The present invention relates to a heater which is suitably utilized in a heating fixing device provided in an image forming apparatus such as an electrophotographic copier or an electrophotographic printer, an image heating device on which this heater is mounted, and an image forming apparatus.
As a fixing device provided in a photocopier or a printer, there is a type of the fixing device including an endless belt, a ceramic heater which comes into contact with the inner surface of the endless belt, and a pressure roller which forms a fixing nip portion together with the ceramic heater via the endless belt. When small-size sheets are continuously printed by an image forming apparatus provided with this fixing device, a phenomenon (the temperature rise of a non-sheet feeding portion) in which the temperature gradually rises in an area through which no sheet passes in the longitudinal direction of the fixing nip portion occurs. If the temperature of the non-sheet feeding portion excessively rises, parts in the device are damaged, or toner offsets at a high temperature causes in the area corresponding to the non-sheet feeding portion of the small-size sheets when a large-size sheets are printed in a state where the temperature rises at the non-sheet feeding portion.
As one of means to suppress the temperature rise of the non-sheet feeding portion, it is considered that a heat generating resistor on a ceramic substrate is made of a material having negative resistance temperature characteristics. Even if the temperature of the non-sheet feeding portion rises, the resistance value of the heat generating resistor of the non-sheet feeding portion lowers. Therefore, it is considered that even when a current flows through the heat generating resistor of the non-sheet feeding portion, the heat generation of the non-sheet feeding portion is suppressed. In the negative resistance temperature characteristics, when the temperature rises, the resistance lowers. Hereinafter, the characteristics will be referred to as a negative temperature coefficient (NTC). Conversely, it is suggested that the heat generating resistor is made of a material having positive resistance temperature characteristics. It is considered that when the temperature of the non-sheet feeding portion rises, the resistance value of the heat generating resistor of the non-sheet feeding portion rises, and the current flowing through the heat generating resistor of the non-sheet feeding portion is suppressed to inhibit the heat generation of the non-sheet feeding portion. In the positive resistance temperature characteristics, when the temperature rises, the resistance rises. Hereinafter, the characteristics will be referred to as a positive temperature coefficient (PTC).
However, the material having the NTC usually has a very high volume resistance. It is very difficult to set the total resistance of the heat generating resistors formed in one heater to a range usable with a commercial power supply. Conversely, the material having the PTC has a very low volume resistance. In the same manner as in the material having the NTC, it is very difficult to set the total resistance of the heat generating resistors in the heater to the range usable with the commercial power supply.
To solve such a problem, the heat generating resistors of the PTC formed on the ceramic substrate are divided by a plurality of heat blocks in the longitudinal direction of the heater. In each of the heat blocks, two conductive members are arranged at both ends of the block in the lateral direction of the substrate so that the current flows through the block in the lateral direction of the heater (the conveyance direction of a recording sheet). Furthermore, Japanese Patent Application Laid-Open No. 2005-209493 discloses the plurality of heat blocks electrically connected in series. According to such a constitution, even when the heat generating resistor of the PTC is used, the total resistance of the heater can easily be set to the range usable with the commercial power supply. Moreover, this document also discloses that a plurality of heat generating resistors is electrically connected in parallel between two conductive members to form the heat block.
Because, however, the resistance value of each conductive member is not zero, and owing to the influence of a voltage drop occurring in the conductive member, voltages applied to heat generating resistors in the center of one heat block are smaller than those applied to heat generating resistors at both ends thereof. The heat generation amount of each heat generating resistor is proportional to the square of the applied voltage. Therefore, the heat generation amount of the center of the heat block is different from that of each end of the heat block. In this way, when heat generation unevenness occurs in the heat block, the heat generation distribution unevenness in the longitudinal direction of a heater also increases.
In order to solve the above problem, according to the present invention, the purpose of the present invention is to provide a heater including a substrate, first and second conductive members provided on the substrate, and a heat generating resistor interconnected between the first conductive member and the second conductive member, the first conductive member being provided along the longitudinal direction of the substrate, the second conductive member being provided along the longitudinal direction at a position different from that of the first conductive member in the lateral direction of the substrate, a plurality of heat generating resistors being electrically connected in parallel between the first conductive member and the second conductive member, a plurality of heat blocks including a plurality of heat generating resistors electrically connected in parallel being arranged along the longitudinal direction, the plurality of heat blocks being electrically connected in series, wherein rows including the plurality of heat blocks electrically connected in series are arranged on the substrate in the lateral direction, and the positions of the heat blocks of the first row are shifted from those of the heat blocks of the second row in the longitudinal direction so that the end of the heat in the first row does not overlap with the end of the heat block in the second row in the longitudinal direction, and an image forming apparatus including the heater.
Moreover, another purpose of the present invention is to provide an image forming apparatus including an image forming part which forms an unfixed image on a recording material, and a fixing part including an endless belt, a heater which comes in contact with the inner surface of the endless belt, and a nip portion forming member which forms a nip portion together with the heater via the endless belt, configured to heat and fix the unfixed image on the recording material while pinching and conveying the recording material having the unfixed image at the nip portion, the heater including a substrate, a first conductive member provided on the substrate along the longitudinal direction of the substrate, a second conductive member provided along the longitudinal direction at a position different from that of the first conductive member on the substrate in the lateral direction of the substrate, and a plurality of heat generating resistors having positive resistance temperature characteristics and electrically connected in parallel between the first conductive member and the second conductive member, the heater having a heat block structure in which a portion most distant from a recording material conveyance reference in the longitudinal direction of the substrate in an area provided with the heat generating resistors includes the plurality of heat generating resistors connected in parallel, wherein the plurality of heat generating resistors are arranged with an angle with respect to the longitudinal direction and the recording material conveyance direction so as to obtain such a positional relation that the shortest current path of each of the heat generating resistors overlaps with, in the longitudinal direction, the shortest current path of the heat generating resistors provided adjacent to each other in the longitudinal direction, and the heat generating resistors are arranged so that when the recording material having at least one specific size of sizes smaller than the largest standard recording material size dealt by the apparatus passes through the nip portion, the side of the edge of the recording material in the longitudinal direction does not pass through the areas provided with the heat generating resistors at both ends of the heat block provided in an endmost portion.
According to the present invention, a heat generation distribution unevenness in the longitudinal direction of a heater can be suppressed.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
The heater 10 includes a heater substrate 13 made of a ceramic material, a heat generation line A (a first row) and a heat generation line B (a second row) formed on the substrate 13, and an insulating surface protective layer 14 (glass in the present example) which covers the heat generation lines A and B. A temperature detection element 4 such as a thermistor contacts a sheet feeding area of sheets having a minimum usable size set in a printer on the back surface side of the heater substrate 13. The power to be supplied from a commercial alternate current power supply to the heat generation lines is controlled in accordance with the detected temperature of the temperature detection element 4. A recording material (a sheet) P having an unfixed toner image is heated and fixed, while nipped and conveyed by the fixing nip portion N. A safety element 5 such as a thermo switch also contacts the back surface side of the heater substrate 13, and the safety element operates to block a power supply line leading to the heat generation lines, when the temperature of the heater abnormally rises. The safety element 5 contacts the sheet feeding area of the sheets having the minimum size in the same manner as in the temperature detection element 4. A stay 6 made of a metal is configured to add the pressure of a spring (not shown) to the holding member 3.
The heat generation line A (the first row) includes 20 heat blocks A1 to A20, and the heat blocks A1 to A20 are connected in series. The heat generation line B (the second row) includes 20 heat blocks B1 to B20, and the heat blocks B1 to B20 are also connected in series. Moreover, the heat generation lines A and B are electrically connected in series. A power is supplied to the heat generation lines A and B from electrodes AE and BE connected to power supplying connectors.
The heat generation line A has a conductive pattern Aa provided along the substrate longitudinal direction (a first conductive member of the heat generation line A) and a conductive pattern Ab (a second conductive member of the heat generation line A) provided in the substrate longitudinal direction at a position different from that of the conductive pattern Aa in the lateral direction of the substrate. The conductive pattern Aa is divided into eleven patterns (Aa-1 to Aa-11) in the substrate longitudinal direction. The conductive pattern Ab is divided into ten patterns (Aa-1 to Aa-10) in the substrate longitudinal direction. As shown in
The heat generation line B also has a conductive pattern Ba provided along the longitudinal direction of the substrate (a first conductive member of the heat generation line A) and a conductive pattern Bb (a second conductive member of the heat generation line B) provided along the longitudinal direction of the substrate at a position different from that of the conductive pattern Ba in the lateral direction of the substrate. The constitution of each heat block in the heat generation line B is also similar to that in the heat generation line A, and the constitution of each of 19 heat blocks (B2 to B20) in the heat generation line B is the same as that of each of the heat blocks (A1 to A19) in the heat generation line A. Moreover, the only heat block B1 in the heat generation line B is different from the other heat blocks in the length of the heat block and the number of the heat generating resistors.
Meanwhile, as described above, it has been found that the resistance value of each conductive member is not zero, and owing to the influence of a voltage drop in the conductive member, voltages applied to heat generating resistors in the center of one heat block are smaller than those applied to heat generating resistors at both ends thereof. The heat generation amount of each heat generating resistor is proportional to the square of the applied voltage. Therefore, the heat generation amount of the center of the one heat block is different from that of each end thereof. Specifically, the heat generation amounts at both the ends of the heat block are largest, and the heat generation amount in the center thereof decreases. In this way, when heat generation unevenness occurs in the heat block, the heat generation distribution unevenness in the longitudinal direction of the heater also increases.
Consequently, as shown in
There will be described a heat generation distribution unevenness suppression effect in a case where the heat blocks of the heat generation line A are shifted from the heat blocks of the heat generation line B in the substrate longitudinal direction, with reference to
As shown in
On the other hand,
Thus, rows including a plurality of heat blocks electrically connected in series are arranged on the substrate in the lateral direction thereof, and the positions of the heat blocks in the heat generation line A (the first row) are shifted from those of the heat blocks in the heat generation line B (the second row) in the substrate longitudinal direction. In the constitution, the heat generation distribution unevenness can be suppressed.
Moreover, the shape of one heat generating resistor is not limited to a rectangular shape shown in
Next, there will be described the heat blocks (A20 and B1) having a constitution different from that of the other heat blocks in the heat generation lines A and B in the heater shown in
Therefore, in the present example, the heat blocks (A20 and B1) have a constitution different from that of the other heat blocks.
In the heat generation pattern AP, the sheet resistance value of the heat generation paste is set to 0.047Ω/□. The pattern is a strip-like heat generation pattern having a total resistance of 5.9Ω, a line width of 1.6 mm and a length of 198 mm and extending along the heater longitudinal direction. A heat generation pattern BP is slightly shorter than the heat generation pattern AP. In the pattern, the sheet resistance value of the heat generation paste is set to 0.047Ω/□. The pattern is a strip-like heat generation pattern having a total resistance of 5.8Ω, a line width of 1.6 mm and a length of 198 mm and extending along the heater longitudinal direction. The heat block A1 is connected to the heat generation pattern AP via a conductive pattern (j=0.27 mm). Thus, a material of a sheet resistor of the heat generating resistor in the heat block A1 is used. The material has a resistance value which is different from that of a material of a sheet resistor of the heat generation pattern AP. In consequence, the heat generation amount per unit length is regulated. As shown in
Next, Examples 4 to 7 will be described as an example in which when a recording material having a specific size is fed, the temperature rise of a non-sheet feeding portion is suppressed while suppressing heat generation unevenness.
A developer 17 supplies toner to this electrostatic latent image, to form a toner image on the photosensitive member 19 in accordance with the image information.
On the other hand, recording materials (recording sheets) P stacked in a feeding cassette 11 are supplied to a pickup roller 12 sheet by sheet, and conveyed to registration rollers 14 by rollers 13. Furthermore, the recording material is conveyed from the registration roller 14 to a transfer position, when the toner image on the photosensitive member 19 reaches the transfer position formed by the photosensitive drum 19 and a transfer roller 20. While the recording material P passes through the transfer position, the toner image on the photosensitive member 19 is transferred to the recording material P.
Afterward, the recording material P is heated in a fixing portion 100, and the toner image is heated and fixed on the recording material P. The recording material P having the fixed toner image is discharged onto a tray in the upper part of a printer by rollers 26 and 27. It is to be noted that the photosensitive member 19 is cleaned by a cleaner 18. A sheet feeding tray (a manual sheet feeding tray) 28 includes a pair of recording material regulation plates in which a distances in a width direction is adjustable according to the size of the recording material.
The sheet feeding tray 28 is provided to receive recording materials having a standard size and another size. The recording material is supplied from the sheet feeding tray 28 by pickup rollers 29. The fixing portion 100 is driven by a motor 30. The photosensitive member 19, the charging roller 16, the scanner unit 21, the developer 17 and the transfer roller 20 constitute an image forming part which forms an unfixed image on the recording material.
The printer f the present example is a printer for an A4-size (210 mm×297 mm) corresponding to a letter size (about 216 mm×279 mm). That is, the printer basically vertically feeds A4-size sheets (so that the long sides of the sheets are parallel to a conveyance direction), but the printer is also designed to vertically feed letter-size sheets each having a width slightly larger than the A4-size.
Therefore, the largest size (with the large width) of the standard size of the recording material to be printed by the printer (a corresponding sheet size on a catalog) is the letter size.
The heat generation line A (a first row) includes 20 heat blocks A1 to A20, and the heat blocks A1 to A20 are connected in series. The heat generation line B (a second row) includes 20 heat blocks B1 to B20, and the heat blocks B1 to B20 are connected in series.
Moreover, the heat generation lines A and B are also electrically connected in series. A power is supplied to the heat generation lines A and B from electrodes AE and BE connected to a power supplying connector. The heat generation line A includes a conductive pattern Aa (a first conductive member of the heat generation line A) provided along a substrate longitudinal direction, and a conductive pattern Ab (a second conductive member of the heat generation line A) provided along the substrate longitudinal direction at a position different from that of the conductive pattern Aa in a lateral direction of a substrate. The conductive pattern Aa is divided into eleven patterns (Aa-1 to Aa-11) in the longitudinal direction of the substrate.
The conductive pattern Ab is divided into ten patterns (Ab-1 to Ab-10) in the substrate longitudinal direction. The constitution of the heat generation line B is similar to the heat generation line A, and hence the description thereof is omitted.
When the heater 200 is manufactured, first, heat generating resistors A and B are formed on a heater substrate 105. Afterward, conductive patterns Aa, Ab, Ba and Bb are formed. Finally, a surface protective layer 107 is formed.
The heater is formed in such an order. Therefore, as seen from the cross section of the heater in
When the conductive patterns are formed on the heater substrate 105 before the heat generating resistors, a part of each heat generating resistor covers each conductive pattern, and the sectional shape of the heat generating resistor is deformed. The resistance value of the heat generating resistor is proportional to the length thereof, and is inversely proportional to the width thereof. However, when the sectional shape is deformed, a current flowing area in the heat generating resistor varies, and the resistance value suitable for the size of the heat generating resistor is not indicated sometimes (an area seen along the direction of an arrow L in
However, when the heat generating resistors are formed before the conductive patterns as in the present example, the sectional shape of each heat generating resistor does not vary. Therefore, the present example has a merit that the resistance value of the heat generating resistor is easily set to the design value.
As shown
In the heater 200, heat generation resistive spaces c-1 to c-8 are equal not only in the heat block A1 but also in the other heat blocks, and all the spaces are c/8. In the heat block A1, the line width of the heat generating resistor is varied so as to obtain a uniform heat generation distribution of the heat block in the longitudinal direction of the heater. In consequence, the uniformity of the heat generation amounts of the heat generating resistors A1-1 to A1-8 is improved.
In the heat block A1, the line width b-n of each heat generating resistor is set so that the heat generating resistors (A1-4 and A1-5) in the center have a lower resistance value and the heat generating resistors (A1-1 and A1-8) at the ends have a higher resistance value. The table shown in
Here, the lengths (a-n: a-1 to a-8) and spaces (c-n: c-1 to c-8) of the heat generating resistors are set to be constant, and the line widths (b-n: b-1 to b-8) of the heat generating resistors are varied, to obtain the uniform heat generation distribution of the heat block A1. The resistance value of each heat generating resistor is proportional to the length/line width. Therefore, the length of the heat generating resistor may be varied in the same manner as in the line width, to regulate the resistance value of the heat generating resistor. Moreover, when the heat generating resistor has a rectangular shape as shown in
When, for example, the heat generating resistor has a parallelogram shape, a large amount of current flows through the shortest path of the resistor. Therefore, although the distribution of the current flowing through the heat generating resistors may not be uniform, when the shape is changed to the rectangular shape, the current easily uniformly flows through the whole heat generating resistor.
However, the effect of suppressing the temperature rise of the non-sheet feeding portion can be obtained, also when the heat generating resistor having the parallelogram shape is used. The shape of the heat generating resistor is not limited to the rectangular shape. Moreover, as shown in
This positional relation also applies to a relation between the endmost heat generating resistor in one heat block (e.g., the shortest heat generating resistor A1-8 on the right side of the heat block A1) and the shortest heat generating resistor in the adjacent heat block (e.g., the shortest heat generating resistor A2-1 on the left side of the heat block A2). Since the heat generating resistor of the present example has a rectangular shape, the whole heat generating resistor is the shortest current path.
In the present example, as shown in
As shown in
In addition, as described above, the printer of the present example corresponds to the letter size, but basically corresponds to the A4-size sheets. Therefore, the printer is suitable for a user who most frequently utilizes the A4-size sheets. However, the printer also corresponds to the letter size. Therefore, when the A4-size sheets are printed, a 3 mm non-sheet feeding area is formed at each end of the heat generation line. The power to be supplied to the heater is controlled so that during a fixing treatment, a temperature detected by a temperature detection element 111 for detecting the temperature of the heater near the recording material conveyance reference X is kept at a control target temperature. In consequence, in order to prevent heat from dissipating by a sheet in the non-sheet feeding portion, and hence the temperature of the non-sheet feeding portion rises as compared with the sheet feeding portion. It is to be noted that in the present example, the letter size is the maximum size, and the A4-size is a specific size.
In the present example, through the position D1, the edge of the sheet having the letter size passes, when the sheet is aligned with the reference X and conveyed. Moreover, at the positions D2 and D5, it is supposed that the edge of the recording material passes through the heat generating resistors (A1-1, A1-8, B1-1 and B1-8) at both the ends of the heat blocks A1 and B1. At the positions D3 and D4, it is supposed that the edge of the recording material does not pass through the heat generating resistors (A1-1, A1-8, B1-1 and B1-8) at both the ends of the heat blocks A1 and B1.
In the simulation result of
Both ends of the adjacent heat generation patterns in the heat block are connected via a conductive pattern having a line length of 1.35 mm and a line width of 1 mm. On such simplified conditions, the resistance value r of the conductive pattern connected to the heat generation patterns is 0.007Ω. The description of the heat block B1 is similar to the heat block A1, and is therefore omitted. In
When the temperature of the heat generation pattern of the non-sheet feeding portion reaches 300° C. or higher, a roller portion 110 made of an elastic material such as heat-resistant rubber in a pressure roller 108, a film 102 and a film guide 101 reach the limit of the heat-resistant temperature, and a fixing unit might be damaged. Therefore, the raised temperature of the non-sheet feeding portion is set to 300° C. The above set temperature varies in accordance with a material or a constitution, and the temperature is not especially limited to this temperature. Moreover, a continuous temperature distribution is actually present in the non-sheet feeding area and the end of the sheet feeding area. However, for the sake of simplicity, on the border of D1 to D6 in
When the edge of the recording material is present at the position D1, the ends of the heat generation line matches the edges of the sheet, and the non-sheet feeding area is eliminated. It is seen that when the edge positions of the recording material are D2 and D5, the effect of suppressing the temperature rise of the non-sheet feeding portion deteriorates as compared with the case of the edge positions D3 and D4.
Therefore, the heat generation patterns and heat blocks are formed so that the edge of the small-size sheet (the A4-sheet) passes inside the heat generation pattern at each end of the heat block (between D3 and D4 of
In the above simulation, the heat generation amount has been described in a case where the temperature of the non-sheet feeding area reaches 300° C. However, when the edge of the sheet having a specific size passes between D3 and D4 in
As described with reference to
Meanwhile, it is considered that especially when the sheet is supplied from the sheet feeding tray 28, a user mistakenly supplies the A4-size sheet along a recording sheet regulating plate in a state where the recording sheet position regulating sheet is widely positioned with a distance for a letter size. That is, the A4-size sheet is not aligned with the recording material conveyance reference X but is supplied in the case of so-called one-sided sheet feeding. In this case, the non-sheet feeding portion having a size of 6 mm is formed on one side of the heat generation line. This one-sided sheet feeding might occur, also when the sheet is supplied from the feeding cassette 11. For example, the one-sided sheet feeding might occur in a case where after setting the sheets in the feeding cassette 11, the feeding cassette is returned into the main body of the image forming apparatus while the position of the sheet is not regulated by the sheet position regulation plate in the feeding cassette.
It is preferable to design the shape of the heat generating resistor in consideration of the aforementioned irregular case. In the heater having a heat generation line length of 216 mm as described above, when the A4-size sheet (the small-size sheet having a size of 210 mm) having the center thereof aligned as a reference is vertically fed, the width of the non-sheet feeding area is 3 mm. When the sheet is aligned with one side of the heat generation line and fed, the width of the non-sheet feeding area is 6 mm. In each case, the edge of the sheet is passed between D3 and D4 in the heater 200. Consequently, in the heater 200, when the center of the A4-size sheet is aligned as the reference and the sheet is fed and when the one-sided sheet is fed, the effect of suppressing the temperature rise of the non-sheet feeding portion can be obtained.
It is to be noted that in the present example, the printer for the A4-size (210 mm×297 mm) corresponding to the letter size (about 216 mm×279 mm) has been described. However, the present invention can also be applied to a A3-size vertical feeding printer (a width of 300 mm) for SRA3-size (an A3 elongated size) vertical feeding (a width of 320 mm) and an A3 vertical feeding (300 mm) printer corresponding to a letter-size horizontal feeding (279 mm).
The maximum processing speed of this printer is 42 ppm. In S501, it is judged whether or not a printing start request occurs. When the request occurs, the processing proceeds to S502. In S502, it is judged whether the standard sheet fed from the feeding cassette 11 or the non-standard sheet fed from the manual sheet feeding tray 28 is printed. In the case of the standard sheet printing, the processing advances to S503 in which the size of the recording material set in the feeding cassette 11 is detected. In S504, it is judged whether or not the size of the recording material is the letter size. When the size of the recording material is the letter size, the processing proceeds to S506 to set a counter to N=9999.
This counter indicates the number of the sheets allowed to be continuously printed at the maximum processing speed. In the case of the letter size, the non-sheet feeding portion is not generated, and hence the number is set to N=9999 (=infinite). That is, the sheets can infinitely be output at a speed of 42 ppm. In S505, it is judged whether or not the size of the recording material is the A4-size. When the size of the recording material is the A4-size, the processing advances to S507 to set the counter to N=500.
In the case of the A4-size, the number of the sheets allowed to be continuously printed at the maximum processing speed (42 ppm) is 500. When the heat generating resistor does not have the shape in consideration of the above A4-size sheet, a counter value has to be set to a small value in the case of the A4-size sheet. When the sheets set in the sheet feeding cassette 11 have a size smaller than the A4-size or when the non-standard sheets fed from the manual sheet feeding tray 28 are printed, the processing advances to S508 to set the counter to N=10. In S509, subtraction processing of “N=N−1” is performed. It is judged in S510 whether or not the counter N is below 0. When the counter N is not equal to or not less than 0 (i.e., equal to or more than 1), the processing advances to S511 to performs a usual image forming step.
In S511, the control target temperature (the fixing target temperature) of the heater 200 is set to 200° C., and a process speed is set to the whole process speed to perform print processing (the processing at a speed of 42 ppm). When the counter N is equal to or less than in S510, the processing proceeds to S512 to lower the control target temperature (the fixing target temperature) of the heater 200 to 170° C. Moreover, the throughput of the image forming apparatus is lowered, and the process speed is set to a half-process speed (the processing at a speed of 21 ppm) to perform the print processing. When the process speed is set to the half-process speed, the movement speed of the sheet in the fixing nip portion is the half. Therefore, as compared with the whole process speed, fixing properties can be acquired at a low heater temperature. Moreover, the fixing target temperature is lowered, and hence the temperature of the non-sheet feeding portion can be suppressed.
In S513, the above processing is repeatedly performed until any remaining print job is not present, to set the throughput of the image forming apparatus, the image forming process speed and the fixing target temperature. When the sheet size is the letter size, the length of the heat generation line of the heater 200 is designed to be optimized to the letter size. Therefore, even when the maximum number of the sheets to be printed are continuously fed in the image forming apparatus, the temperature rise of the non-sheet feeding portion hardly occurs at all.
Therefore, the value of the counter is set to N=9999, and any restriction is not set to the number of the sheets to be continuously printed. When the sheet size is A4, the temperature rise of the non-sheet feeding portion occurs. However, the effect of suppressing the temperature rise of the non-sheet feeding portion can be obtained as described with reference to
Moreover, in the image forming apparatus including a thermistor as a second temperature detection element near the end of the heat generation line of the heater 200, when the temperature detected by the end thermistor reaches a predetermined threshold value, control may be performed so as to decrease the throughput of the image forming apparatus, set the image forming process speed to the half and lower the fixing target temperature to 170° C.
Furthermore, in the case of the non-standard sheet size, the predetermined threshold value at which the throughput is lowered may be set to be lower as compared with the case of the standard sheet size. The control can be performed as shown in the flowchart of
As described above, i) In the area provided with the heat generating resistors, the portion most distant from the recording material conveyance reference in the substrate longitudinal direction has the structure of the heat block including the plurality of heat generating resistors connected in parallel, ii) The plurality of heat generating resistors are obliquely tilted and arranged with respect to the longitudinal direction and recording material conveyance direction to obtain such a positional relation that the shortest current path of each of the heat generating resistors overlaps with the shortest current path of the heat generating resistors provided adjacent to each other along the longitudinal direction, in the longitudinal direction and iii) The plurality of heat generating resistors are arranged so that the side of the edge of the recording material in the longitudinal direction does not pass through the areas provided with the heat generating resistors in the heat block provided in the endmost portion, when the recording material having at least one specific size of the sizes smaller than the largest standard recording material size dealt by the apparatus passes through the nip portion. When the heater having such a constitution is used, there can be provided the image forming apparatus in which the temperature rise of the non-sheet feeding portion in a case where the recording material having the specific size is fed can be suppressed while suppressing the heat generation unevenness.
Next, Example 5 will be described. In the example, the heater to be provided in the fixing portion of the image forming apparatus is changed. Description of a constitution similar to Example 4 is omitted.
Next, Example 6 will be described. In the example, the heater to be provided in the fixing portion of the image forming apparatus is changed. Description of a constitution similar to Example 4 is omitted.
In the heat block A1, eight heat generation patterns, i.e., a heat generation pattern A1-1 having a line length a-1, line width b-1 and tilt 8-1 to a heat generation pattern A1-8 having a line length a-8, line width b-8 and tilt 8-8 are arranged with spaces c-1 to c-8, and the patterns are connected in parallel via the conductive pattern. The heat block A1 is characterized by obtaining the uniform heat generation distribution of the heat block in the heater longitudinal direction, the space between the heat generation patterns and the tilt are changed to increase the density of the heat generation patterns A1-1 to Al-8 toward the center of the heat block. The present invention can be applied to the use of a heater which does not include any heat generation line (only one heat generation line) as shown in
In the heater of
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application Nos. 2009-210706, filed on Sep. 11, 2009, and 2009-289722, filed on Dec. 21, 2009 which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | Kind |
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2009-210706 | Sep 2009 | JP | national |
2009-289722 | Dec 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/065573 | 9/3/2010 | WO | 00 | 1/17/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/030843 | 3/17/2011 | WO | A |
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Number | Date | Country | |
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20120121306 A1 | May 2012 | US |