed at the guide surface 202r, but the present disclosure is not limited thereto, and arc shaped protrusions as viewed from the CD direction may be provided instead of the rollers 200. The arc shaped protrusions may be cylindrical surfaces 801 disposed on the guide surface 202r as in
When the arc shaped protrusions as viewed from the CD direction are disposed on the guide surface 202r, regardless of whether or not the arc shaped protrusions rotate following the recording sheet S, the effect of the present disclosure can be obtained if the displacement range in the direction perpendicular to the sheet surface of the recording sheet S passing through the sheet detection position 310 (direction of the interval 202g which is between the guide surfaces 202t and 202r) can be regulated.
The arc shaped protrusions may be a component separate from or integrated with the guide surfaces 202t and 202r.
(4-2) At least one embodiment above describes an example in which the rollers 200 are disposed at both sides of the second sensor 201r in the CD direction, but the present disclosure is not limited thereto, and may be modified as below.
For example, as in
In addition to the upstream side of the second sensor 201r in the sheet conveyance direction, protrusions such as rollers may be disposed at the downstream side of the second sensor 201r in the sheet conveyance direction. For example, as in
In
In this way, in comparison with an arrangement in
In
Further, in
(4-3) At least one embodiment above describes an example in which the rollers 200 are disposed at the side having the guide surface 202r, but the present disclosure is not limited thereto, and the same effect of the present disclosure may be obtained when the rollers are disposed at the side having the guide surface 202t instead of 202r. Further, as in
A path width of the sheet conveyance path 145 is smaller at the sheet detection position 310 compared to the path widths in other areas of the sheet conveyance path 145 in the direction perpendicular to the sheet surface of the recording sheet S. Thus, frictional resistance easily occurs between the recording sheet S and the guide surfaces 202t and 202r, and between the recording sheet S and the protrusions, which may prevent smooth conveyance of the recording sheet S and induce risks of sheet jams.
However, if rollers are disposed both at the side having the guide surface 202t and at the side having the guide surface 202r, the roller 200 and the roller 1000 rotate so as to follow the recording sheet S, and minimize the frictional resistance generated by the recording sheet S passing through the sheet detection position 3. And thus the recording sheet S is smoothly conveyed and sheet jams can be prevented.
(4-4) At least one embodiment above describes an example in which the sheet types are determined by using the average values of the amount of the received light detected by the light receiving elements 302 and 303, but the present disclosure is not limited thereto, and may be modified as below.
As in
In contrast, the distance between the recording sheet S and the first sensor 201t at the sheet detection position 310 is recognized to have a specific tendency depending on whether the recording sheet S is fed out from the paper feed cassettes 141a, 141b or the manual feed tray. Therefore, focusing on this tendency can further increase the determination accuracy of the sheet types.
As described above, the recording sheet S fed out from the paper feed cassette 141a tends to be conveyed along the guide surface 202r. Therefore, at the sheet detection position 310, the distance from the first sensor 201t to the recording sheet S tends to be large, and accordingly, an amount of received light detected by the light receiving element 302 of the first sensor 201t tends to decrease.
On the other hand, as the recording sheet S fed out from the manual feed tray tends to be conveyed along the guide surface 202t, and the distance from the first sensor 201t to the recording sheet S tends to be small at the sheet detection position 310, the amount of received light detected by the light receiving element 302 of the first sensor 201t tends to increase. With respect to the recording sheet S fed out from the paper feed cassette 141b of the image forming device according to at least one embodiment, a specific tendency cannot be recognized.
Based on such knowledge, as in
When the recording sheet S is fed out from the paper feed cassette 141a, the amount of reflected light detected by the light receiving element 302 tends to decrease, and thus the average value is multiplied by a value larger than 1 as the correction coefficient C. Alternatively, when the recording sheet S is fed out from the manual feed tray, the amount of reflected light detected by the light receiving element 302 tends to increase, and thus the average value is multiplied by a value smaller than 1 as the correction coefficient C.
Specific value of the correction coefficient C is preferably determined according to a distance from the light receiving surface of the light receiving element 302 to the guide surface 202t and a distance from the light receiving surface of the light receiving element 302 to a position where the roller 200 contacts the recording sheet S.
Calculation results are the same in terms of correcting average values, whether a calculation result is obtained by calculating an average value of the detected values of the amount of reflected light and then multiplying by the correction coefficient C, or by multiplying the detected value of the amount of reflected light by the correction coefficient C and then calculating an average value.
Thus, by correcting the average value of the amount of reflected light according to a tendency of the passing position of the recording sheet S at the sheet detection position 310, the determination accuracy of the sheet types can be increased while preventing occurrence of failures when the recording sheet S is thin paper.
Note that the amount of transmitted light received by the light reception element 303 attenuates at a constant rate irrespective of the passing position of the recording sheet S. Therefore, unlike the average value of the amount of reflected light, no correction needs to be made for the average value of the amount of transmitted light according to a change in the passing position of the recording sheet S according to the feed source of the recording sheet S.
(4-5) At least one embodiment above describes an example in which three feed sources are provided for the recording sheet S, such as feed cassettes 141a, 141b, and the manual feed tray, but the same effect of the present disclosure is obtained when two or less, or four or more feed sources are provided for the recording sheet S.
(4-6) At least one embodiment above describes an example in which the rollers 200 are used to regulate the conveyance position of the recording sheet S, but the present disclosure is not limited thereto. A conveyance roller may be disposed instead of the roller 200 and rotated in the conveyance direction of the recording sheet S. The conveyance roller should be disposed at least at one of the sides having the guide surface 202t or 202r.
Similar to the arrangement of the rollers 200, the conveyance roller may be disposed spaced from and at an opposite side of another conveyance roller, the guide surface 202t, and the guide surface 202r with respect to a direction perpendicular to the sheet surface of the recording sheet S in conveyance. Such arrangement is further preferable for preventing the occurrence of failures such as sheet jams when the recording sheet S is thin paper. When the conveyance roller is used as a regulating member for the conveyance position of the recording sheet S, no stress in a direction opposite to the conveyance direction is applied to the recording sheet S during conveyance, and thus the occurrence of failures can be more reliably prevented in a case where the recording sheet S is thin paper.
(4-7) At least one embodiment above describes an example in which the image forming device 1 is the copying device that forms polychromatic images using the tandem electrophotographic method, but the present disclosure is not limited thereto. The image forming device 1 may be the copying device that forms polychromatic images using a method other than the tandem electrophotographic method, or the copying device that forms only monochrome images. Moreover, a similar effect can be obtained by applying the present disclosure to single-function devices such as a printing device without the image reading unit 150 or a facsimile device having a facsimile communication function, or to the multi-function peripheral (MFP) which combines such functions.
The above embodiments and modifications represent one or more aspect of the present disclosure, and are summarized as in the following.
That is, a sheet type determining device includes a guide that guides a sheet along a sheet conveyance path to a destination, the sheet conveyance path being between a first guide surface and a second guide surface disposed facing each other across an interval; a determiner that determines a sheet type when the sheet is in the sheet conveyance path, without having contact with the sheet in conveyance; and one or more regulators, each of the regulators regulating a displacement range of the sheet in a direction of the interval between the first and the second guide surfaces, at a detection position in the sheet conveyance path where the determiner determines the sheet type, wherein each of the regulators is a member that protrudes in an arc shape from the first or the second guide surface toward the guide surface opposite, and each of the regulators is spaced from the guide surface or another one of the regulators opposite in a direction perpendicular to a surface of the sheet.
In the sheet type determining device, when the number of the regulators is two or more, the regulators protruding from the first or the second guide surface are disposed at both sides of the detection position in a width direction of the sheet in conveyance.
In the sheet type determining device, when the number of the regulators is two or more, the regulators protruding from the first or the second guide surface are disposed at both sides of the detection position in a conveyance direction of the sheet.
In the sheet type determining device, the regulators are disposed upstream of the detection position in a conveyance direction of the sheet.
In the sheet type determining device, when the number of the regulators is two or more, the regulators protrude from the first and the second guide surfaces, and the regulators face each other across the sheet conveyance path spaced from each other.
In the sheet type determining device, each of the regulators is a roller rotated by the sheet in conveyance, the roller having a width direction of the sheet in conveyance as a rotation axis.
In the sheet type determining device, each of the regulators is a roller member having a width direction of the sheet in conveyance as a rotation axis, and the roller member is rotationally-driven in a conveyance direction of the sheet when at least a leading end of the sheet reaches a position of the roller member in the sheet conveyance path.
In the sheet type determining device, each of the regulators is spaced 1 mm or more from the guide surface or another one of the regulators opposite in the direction perpendicular to the surface of the sheet.
In the sheet type determining device, the determiner includes a light emitting element and a light receiving element, and determines the sheet type using at least a value of an amount of light reflected from the sheet or a value of an amount of light transmitted through the sheet.
In the sheet type determining device, when the sheet can be conveyed from different conveyance sources to the detection position, the determiner corrects the value of the amount of light reflected from the sheet according to a conveyance source of the sheet and determines the sheet type using a corrected value of the amount of light reflected.
An image forming device includes a sheet type determining device; and an image former that forms an image on a sheet after a sheet type is determined by the sheet type determining device, the image being formed according to an image forming condition determined by a determination result of the sheet type determining device, wherein the sheet type determining device includes a guide that guides a sheet along a sheet conveyance path to a destination, the sheet conveyance path being between a first guide surface and a second guide surface disposed facing each other across an interval; a determiner that determines a sheet type when the sheet is in the sheet conveyance path, without having contact with the sheet in conveyance; and one or more regulators, each of the regulators regulating a displacement range of the sheet in a direction of the interval between the first and the second guide surfaces, at a detection position in the sheet conveyance path where the determiner determines the sheet type, wherein each of the regulators is a member that protrudes in an arc shape from the first or the second guide surface toward the guide surface opposite, and each of the regulators is spaced from the guide surface or another one of the regulators opposite in a direction perpendicular to a surface of the sheet.
The image forming device further includes a resistance roller pair that controls a timing for conveying the sheet in order to transfer a toner image to the sheet, wherein the determiner and each of the regulators are disposed upstream of the resistance roller pair in a sheet conveyance direction.
In this way, as the regulating member is disposed so as not to contact with a member countering each other with respect to the direction perpendicular to the surface of the sheet, the determination accuracy of the sheet types are increased while the occurrence of failures such as sheet jams are suppressed even when the recording sheets are thin paper.
Although one or more embodiments of the present disclosure have been described and illustrated in detail, the disclosed embodiments are made for the purposes of illustration and example only and not limitation. The scope of the present disclosure should be interpreted by the terms of the appended claims.
Number | Date | Country | Kind |
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2017-239846 | Dec 2017 | JP | national |