JP6642468B2 - Image forming device - Google Patents

Description

  The present invention relates to an image forming apparatus provided with a filter for preventing particles such as toner from leaking outside due to ventilation for cooling, and more particularly to a technique for preventing a decrease in cooling efficiency.

  For example, in Patent Document 1, the number of ultrafine particles around a fixing unit is obtained, and a normal mode and a particle countermeasure mode are switched according to a determination value based on the number. In the normal mode, a normal filter is used. In the particle countermeasure mode, a finer filter is used. Thereby, even if the amount of the ultrafine particles increases, the ultrafine particles can be reliably captured. When a fine-grained filter is used, a large-capacity fan is used, the rotation speed of the fan is increased, or the conveyance speed of the recording paper in the fixing unit is reduced.

JP 2012-128013 A

  Here, in recent image forming apparatuses, in order to reduce the power consumption, the melting point of the toner is lowered to lower the fixing temperature of the toner image on the recording paper. However, when the melting point of the toner is lowered, a situation in which the toner melts in the image forming unit due to a rise in temperature around the image forming unit for forming a toner image on recording paper is likely to occur. For this reason, a cooling mode in which the image forming speed of the image forming unit is reduced is set to suppress an increase in the temperature around the image forming unit, and ventilation is performed by a fan.

  However, in such an image forming apparatus, when the cooling mode is set, the number of printed sheets per unit time by the image forming apparatus, that is, the productivity is reduced. Further, particles such as untransferred toner and ultrafine particles released from the material exposed to the high temperature are generated around the image forming portion, and this causes contamination inside the apparatus. Then, with the ventilation by the fan, the particles are released to the outside, causing environmental pollution. Furthermore, when the fan is rotated at a high speed to promote ventilation, there is a problem that noise generated from the image forming apparatus increases. For this reason, it is required that the productivity of the image forming apparatus, the in-machine contamination, the environmental pollution, and the management of noise and the like be more accurately controlled.

  However, in Patent Literature 1, the temperature around the image forming unit is not detected, and thus it cannot be said that the productivity of the image forming apparatus is properly managed. In addition, although we use a regular filter and a finer filter properly, regardless of which filter is used, it is necessary to increase the fan rotation speed to increase the amount of air to be ventilated, reducing noise. It cannot be said that sufficient consideration has been given from the viewpoint. Further, when the number of generated particles is small, a filter is not required, and it is possible to reduce the rotation speed of the fan and improve the productivity, but there is no such technical description.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to make it possible to more appropriately manage the productivity of an image forming apparatus, contamination inside a machine, environmental pollution, noise, and the like.

  An image forming apparatus according to one aspect of the present invention includes an image forming unit that forms a toner image on recording paper, a temperature detecting unit that detects a temperature around the image forming unit, and a degree of contamination around the image forming unit. A fan that ventilates air around the image forming unit, a filter through which air discharged to the outside by the fan passes, and an air discharged through the filter to the outside. Filter path, and a path selection unit that selectively forms any one of a bypass path through which air is discharged to the outside without passing through the filter, and a path selection unit that detects the image formation unit detected by the temperature detection unit. It is determined whether or not the surrounding temperature is higher than a preset temperature threshold, and the degree of contamination around the image forming unit detected by the contamination detection unit is higher than a preset contamination degree threshold. It is determined whether it is high or not, and based on these determination results, the path selection unit is controlled to form one of the filter path and the bypass path, and to reduce the image forming speed by the image forming unit. A control unit for setting or not setting the cooling mode.

  Further, an image forming apparatus according to one aspect of the present invention includes an image forming unit that forms a toner image on a recording sheet, a temperature detecting unit that detects a temperature around the image forming unit, and a temperature detecting unit around the image forming unit. A fouling detection unit for detecting the degree of fouling, a fan for ventilating air around the image forming unit, a first filter, a second filter having a lower particle collection rate than the first filter, and Path selection for selectively forming one of a first filter path that is discharged to the outside through the first filter and a second filter path that air is discharged to the outside through the second filter. Unit, and determines whether the temperature around the image forming unit detected by the temperature detecting unit is higher than a preset temperature threshold, and the image forming unit detected by the stain detecting unit Perimeter contamination Is determined to be higher than a preset pollution degree threshold, and based on these determination results, the path selector is controlled to form either the first filter path or the second filter path. And a control unit for setting or not setting a cooling mode for reducing an image forming speed by the image forming unit.

  According to the present invention, it is possible to more accurately manage the productivity of an image forming apparatus, contamination inside a machine, environmental pollution, noise, and the like.

FIG. 1 is a front sectional view showing a structure of an image forming apparatus according to a first embodiment of the present invention. FIG. 2 is a cross-sectional view schematically illustrating a mechanism of ventilation of an image forming unit by a fan in the image forming apparatus according to the first embodiment. FIG. 5 is a cross-sectional view illustrating a state where the filter path is switched from a filter path to a bypass path in the ventilation mechanism of the image forming unit. 9 is a table showing conditions for selecting setting or non-setting of a filter path or a bypass path and a cooling mode of an image forming unit. 9 is a flowchart illustrating a processing procedure for selecting setting or non-setting of a filter path or a bypass path and a cooling mode. 9 is a table showing a filter path or a bypass path and other conditions for selecting setting or non-setting of the cooling mode. FIG. 7A is a cross-sectional view schematically showing Modification Example 1 of a mechanism of ventilation of an image forming unit by a fan, and FIG. 8B is a cross-sectional view showing a state where a bypass path is formed. (A) is a sectional view schematically showing a mechanism of ventilation of an image forming unit by a fan in the image forming apparatus of the second embodiment, and (B) is switched from a first filter path to a second filter path. It is sectional drawing which shows a state. It is a table | surface which shows the conditions for selecting the setting or non-setting of a 1st filter path | route or a 2nd filter path | pass, and a cooling mode. FIG. 7A is a cross-sectional view schematically showing Modification Example 2 of a mechanism of ventilation of an image forming unit by a fan, and FIG. 7B is a cross-sectional view showing a state where a second filter path is formed.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a front sectional view showing the structure of the image forming apparatus according to the first embodiment of the present invention. The image forming apparatus 10 of the present embodiment is, for example, an MFP (multifunction peripheral) having a plurality of functions such as a copy function, a printer function, a scanner function, and a facsimile function. The image forming apparatus 10 includes an image reading unit 11, an image forming unit 12, and the like.

  The image reading unit 11 has a scanner that optically reads a document, and generates image data indicating an image of the document.

  The image forming unit 12 prints an image indicated by the image data generated by the image reading unit 11 on recording paper, and includes an image forming unit 3M for magenta, an image forming unit 3C for cyan, and an image for yellow. A forming unit 3Y and an image forming unit 3Bk for black are provided. In each of the image forming units 3M, 3C, 3Y, and 3Bk, the surface of the photosensitive drum 4 is uniformly charged, the surface of the photosensitive drum 4 is exposed, and an electrostatic latent image is formed on the surface of the photosensitive drum 4. Is formed, the electrostatic latent image on the surface of the photosensitive drum 4 is developed into a toner image, and the toner image on the surface of the photosensitive drum 4 is transferred to the intermediate transfer belt 5. As a result, a color toner image (image) is formed on the intermediate transfer belt 5. This color toner image is secondarily transferred to the recording paper P conveyed from the paper supply unit 7 through the conveyance path 8 in the nip area N between the intermediate transfer belt 5 and the secondary transfer roller 6.

  Thereafter, the recording paper P is heated and pressed by the fixing device 15, the toner image on the recording paper P is fixed by thermocompression, and the recording paper P is further discharged to the discharge tray 17 through the discharge roller pair 16.

  In such an image forming apparatus 10, in order to reduce power consumption, a low melting point toner is applied to lower the fixing temperature of a toner image on recording paper. However, when a low melting point toner is used, an unexpected situation in which the toner melts in the image forming unit 12 due to a rise in temperature around the image forming unit 12 is likely to occur. Therefore, ventilation around the image forming unit 12 is performed by a fan.

  FIG. 2 is a sectional view schematically showing a mechanism of ventilation around the image forming unit 12 by a fan. A temperature sensor 21 is provided around the image forming unit 12. Further, the ducts 22 and 23 are provided so as to sandwich the image forming unit 12, and the fine particle sensor 24 and the fan 25 are provided near the intake port 23 </ b> A of the duct 23, and are closer to the image forming unit 12 than the fan 25. A fine particle sensor 24 is provided, and a filter 26 is provided at an exhaust port 23 </ b> B of the duct 23. Further, a bypass duct 27 is connected to the duct 23, and a path selection valve 28 (path selection unit) is provided inside the bypass duct 27. The path selection valve 28 is rotated by an actuator 28B around a support shaft 28A of the path selection valve 28 as a rotation center.

The control unit 29 rotates the fan 25 at a predetermined standard operating speed in principle. When the air is sucked by the fan 25, air flows in the ducts 22 and 23 in the direction of arrow G, and the air passes through the inside of the image forming unit 12 and cools the image forming unit 12. The image forming section 12 is provided with a developing device for developing the electrostatic latent image on the surface of the photosensitive drum 4 into a toner image, and the developing device stores toner. When the temperature around the image forming unit 12 rises, the toner contained in the developing device and the untransferred toner removed from the surface of the photosensitive drum 4 are melted, so that the cooling of the image forming unit 12 by the fan 25 is performed. Required.

  The temperature sensor (temperature detection unit) 21 includes, for example, a thermistor, detects a temperature T around the image forming unit 12, and outputs a detection signal indicating the temperature T around the image forming unit 12 to the control unit 29.

  The fine particle sensor (soil detection unit) 24 detects the amount of particles such as untransferred toner and ultrafine particles released from the material exposed to high temperature, and determines the amount of the particles (hereinafter referred to as a stain degree K). The detected detection signal is output to the control unit 29. Since the particles are generated around the image forming unit 12, the particle sensor 24 receives the air flowing through the inside of the image forming unit 12 and flowing into the duct 23, and determines the amount of the particles (the degree of contamination K). Can be detected. As the fine particle sensor 24, a biomolecular interaction analyzer (NAPICOS, a registered trademark of Nihon Dempa Kogyo KK) or the like can be applied.

  The filter 26 passes through the air flowing from the fan 25 through the duct 23 to collect and remove the particles contained in the air. Then, the air from which the particles have been removed is discharged from the filter 26 to the outside of the image forming apparatus 10. As a result, in-machine pollution is reduced, and environmental pollution is prevented.

  Here, the control unit 29 drives the fan 25 to rotate, inputs the detection signal output from the temperature sensor 21 and the detection signal output from the particle sensor 24, and drives the actuator 28B based on these detection signals. Then, the position (posture) of the path selection valve 28 is switched by rotating the path selection valve 28. When the path selection valve 28 is switched to the position P1 as shown in FIG. 2, the air flows from the fan 25 through the duct 23 and further passes through the filter 26 to the outside of the image forming apparatus 10 as described above. Is formed, a filter path F is formed.

  When the path selection valve 28 is switched from the position P1 to the position P2 as shown in FIG. 3, the air mainly flows from the fan 25 to the bypass duct 27 through the duct 23, and from the bypass duct 27 to the image forming apparatus 10 Is formed to form a bypass path B that is discharged to the outside. Since the air flowing through the duct 23 receives a large resistance when passing through the filter 26 of the filter path F and does not receive a resistance when passing through the bypass path B, when the bypass path B is formed, most of the air flows. It is discharged to the outside through the bypass path B. At the same time, the flow rate of the air blown out from the fan 25 increases, and the flow rate of the air passing through the inside of the image forming unit 12 also increases, so that the cooling effect of the image forming unit 12 increases.

  On the other hand, the control unit 29 can control the image forming unit 12 to control the image forming speed (process speed) of the image forming unit 12, and based on the detection signals of the temperature sensor 21 and the fine particle sensor 24, The cooling mode in which the image forming speed of the forming unit 12 is reduced is set or not set. When the cooling mode is set, the control unit 29 reduces the image forming speed of the image forming unit 12 to a predetermined speed. When the cooling mode is set, an increase in the temperature around the image forming unit 12 is suppressed, and the inside contamination is also reduced. Furthermore, when the cooling mode is set, the control unit 29 lowers the conveyance speed of the recording paper and suppresses the amount of heat generated by the fixing device 15 for fixing the toner image on the recording paper. Therefore, in the cooling mode, the number of recordings per unit time, that is, the productivity is reduced.

  In such a configuration, setting or non-setting of the filter path F or the bypass path B and the cooling mode is selected according to conditions as shown in the table of FIG. Thereby, the productivity of the image forming apparatus 10, the management of contamination inside the machine, environmental pollution, noise, and the like are properly performed.

  As is apparent from the table of FIG. 4, under the condition that the temperature T around the image forming unit 12 is high and the degree of air contamination K is low, the bypass path B is selected and the cooling mode is not set. . In this case, the flow rate of the air blown from the fan 25 increases, the cooling effect of the image forming unit 12 increases, and the temperature T around the image forming unit 12 decreases. Further, since the cooling mode is not set, the productivity does not decrease.

  Further, under the condition that the temperature T around the image forming unit 12 is high and the degree of air contamination K is high, the filter path F is selected and the cooling mode is set. In this case, the particles contained in the air are removed by the filter 26, and the in-machine pollution is reduced, and the air from which the particles are removed is discharged to the outside, thereby preventing environmental pollution. Further, since the cooling mode is set, a rise in the temperature around the image forming unit 12 is suppressed, and thereby, the inside contamination is reduced.

  Further, under the condition that the temperature T around the image forming unit 12 is low and the degree of air contamination K is high, the filter path F is selected and the cooling mode is not set. In this case, the particles contained in the air are removed by the filter 26, so that the in-machine pollution is reduced and the environmental pollution is prevented. Further, since the cooling mode is not set, the productivity does not decrease.

  Further, even under the condition that the temperature T around the image forming section 12 is low and the degree of air contamination K is low, the filter path F is selected and the cooling mode is not set. Therefore, the particles contained in the air are removed by the filter 26, so that the in-machine pollution is reduced and the environmental pollution is prevented. Further, since the cooling mode is not set, the productivity does not decrease.

  Next, a processing procedure for selecting setting or non-setting of the filter path F or the bypass path B and the cooling mode will be described with reference to the flowchart shown in FIG.

  First, the control unit 29 determines whether the temperature T around the image forming unit 12 detected by the temperature sensor 21 exceeds a preset temperature threshold th, and determines whether the air temperature detected by the particle sensor 24 is higher. It is determined whether or not the contamination degree K exceeds a preset contamination degree threshold kh (step S101).

  Then, the control unit 29 determines that the temperature T detected by the temperature sensor 21 is higher than the temperature threshold th, and determines that the contamination degree K detected by the fine particle sensor 24 is equal to or less than the contamination degree threshold kh ( (Step S101 “T> th, K ≦ kh”), the path selection valve 28 is controlled to select the bypass path B, and the cooling mode is not set (step S102). Therefore, under the condition that the temperature T around the image forming unit 12 in the table of FIG. 4 is high and the degree of air pollution K is low, the bypass path B is selected and the cooling mode is not set. It will be.

  Further, the control unit 29 determines that the temperature T detected by the temperature sensor 21 is higher than the temperature threshold th and determines that the contamination degree K detected by the fine particle sensor 24 is higher than the contamination degree threshold kh ( In step S101 “T> th, K> kh”), the path selection valve 28 is controlled to select the filter path F and set the cooling mode (step S103). Accordingly, under the condition that the temperature T around the image forming unit 12 in the table of FIG. 4 is high and the degree of air contamination K is high, the filter path F is selected and the cooling mode is set. Become.

  Further, the control unit 29 determines that the temperature T detected by the temperature sensor 21 is equal to or lower than the temperature threshold th and determines that the contamination degree K detected by the fine particle sensor 24 is higher than the contamination degree threshold kh ( Step S101 “T ≦ th, K> kh”), the path selection valve 28 is controlled to select the filter path F, and the cooling mode is not set (step S104). Therefore, the filter path F is selected and the cooling mode is not set under the condition that the temperature T around the image forming unit 12 in the table of FIG. 4 is low and the degree of air contamination K is high. It will be.

  Further, the control unit 29 determines that the temperature T detected by the temperature sensor 21 is equal to or lower than the temperature threshold th, and determines that the contamination degree K detected by the particle sensor 24 is equal to or lower than the contamination threshold kh ( Step S101 “T ≦ th, K ≦ kh”), the path selection valve 28 is controlled to select the filter path F, and the cooling mode is not set. Accordingly, the filter path F is selected and the cooling mode is not set under the condition that the temperature T around the image forming unit 12 in the table of FIG. 4 is low and the degree of air contamination K is low. It will be.

  Thereafter, steps S101 to S105 are repeated, and each time, setting or non-setting of the filter path F or the bypass path B and the cooling mode is selected.

  As described above, in the first embodiment, the temperature T and the degree of contamination K around the image forming unit 12 are detected to determine whether the temperature T is higher than the temperature threshold th, and the degree of contamination K is kh is determined, and based on these determination results, the filter path F or the bypass path B is formed, and the cooling mode is set or not set. When the bypass path B is formed, the cooling mode of the image forming unit 12 is not set because the cooling effect of the image forming unit 12 is enhanced. Accordingly, it is possible to prevent the temperature of the image forming unit 12 from rising while suppressing the setting frequency of the cooling mode and suppressing the decrease in the productivity of the image forming apparatus 10.

  Further, when the bypass path B is formed, the image forming unit 12 can be efficiently cooled without increasing the rotation speed of the fan 25, and without increasing the noise generated from the fan 25.

  Further, when the temperature T is higher than the temperature threshold th and the pollution degree K is higher than the pollution degree threshold kh, a filter path F is formed and a cooling mode is set to effectively suppress in-machine pollution and environmental pollution. ing.

  In the first embodiment, the rotation speed of the fan 25 is fixed, but the rotation speed of the fan 25 may be changed according to the temperature T around the image forming unit 12. For example, when the temperature T detected by the temperature sensor 21 is equal to or lower than the temperature threshold th, the control unit 29 sets the rotation speed of the fan 25 to a normal rotation speed, and sets the rotation speed of the fan 25 to be lower than the standard operation speed. The speed is reduced by a predetermined speed, or the fan 25 is stopped.

  When determining that the temperature T exceeds the temperature threshold th, the control unit 29 sets the rotation speed of the fan 25 higher than the standard operation speed by the predetermined speed, and passes through the image forming unit 12. By increasing the amount of air, the rise in temperature around the image forming unit 12 is effectively suppressed. However, since noise increases due to an increase in the rotation speed of the fan 25, it is preferable to appropriately determine the upper limit of the rotation speed of the fan 25.

  Further, the temperature T detected by the temperature sensor 21 is compared with a plurality of different thresholds th set in advance, and the degree of contamination K detected by the particle sensor 24 is compared with a plurality of thresholds different from each other. kh, and based on the comparison result, the filter path F or the bypass path B may be selected, and the cooling mode may be set or not set.

  For example, the temperature T detected by the temperature sensor 21 is compared with a first temperature threshold th1 and a second temperature threshold th2 lower than the first temperature threshold th1, and the temperature T is distinguished between high, medium, and low. The pollution degree K detected by the fine particle sensor 24 is compared with the first pollution degree threshold kh1 and the second pollution degree threshold kh2 lower than the first pollution degree threshold kh1, and the pollution degree K is classified into high, medium, and low. I do. Then, as shown in the table of FIG. 6, the filter path F or the bypass path B is selected for each of the nine types of conditions obtained by combining the high, medium, and low temperatures T and the high, medium, and low pollution degrees K, and cooled. Set or unset the mode. Furthermore, the operating state of the fan 25 may be switched between high-speed rotation, medium-speed rotation, and stop according to the high, medium, and low temperatures T.

  In the above-described embodiment, the control unit 29 drives the actuator 28B to rotate and move the path selection valve 28 based on each determination result, thereby switching the position (posture or angle) of the path selection valve 28. , The filter path F or the bypass path B is formed, but instead, the control unit 29 drives the actuator 28B to change the attitude of the path selection valve 28 according to each of the above determination results. Thus, the size ratio of the filter path F and the bypass path B may be changed.

  Also, according to the first modification as shown in FIG. 7A, the filter path and the bypass path can be switched. In the first modification, the bypass duct 27 shown in FIG. 3 is omitted. Further, the filter 26 is rotatably supported by a support shaft 31 passing through a virtual center line of the filter 26, and an actuator 32 for rotating the filter 26 about the support shaft 31 is provided. The control unit 29 controls the actuator 32 to rotate the filter 26 around the support shaft 31, and changes the filter 26 to one of a direction orthogonal to and parallel to the flow of air in the duct 23. When the filter 26 is oriented perpendicular to the flow of air in the duct 23 as shown in FIG. 7A, a filter path F is formed in which air passes through the filter 26 and is discharged to the outside. You. When the filter 26 is oriented in parallel to the flow of air in the duct 23 as shown in FIG. 7 (B), the air is discharged to the outside without passing through the filter 26. B is formed.

  FIGS. 8A and 8B are cross-sectional views schematically illustrating a mechanism of ventilation of the image forming unit 12 by a fan in the image forming apparatus 10 according to the second embodiment.

  In this embodiment, the bypass duct 27 shown in FIG. 3 is omitted, and a first filter 41 and a second filter 42 are used instead of the filter 26 shown in FIG. The first filter 41 and the second filter 42 are integrally provided so as to be orthogonal to each other at respective virtual center lines, and are rotatably supported by a rotation shaft 43 common to the first filter 41 and the second filter 42. Is rotated about the rotation shaft 43 by the actuator 44.

  For example, as illustrated in FIG. 8A, the control unit 29 controls the actuator 44 to rotate the first filter 41 and the second filter 42 around the rotation axis 43 and move the first filter 41 inside the duct 23. The second filter 42 is oriented in a direction perpendicular to the air flow and in a direction parallel to the air flow. In this case, a first filter path is formed in which air passes through the first filter 41 and is discharged to the outside.

  Further, as shown in FIG. 8B, the control unit 29 controls the actuator 44 to rotate the first filter 41 and the second filter 42 around the rotation axis 43, and moves the second filter 42 inside the duct 23. The first filter 41 is oriented in a direction perpendicular to the air flow and in a direction parallel to the air flow. In this case, a second filter path is formed in which air passes through the second filter 42 and is discharged to the outside.

  The first filter 41 is a fine filter, and has a high particle collection rate and hardly allows air to pass through. The second filter 42 is a coarse filter, and has a lower particle collection rate than the first filter 41 and allows air to pass easily. Therefore, when the first filter path is formed, the particles contained in the air are effectively removed by the first filter 41, so that the in-machine pollution is effectively reduced, and the environmental pollution is sufficiently prevented. However, the flow rate of the air blown from the fan 25 is reduced, and the cooling effect of the image forming unit 12 is reduced. When the second filter path is formed, the effect of removing the particles contained in the air by the second filter 42 is not sufficient, but the flow rate of the air blown out from the fan 25 increases. As a result, the cooling effect of the image forming unit 12 increases.

  The control unit 29 determines whether or not the temperature T around the image forming unit 12 detected by the temperature sensor 21 exceeds a preset temperature threshold th, and determines whether or not the air pollution detected by the particulate It is determined whether or not the degree K exceeds a preset pollution degree threshold kh, and the first result is determined according to the result of these determinations, that is, whether the temperature T is high or low and whether the pollution degree K is high or low. Select setting or non-setting of the filter path or the second filter path and the cooling mode.

  For example, as shown in the table of FIG. 9, under the condition that the temperature T around the image forming unit 12 is high and the degree of air contamination K is low, the second filter path is selected and the cooling mode is not set. Is done. In this case, the flow rate of the air blown from the fan 25 increases, the cooling effect of the image forming unit 12 increases, and the temperature T around the image forming unit 12 decreases. Further, since the cooling mode is not set, the productivity does not decrease. Further, the particles contained in the air are removed by the second filter 42.

  Further, under the condition that the temperature T around the image forming unit 12 is high and the degree of air contamination K is high, the first filter path is selected and the cooling mode is set. In this case, the particles contained in the air are effectively removed by the first filter 41, so that the in-machine pollution is reduced, and the air is discharged to the outside, thereby preventing environmental pollution. Further, since the cooling mode is set, a rise in the temperature around the image forming unit 12 is suppressed, and thereby, the inside contamination is reduced.

  Further, under the condition that the temperature T around the image forming unit 12 is low and the degree of air contamination K is high, the first filter path is selected and the cooling mode is not set. In this case, the particles contained in the air are effectively removed by the first filter 41, thereby reducing in-machine pollution and preventing environmental pollution. Further, since the cooling mode is not set, the productivity does not decrease.

  Further, even under the condition that the temperature T around the image forming unit 12 is low and the degree of air contamination K is low, the first filter path is selected and the cooling mode is not set. Therefore, the particles contained in the air are effectively removed by the first filter 41, so that the in-machine pollution is reduced and the environmental pollution is prevented. Further, since the cooling mode is not set, the productivity does not decrease.

  Thereby, the productivity of the image forming apparatus 10, the management of contamination inside the machine, environmental pollution, noise, and the like are properly performed.

  Also in the second embodiment, the rotation speed of the fan 25 may be changed or the fan 25 may be stopped according to the temperature T around the image forming unit 12.

  Further, the temperature T detected by the temperature sensor 21 is compared with a plurality of different thresholds th set in advance, and the degree of contamination K detected by the particle sensor 24 is compared with a plurality of thresholds different from each other. kh, and based on the result of the comparison, the first filter path or the second filter path may be selected, and the cooling mode may be set or not set.

  Also, the first filter path and the second filter path can be switched by the second modification as shown in FIG. In the second modification, a vertical duct 51 is connected to the duct 23, and a path selection valve 52 is provided on the side of the fan 25 from which air is blown out and below the vertical duct 51. The control unit 29 receives the detection signal output from the temperature sensor 21 and the detection signal output from the particle sensor 24, drives the actuator 53 based on these detection signals, and rotates and moves the path selection valve 52. The position of the path selection valve 52 is switched. When the path selection valve 52 is switched to the position P1 as shown in FIG. 10A, air flows from the fan 25 through the duct 23, further passes through the first filter 41, and is outside the image forming apparatus 10. A first filter path is formed that is discharged to When the path selection valve 52 is switched from the position P1 to the position P2 as shown in FIG. 10B, air flows from the fan 25 through the vertical duct 51, further passes through the second filter 42, and passes through the image forming apparatus. A second filter path is formed that is discharged to the outside of 10.

  Further, the configuration and processing described with reference to FIGS. 1 to 10 are merely embodiments of the present invention, and are not intended to limit the present invention to the configuration and processing.

DESCRIPTION OF SYMBOLS 10 Image forming apparatus 11 Image reading part 12 Image forming part 15 Fixing device 21 Temperature sensor 22, 23 Duct 24 Particle sensor 25 Fan 26 Filter 27 Bypass duct 28 Route selection valve 29 Control part 41 First filter 42 Second filter

Claims (11)

An image forming unit that forms a toner image on recording paper;
A temperature detection unit that detects a temperature around the image forming unit,
A stain detection unit that detects the degree of stain around the image forming unit,
A fan for ventilating air around the image forming unit,
Air discharged to the outside by the fan is passed, and a filter having a function of collecting the air,
A filter path through which air is discharged to the outside through the filter, and a path selection unit that selectively forms one of a bypass path through which the air is discharged to the outside without passing through the filter.
It is determined whether the temperature around the image forming unit detected by the temperature detecting unit is higher than a preset temperature threshold, and contamination around the image forming unit detected by the contamination detecting unit is determined. Determine whether the degree is higher than a preset pollution degree threshold, based on these determination results, control the path selection unit, to form any of the filter path and the bypass path, and A control unit that sets or non-sets a cooling mode that reduces the image forming speed by the image forming unit ,
The control unit determines that the temperature around the image forming unit detected by the temperature detection unit is higher than the temperature threshold, and determines the degree of contamination around the image forming unit detected by the contamination detection unit. An image forming apparatus that controls the path selecting unit to form the bypass path and that does not set the cooling mode, when it is determined that the cooling mode is not more than the contamination degree threshold value . The control unit determines that the temperature around the image forming unit detected by the temperature detection unit is higher than the temperature threshold, and determines the degree of contamination around the image forming unit detected by the contamination detection unit. There when it is determined to be higher than the pollution degree threshold, and controls the path selection unit, an image forming apparatus according to claim 1, wherein the filter path is formed, and sets the cooling mode. An image forming unit that forms a toner image on recording paper;
A temperature detection unit that detects a temperature around the image forming unit,
A stain detection unit that detects the degree of stain around the image forming unit,
A fan for ventilating air around the image forming unit,
Air discharged to the outside by the fan is passed, and a filter having a function of collecting the air,
A filter path through which air is discharged to the outside through the filter, and a path selection unit that selectively forms one of a bypass path through which the air is discharged to the outside without passing through the filter.
It is determined whether the temperature around the image forming unit detected by the temperature detecting unit is higher than a preset temperature threshold, and contamination around the image forming unit detected by the contamination detecting unit is determined. Determine whether the degree is higher than a preset pollution degree threshold, based on these determination results, control the path selection unit, to form any of the filter path and the bypass path, and A control unit that sets or non-sets a cooling mode that reduces the image forming speed by the image forming unit,
The control unit determines that the temperature around the image forming unit detected by the temperature detecting unit is equal to or lower than the temperature threshold, and determines the degree of contamination around the image forming unit detected by the contamination detecting unit. There when it is determined to be higher than the contamination degree threshold, the path selection unit to control, the filter path is formed, and the cooling mode is not set and to that images forming device. An image forming unit that forms a toner image on recording paper;
A temperature detection unit that detects a temperature around the image forming unit,
A stain detection unit that detects the degree of stain around the image forming unit,
A fan for ventilating air around the image forming unit,
Air discharged to the outside by the fan is passed, and a filter having a function of collecting the air,
A filter path through which air is discharged to the outside through the filter, and a path selection unit that selectively forms one of a bypass path through which the air is discharged to the outside without passing through the filter.
It is determined whether the temperature around the image forming unit detected by the temperature detecting unit is higher than a preset temperature threshold, and contamination around the image forming unit detected by the contamination detecting unit is determined. Determine whether the degree is higher than a preset pollution degree threshold, based on these determination results, control the path selection unit, to form any of the filter path and the bypass path, and A control unit that sets or non-sets a cooling mode that reduces the image forming speed by the image forming unit,
The control unit determines that the temperature around the image forming unit detected by the temperature detecting unit is equal to or lower than the temperature threshold, and determines the degree of contamination around the image forming unit detected by the contamination detecting unit. There when it is determined that the at defacement degree below the threshold, the path selection unit to control, the filter path is formed, and the cooling mode is not set and to that images forming device. When the temperature around the image forming unit detected by the temperature detection unit exceeds the temperature threshold, the control unit increases the rotation speed of the fan by a predetermined speed from a predetermined standard operation speed. high, when the temperature falls below the temperature threshold value, the rotational speed of the fan and the standard operating rate, as low as a predetermined rate than the standard operating speed a rotational speed of the fan, or the fan the stop, the image forming apparatus according to any one of claims 1 to 4 set to any. An image forming unit that forms a toner image on recording paper;
A temperature detection unit that detects a temperature around the image forming unit,
A stain detection unit that detects the degree of stain around the image forming unit,
A fan for ventilating air around the image forming unit,
Air discharged to the outside by the fan is passed, and a filter having a function of collecting the air,
A filter path through which air is discharged to the outside through the filter, and a path selection unit that selectively forms one of a bypass path through which the air is discharged to the outside without passing through the filter.
It is determined whether the temperature around the image forming unit detected by the temperature detecting unit is higher than a preset temperature threshold, and contamination around the image forming unit detected by the contamination detecting unit is determined. Determine whether the degree is higher than a preset pollution degree threshold, based on these determination results, control the path selection unit, to form any of the filter path and the bypass path, and A control unit that sets or non-sets a cooling mode that reduces the image forming speed by the image forming unit,
A plurality of different temperature thresholds are set in advance as the temperature threshold,
A plurality of different contamination degree thresholds are preset as the contamination degree threshold,
The control unit includes:
Comparing the plurality of temperature thresholds with the temperature around the image forming unit detected by the temperature detecting unit, and the degree of contamination and the plurality of degrees of contamination around the image forming unit detected by the contamination detecting unit. comparing the threshold, based on these comparison results, and controls the path selector, the form either of a filter path and the bypass path, and the setting of the cooling mode or the non-set with images formed you apparatus. The path selecting unit changes the filter to one of a direction orthogonal to and a direction parallel to the flow of air discharged to the outside by the fan, so that air passes through the filter and moves to the outside. filter path to be discharged, and an image forming apparatus according to any one of claims 1 to 6 to form either a bypass path to be discharged to the outside without air passing through the filter. An image forming unit that forms a toner image on recording paper;
A temperature detection unit that detects a temperature around the image forming unit,
A stain detection unit that detects the degree of stain around the image forming unit,
A fan for ventilating air around the image forming unit,
A first filter;
A second filter having a lower particle collection rate than the first filter;
A first filter path where air passes through the first filter and is discharged to the outside, and a second filter path where air passes through the second filter and is discharged to the outside, is selectively formed. A route selection unit to perform,
It is determined whether the temperature around the image forming unit detected by the temperature detecting unit is higher than a preset temperature threshold, and contamination around the image forming unit detected by the contamination detecting unit is determined. It is determined whether or not the degree is higher than a preset contamination degree threshold, and based on these determination results, the path selection unit is controlled, and any one of the first filter path and the second filter path is determined. A control unit configured to set or not set a cooling mode for forming and reducing an image forming speed by the image forming unit. The control unit determines that the temperature around the image forming unit detected by the temperature detection unit is higher than the temperature threshold, and determines the degree of contamination around the image forming unit detected by the contamination detection unit. 9. The image forming apparatus according to claim 8 , wherein when it is determined that is equal to or less than the contamination degree threshold value, the path selection unit is controlled to form the second filter path and not to set the cooling mode. . The control unit determines that the temperature around the image forming unit detected by the temperature detection unit is higher than the temperature threshold, and determines the degree of contamination around the image forming unit detected by the contamination detection unit. If There were determined to be higher than the pollution degree threshold, and controls the path selector, to form the first filter path, and an image according to claim 8 or claim 9 sets the cooling mode Forming equipment. The first filter and the second filter are integrally provided so as to be rotatable about a common rotation axis,
The path selection unit is configured to rotate the first filter and the second filter about the rotation axis and to cause one of the first filter and the second filter to be discharged to the outside by the fan. The first filter path through which the air passes through the first filter and is discharged to the outside, and the air flows through the first filter path by making the direction orthogonal to the flow and the other direction parallel to the flow of the air. second image forming apparatus according to any one of claims 8 to 10 to form either a second filter path is discharged to the outside through the filter.