JP2000235338A - Image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image forming device capable of effectively cooling by controlling the quantity and the direction of cooling air based on the detection result of the temp. sensor, the flow speed sensor, or the like incorporated in the image forming device. SOLUTION: A copying device 30 is provided with fans 71 to 83, in order to cool appropriately by air the respective units for optical, image forming, developing and power supplying, simultaneously provided with the temp. sensor for detecting the temp. of hot spot in the respective unit and with the flow speed sensor for detecting flow speed of the cooling air. The control part efficiently and appropriately execute the air cooling for the respective unit by respectively controlling the operation including stoppage of the fan 71 to 83 based on detecting result of the temp. sensor and the flow speed sensor. Therefore, the image forming device appropriately controls the temp. of respectively unit in accordance with the operational state of the copying device 30 and keeps stabilized image quality.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image forming apparatus, and more particularly, to an image forming apparatus based on detection results of a temperature sensor, a flow rate sensor, and the like provided in a unit formed image forming apparatus such as a copying machine or a laser printer. The present invention relates to an image forming apparatus that controls the amount and direction of cooling air to effectively cool the cooling air.

[0002]

2. Description of the Related Art In recent years, electronic devices, particularly information processing devices such as computers, have a central processing unit (CPU).
With the rapid increase in the speed t), the amount of generated heat is large and the demand for downsizing of equipment has been increasing, so how to cool efficiently has become an important issue.

In a conventional information processing device such as a computer, a fan is constantly operated to cool the inside of the device while the device is in use. However, consideration is given to environmental considerations such as fan noise and wasted energy. In addition, with the spread of personal computers and higher performance, documents and images to be created are also required to be full-color and high-resolution image quality, and as personal computers are further downsized, Image forming apparatuses such as digital copiers and laser printers are also required to be further miniaturized due to the demands of office environments.

In response to such demands, image forming apparatuses such as copiers and printers require high-density mounting of various units housed in a housing in order to achieve miniaturization. However, when high-density mounting is performed, heat generated by the electronic components and frictional heat of the driving unit are discharged, and a flow path, which is a passage for cooling air that was sufficiently secured before the density is increased, cannot be provided. In addition, it has become difficult to secure a sufficient flow path, and it has become difficult to appropriately circulate air and appropriately cool each unit. Therefore, as the size of the image forming apparatus is reduced, the temperature rise in the housing increases, and the reliability of the image forming apparatus may be impaired.

Therefore, various countermeasures have conventionally been taken, for example, a control system having a central processing unit (hereinafter, referred to as a CPU), a memory, a hard disk drive, a floppy disk drive, and a heating electric component of a power supply. A local cooling fan for cooling the heat-generating electric parts, an air chamber for passing air sent by the local cooling fan into the housing, and exhausting air passing through the air chamber to the outside of the housing. An air-cooling unit has been proposed in which the exhaust fan is configured so that the exhaust scene of the exhaust fan is larger than the cooling air volume of the local cooling fan (Japanese Patent Laid-Open No. 6-195155). Gazette).

Also, an enclosure surrounding the operating elements of the personal computer, a printed circuit board mounted in the enclosure for supporting and interconnecting the operating elements of the personal computer, and the personal computer mounted on the printed circuit board and mounted on the printed circuit board A heat generating element that achieves the operation function of, a fan for sucking air into the enclosure, a fan for exhausting air from the enclosure, and one of the intake fan and the exhaust fan in the enclosure. A baffle mounted in the airflow path and near the heat generating element to direct the airflow passing through the enclosure to pass over the heat generating element and cool the element;
Has been proposed (see Japanese Patent Application Laid-Open No. 4-273507).

[0007] However, in a complicated apparatus such as an image forming apparatus, the inside of the apparatus is unitized and many units are arranged today. It is necessary to perform appropriate air cooling every time.

That is, for example, a copying apparatus as an image forming apparatus is roughly divided into an optical unit, an image forming unit, a developing unit, a fixing unit, a power supply unit and the like, and each unit is housed in a main body housing. I have.

More specifically, as shown in FIG. 5, the copying apparatus includes an optical unit 2, an image forming unit 3, a developing unit 4, a fixing unit 5 and a power supply unit (not shown) in a main body 1a. The optical unit 2 is housed, and is disposed horizontally above the main body housing 1a. The optical unit 2 projects light from a lamp 6 such as a halogen lamp onto a document set on a contact glass 7 and reflects the reflected light through a mirror 8 and a lens 9 to a CCD.
(Charge Coupled Device) Injects into the sensor 10 and C
The image of the document is read by the CD sensor 10.

The heat generated from the lamp 6 is remarkable, and when a halogen lamp is used as the lamp 6, the temperature inside the contact glass 7 and the optical unit 2 rises due to the infrared rays of the irradiation light from the lamp 6. Therefore, the optical unit 2 is provided with the cross flow fans 11 and 12 capable of generating a large air volume, and the inside of the optical unit 2 is air-cooled by forced air cooling to prevent the temperature of the optical unit 2 from rising. .

The image forming unit 3 includes a charging unit 14 and a cleaning unit 1 disposed around a photosensitive member 13 that is driven to rotate.
The charging unit 14 applies a charge of about 1 KV to the photoconductor 13 in advance using corona discharge by the charging unit 14 and irradiates light of an image read by the optical unit 2 to form an electrostatic latent image. .

In the image forming unit 3, since the surface of the photosensitive member 13 is uniformly charged by a high voltage in the charging unit 14, the air is dielectrically broken down, and positive ions of H ₃ O ⁺ and O
The negative ions (ozone) of ₃ ⁻ remain in the image forming unit 3 excessively even after the charging, which hinders normal ionization of air and increases the ambient temperature during the next charging. Therefore, air in the image forming unit 3 is exhausted by a fan (not shown) to perform ventilation and prevent a rise in temperature.

The developing unit 4 includes a developing unit 16, a transfer belt 17, a transfer unit 18, and the like. The developing unit 17 applies toner to the photoreceptor 13 on which an electrostatic latent image is formed, and develops the toner image. Is formed on the photoconductor 13. The developing unit 4 transfers the toner image adhered to the photoreceptor 13 to the transfer belt 17 and then, from the paper feed trays 19 to 21 stored in the lower part of the main body housing 1a, as shown by arrows in FIG. Then, the image is transferred from the transfer belt 17 to the recording paper conveyed to the transfer unit 18 by the transfer unit 18 and is conveyed to the fixing unit 5 as indicated by an arrow in FIG.

The developing unit 4 rotates a developing unit 16 containing a ferrite carrier or a stirrer having a weight of about 200 g therein with a considerably large torque, and the temperature rises. 4 is being cooled.

After the transfer of the photosensitive member 13 is completed, the photosensitive member 13 is neutralized by the neutralizing section of the image forming unit 3, and then the cleaning section 1 is removed.
5 removes the residual toner, is charged again by the charging unit 14, and an electrostatic latent image is formed in the same manner as described above.

The recording paper on which the toner image has been transferred is heated and pressed by a fixing unit 5 having a fixing roller 22 having a built-in lamp heater and being heated, and a pressing roller 23 pressed against the fixing roller 22. Then, the toner image is fixed on the recording paper, and is discharged to a discharge tray (not shown) provided on the side of the main body housing 1a.

In this fixing unit 5, since the fixing roller 22 is heated to about 150 ° C., the ambient temperature of the fixing unit 5 reaches about 70 ° C. to 80 ° C., which significantly affects the surroundings. The surrounding air is exhausted to the outside of the main body housing 1a by the fan 24 to perform forced air cooling.

Further, a power supply unit (not shown) converts an AC public power supply into a direct current by an AC / DC converter, and supplies a direct current to each unit. Since the conversion element generates heat, an aluminum heat sink is heated by a fan. Air cooled,
It is cooled to the stable operating temperature of the conversion element.

In such a copying apparatus, unlike an electronic device such as a personal computer, the amount of heat generated in the main body casing 1a is remarkably large, and efficient cooling can reduce the image quality of a read image or a recorded image. It is important to improve the quality and to prevent deterioration of the copying apparatus.

Conventionally, as an air cooling technique using a fan of a unit-configured device, for example, one or a plurality of units are built in according to the system configuration, and the unit is connected to an air inlet by an air cooling fan. In an information processing device that is cooled by air taken in from a temperature sensor that is opened inside the information processing device and detects a temperature of the air near an air inlet that closes a part facing an exhaust unit with a skirt, A temperature / voltage conversion circuit for switching the voltage supplied to the cooling fan in response to the signal from the temperature sensor; and providing a hysteresis to the conversion characteristic of the temperature / voltage conversion circuit, and for a predetermined time during the initial operation, the cooling fan A conversion mode control circuit for instructing a high-speed rotation mode operation, wherein when the temperature rises and becomes equal to or higher than the operating temperature, the voltage is increased. And a cooling fan speed control method for switching the voltage to a low voltage when the temperature drops below a return temperature lower than the operating temperature (see Japanese Patent Publication No. 4-291). ). In this cooling fan rotation speed control method, the rotation speed of the fan is controlled according to the outside air temperature.

Further, in addition to the above, Japanese Patent Application Laid-Open No.
08, JP-A-6-33
Electronic device described in Japanese Patent Application Laid-Open No. 5285/1993 and JP-A-5-2518
No. 84 discloses a forced air cooling device and the like.

[0022]

However, in the above-described conventional cooling technique, there is still a need for improvement in appropriately cooling the unitized image forming apparatus using a fan.

That is, today, the unitization and miniaturization are progressing, and it is difficult to secure a sufficient air passage in the housing, and each unit in the housing in which a plurality of units are provided is provided. In order to effectively cool the cooling device, the conventional cooling technology described above does not sufficiently consider the unitization and the miniaturization, and needs to be improved.

According to the first aspect of the present invention, the temperature of at least a main part of various functional units for recording at least an image stored in the main body housing on a recording paper is detected by a temperature detecting means, and based on the detection result. By controlling the operation of a plurality of cooling means for cooling each functional unit with cooling air to cool each functional unit to a predetermined temperature, each functional unit is cooled according to the operating state of the image forming apparatus. It is an object of the present invention to provide an image forming apparatus that can control the temperature to an appropriate temperature and stabilize the image quality.

According to the second aspect of the present invention, by controlling the operation, the operation stop, the operation time, and the flow rate of the cooling air of the plurality of cooling means, each functional unit can be more appropriately used according to the operation state of the image forming apparatus. It is an object of the present invention to provide an image forming apparatus capable of controlling the temperature to an appropriate temperature and further stabilizing the image quality.

According to a third aspect of the present invention, based on pressure loss data of the flow path of the cooling air generated by the cooling means and data indicating the relationship between the flow rate of the cooling air by the cooling means,
By controlling the operation state of each of the plurality of cooling units and adjusting the air volume, the operation of the cooling unit is appropriately controlled in accordance with the state of the pressure loss in the cooling air flow path, and each functional unit is more appropriately controlled. It is an object of the present invention to provide an image forming apparatus capable of controlling the temperature to a higher temperature and further stabilizing the image quality.

According to a fourth aspect of the present invention, the operating state of each of the plurality of cooling means is controlled based on the reference temperature data to be maintained by each of the main parts and the detection result of each of the temperature detecting means. Accordingly, an object of the present invention is to provide an image forming apparatus capable of cooling a main part to an appropriate temperature and further stabilizing image quality.

According to a fifth aspect of the present invention, a wind direction changing means provided in a flow path of cooling air generated by the cooling means and changing a wind direction of cooling air flowing through the flow path is controlled,
By adjusting the wind direction of the cooling air, for example, when two functional units are cooled by one cooling unit, when it is desired to increase the cooling of only one of the functional units, the cooling air flow path is branched. A wind direction changing means is provided, and the wind direction changing means is controlled while monitoring the temperature rise,
Provided is an image forming apparatus that supplies an optimal amount of air flow to two functional units, reduces the number of cooling units, and further stabilizes image quality while further reducing the size of the apparatus. The purpose is.

According to a sixth aspect of the present invention, by controlling the operating state of the cooling means on the basis of the detection result of the flow velocity detecting means for detecting the flow velocity of the cooling air generated by the cooling means, an appropriate air volume is adjusted. It is another object of the present invention to provide an image forming apparatus capable of controlling the temperature of each functional unit to a more appropriate temperature and stabilizing the image quality.

[0030]

According to the present invention, there is provided an image forming apparatus according to the present invention, wherein at least various functional units for recording an image on recording paper are stored in a main body housing. Temperature detecting means for detecting the temperature of at least the main part, a plurality of cooling means for cooling each of the functional units with cooling air, and controlling the operation of the cooling means based on the detection result of the temperature detecting means. The above-mentioned object is achieved by providing control means for cooling each of the functional units to a predetermined temperature.

That is, a temperature sensor is provided at a place where the temperature is highest in various functional units in the image forming apparatus, for example, optical, image forming, developing, fixing and power supply units.
When power is supplied to the inside of the apparatus, the temperature is constantly detected and monitored by the temperature detecting means during standby or operation, and the operating voltage of the cooling means is controlled according to the temperature rise. For example, since the temperature in each of the optical, image forming, and developing functional units that are not operating during standby is not so high, the operation of the cooling unit is stopped. On the other hand, since the fixing unit is heated and held to some extent and the ambient temperature is somewhat high, control is performed to operate the cooling means at a certain air flow in order to keep the temperature within the allowable temperature.

According to the above configuration, the temperature of at least the main part of each of the various functional units that record at least the image stored in the main body housing on the recording paper is detected by the temperature detecting means, and each function is detected based on the detection result. By controlling the operation of a plurality of cooling means for cooling each unit by cooling air,
Since each functional unit is cooled to a predetermined temperature, the temperature of each functional unit can be controlled to an appropriate temperature according to the operating state of the image forming apparatus, and image quality can be stabilized.

In this case, for example, as described in claim 2, the control means may control the operation, stop, and operation time of the plurality of cooling means and the flow rate of the cooling air. .

According to the above configuration, the operation, stop, operation time, and flow rate of the cooling air of the plurality of cooling units are controlled, so that each functional unit is set to a more appropriate temperature in accordance with the operation state of the image forming apparatus. The temperature can be controlled, and the image quality can be further stabilized.

Further, for example, as set forth in claim 3, the control means is configured to determine the pressure loss data of the flow path of the cooling air generated by the cooling means and the flow rate of the cooling air by the cooling means. It may have data indicating the relationship, and control the operation states of the plurality of cooling means to adjust the air flow based on the data.

That is, the cooling means provided for air-cooling each functional unit is also provided with an air flow path for cooling the heat generating portion in the functional unit. From various functional units to the discharge side, it is bent or narrowed in the middle of the flow path, or branched into a plurality of flow paths. In such a flow path, the flow of air is not uniform and stagnation or the like occurs, so that the air volume changes and a cooling effect may not be obtained. This phenomenon is referred to as pressure loss, and is a serious problem in an image forming apparatus in which each functional unit is arranged without a gap. Therefore, the pressure loss of the flow path is stored in advance in the control means as data for each cooling means, and the operating voltage of the cooling means is controlled so as to obtain an appropriate air volume, so that the cooling air to the heat generating portion is Blow properly.

According to the above configuration, the operation states of the plurality of cooling units are determined based on the pressure loss data of the flow path of the cooling air generated by the cooling unit and the data indicating the flow rate of the cooling air by the cooling unit. Since each control is performed to adjust the air volume, it is possible to appropriately control the operation of the cooling means in accordance with the state of the pressure loss of the cooling air flow path, and to control the temperature of each functional unit to a more appropriate temperature. Image quality can be further stabilized.

Further, for example, as described in claim 4, the control means has reference temperature data to be maintained by each of the main parts in the main body casing, The operation state of each of the plurality of cooling units may be controlled based on a result and the reference temperature data.

According to the above configuration, the operating state of each of the plurality of cooling units is controlled based on the reference temperature data to be maintained by each of the main units and the detection result of each of the temperature detecting units. The main part can be cooled to an appropriate temperature, and the image quality can be further stabilized.

Further, for example, as set forth in claim 5, the image forming apparatus is provided in a flow path of the cooling air generated by the cooling means, and changes a wind direction of the cooling air flowing through the flow path. Further comprising wind direction changing means for causing
The control means may control the wind direction changing means to adjust the wind direction of the cooling air.

According to the above construction, the direction of the cooling air is adjusted by controlling the direction changing means provided in the flow path of the cooling air generated by the cooling means and changing the direction of the cooling air flowing through the flow path. Therefore, for example, when two functional units are cooled by one cooling unit, when it is desired to increase the cooling of only one of the functional units, a wind direction changing unit is provided at a location where the flow path of the cooling air branches, and By controlling the wind direction changing means while monitoring the temperature rise, it is possible to supply an optimum ratio of air flow to the two functional units, reduce the number of cooling means installed, and further reduce the size of the apparatus while maintaining the image quality. Quality can be further stabilized.

Further, for example, as set forth in claim 6, the image forming apparatus further includes a flow rate detecting means for detecting a flow rate of the cooling air generated by the cooling means, and the control means includes: The operation state of the cooling means may be controlled based on a detection result of the flow velocity detecting means.

According to the above configuration, the operation state of the cooling means is controlled based on the detection result of the flow velocity detecting means for detecting the flow velocity of the cooling air generated by the cooling means. The temperature of the functional unit can be controlled to a more appropriate temperature, and the image quality can be further stabilized.

[0044]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. It should be noted that the embodiments described below are preferred embodiments of the present invention, and therefore, various technically preferable limitations are added. However, the scope of the present invention is not limited to the following description. The embodiments are not limited to these embodiments unless otherwise specified.

FIGS. 1 to 4 show a copying apparatus to which an embodiment of the image forming apparatus of the present invention is applied.

In FIG. 1, the copying apparatus 30 includes a main body housing 31 and a paper feeding housing 32. An optical unit 33, an image forming unit 34, a developing unit 35, a fixing unit 36, and a power supply unit 37 (FIG.
And the like. The recording paper stored in the three paper feed cassettes 38 to 40 and the paper feed cassettes 38 to 40 (not shown) is stored in the main body housing 31.
And a transport mechanism for transporting the developer to the developing unit 35.

The optical unit 33 is disposed horizontally above the main body housing 31 and includes a lamp 4 such as a halogen lamp.
1, a mirror 42, a lens 43, a CCD sensor 44, a contact glass 45, and the like. Optical unit 3
3 projects the light from the lamp 41 onto the original set on the contact glass 45, and reflects the reflected light on the mirror 42.
And into the CCD sensor 44 by the lens 43 and the like,
The image of the document is read by the CCD sensor 44.

The lamp 41 generates heat with a power consumption of about 140 W and raises the temperature inside the optical unit 33. Therefore, as will be described later, cooling air flows through the optical unit 33, and And the contact glass 45 is air-cooled.

The image forming unit 34 includes a photosensitive member 46 that is driven to rotate counterclockwise as indicated by an arrow in FIG. 1, a charging unit 47 and a cleaning unit 48 disposed around the photosensitive member 46, and the like. The photoreceptor 46 having been neutralized and cleaned by the cleaning unit 48 is uniformly charged by the charging unit 47, and an electrostatic latent image is formed on the photoreceptor 46 by the optical unit 33.

The developing unit 35 includes a developing section 49, a transfer belt 50, transfer sections 51 and 52, a transport belt 53 and the like. The developing unit 35 sequentially applies red, cyan, magenta, and black toners to the photoreceptor 46 on which the electrostatic latent image is formed by the developing unit 49 to perform color development.
In step 1, the toner images of each color are sequentially transferred to the transfer belt 50 to form a color toner image, and then the transfer unit 52 transfers the recording paper conveyed between the transfer belt 50 and the transfer unit 48 from the paper feeding unit 41 to the transfer unit 52. The color toner image is transferred and transported to the fixing unit 36.

The recording paper is transported between the transfer unit 52 and the transfer belt 50 by a transport mechanism from the plurality of paper cassettes 38 to 40 in the paper feed housing 32, and the transfer unit 52 transfers the color toner image. Then, the sheet is conveyed to the fixing unit 36 by the conveying belt 53.

The fixing unit 36 includes a fixing roller 54 having a built-in lamp heater and driven to rotate, and a fixing roller 54.
A pressure roller 55 that rotates in synchronization with the fixing roller 54 while being pressed against the fixing roller 54. The fixing roller 54 and the pressure roller 55 that heat the recording paper to which the toner image adhered are heated. The toner image is conveyed while being pressed to fix the toner image on the recording paper. The fixing unit 36 discharges the recording paper on which the toner image has been fixed onto a discharge tray (not shown) attached to the side surface of the main body housing 31.

The power supply unit 37, as shown in FIG.
A plurality of power ICs 57 are mounted on the power supply board 56, and an aluminum heat sink 58 is attached to the power ICs 57, for example. A wind direction valve 59 is rotatably attached to the power supply board 56. The wind direction valve 59 is rotated by a predetermined angle by a motor 60 to adjust the direction of the flow of cooling air, as described later. used.

As shown in FIG. 3, the main body housing 31 has, as cooling means, a developing fan 71, intake fans 72 and 73 and an exhaust fan 74 for the optical unit 33, an exhaust fan 74, and an intake fan 75 for the power supply unit 37. , An exhaust fan 76, an exhaust fan 77, 78, 79 for the fixing unit 36, an intake fan 80 and an exhaust fan 81 for exhausting ozone, an exhaust fan 82 for air-cooling an image processing board, and an exhaust for external discharge. A fan 83 and the like are provided, and fans 84 and 85 are provided. In FIG. 3,
Fans 77, 79, 8 with deep hatching
Reference numerals 1 and 83 denote fans with an ozone filter, and the fans 72, 73, 76, and 7 are provided with thin hatching.
Reference numerals 8 and 80 denote fans with a dustproof filter.

The developing fan 71 sucks air from the bottom surface of the main body housing 31 and forms a flow of air that passes through the conveyor belt 53 shown in FIG. 1 and the right side of the fixing unit 36 in FIG. Then, the developing unit 35 is air-cooled.

The intake fans 72 and 73 are
3 is disposed on the optical unit 33 in a state where air sucked from the outside of the main body housing 31 is blown to the opposite side (back side) of the side on which the original is placed on the contact glass 45. The sucked air is discharged out of the main body housing 31 by the exhaust fan 74.

The intake fan 75 sucks air outside the main body housing 31 into the power supply unit 37 and discharges the air inside the power supply unit 37 with the exhaust fan 81. That is, the intake fan 75 and the exhaust fan 81 cool the inside of the power supply unit 37 in a push-pull relationship.

The exhaust fans 77 to 79 are connected to the fixing unit 3
The air inside 6 is discharged to the outside of the main body housing 31 to cool the inside of the fixing unit 36 with air.

The intake fan 80 sucks air from outside the main body housing 31 into the image forming unit 34, and the exhaust fan 81
The charging unit 47 discharges various ions such as ozone generated by the dielectric breakdown of air into the image forming unit 34. The intake fan 80 and the exhaust fan 81 of the image forming unit 34 are formed to suck and exhaust air into and out of a plastic mold 90 that communicates the image forming unit 34 with the outside of the main body housing 31.

The exhaust fan 82 air-cools the board for image processing, and the exhaust fan 83 exhausts the air in the main housing 31 to the outside of the main housing 31.

The fans 84 and 85 are connected to the conveyor belt 5
3 is a fan for sucking the recording paper conveyed by 3 to the conveyance belt 53, and is not directly related to air cooling, but is used for air cooling in the main body housing 31, particularly, in the developing unit 35. Interfering with air flow.

Further, in the main body housing 31, temperature sensors (temperature detecting means) are respectively attached to main parts which are places where the temperatures of the units 33 to 37 are highest (hereinafter, referred to as hot spots). Each temperature sensor detects the temperature of the attached hot spot and outputs the detected temperature to a control unit (not shown) of the copying apparatus 30.

Although not shown, a plurality of flow rate sensors (flow rate detecting means) for measuring the flow rate of the cooling air flowing through each of the units 33 to 37 are provided in the main body casing 31. For example, a flow rate sensor using germanium measures the flow rate of the cooling air at each of the attached positions, and outputs the measured flow rate to a control unit (not shown).

The control unit (control means) includes, for example, a CPU
(Central Processing Unit), a ROM (Read Only Memory) for storing a basic control program of the copying apparatus 30 and an air cooling control program described later, a RAM (Random Access Memory) as a work memory, and the like.
Based on the program in the OM, each unit 33 to 37 of the copying apparatus 30 is controlled to perform basic processing as the copying apparatus 30 and to perform air cooling control processing.

Next, the operation of the present embodiment will be described. The copying apparatus 30 irradiates the original on the contact glass 45 with light from the lamp 41 of the optical unit 33, and reflects the reflected light by the mirror 42 and the lens 43, etc.
4, the image is read into an image of a document by the CCD sensor 44, and an electrostatic latent image is formed on the photoreceptor 46 uniformly charged by the charging unit 47 of the image forming unit 34.

The photoreceptor 46 on which the electrostatic latent image has been formed by the optical unit 33 is rotated in the direction of the arrow in FIG.
In the developing unit 49 of the developing unit 35, red, cyan, magenta, and black toners are sequentially attached and developed. The toner of each color adhered to the photoreceptor 46 is sequentially transferred to the transfer belt 50 by the transfer unit 51 to form a color toner image, and the transfer belt 50 and the transfer unit 48 are transferred from one of the paper feed cassettes 38 to 40. The transfer section 52 transfers the color toner image to the recording paper that has been conveyed during the period, and conveys the recording paper on which the color image has been formed to the fixing unit 36.

The fixing unit 36 has a built-in lamp heater, and the toner conveyed between the rotating fixing roller 54 and the pressure roller 55 pressed in contact with the fixing roller 54 and rotating in synchronization with the fixing roller 54. The recording paper on which the image is adhered is conveyed while being heated and pressurized, the toner image is fixed on the recording paper, and the recording paper on which the toner image is fixed is mounted on a discharge tray (not shown) attached to the side surface of the main body housing 31. Discharge up.

In the above operation, the optical unit 33
Since the temperature inside the optical unit 33 rises due to the lamp 41 generating heat with power consumption of about 140 W, it is necessary to cool the optical unit 33.

Although the temperature of the image forming unit 34 rises, it is necessary to discharge the ions because the charging section 47 causes the dielectric breakdown of the air to generate ions such as ozone.

Further, since the developing unit 35 has an integrated structure other than a toner supply opening (not shown),
If the air flow is too fast, the toner scatters and contaminates the surroundings. Therefore, air cooling by a fan is not performed.

In the fixing unit 36, the fixing roller 54 is heated to about 150 ° C. by a lamp heater to perform fixing, and the temperature of the outer side plate of the fixing unit 36 rises from 70 ° C. to about 80 ° C. It is necessary to air cool to prevent the ambient temperature from rising.

Further, the power supply unit 37 needs to be air-cooled because the temperature of the power IC 57 attached to the heat sink 58 rises.

Therefore, in the present embodiment, in order to properly cool the units 33 to 37 by air, the fans 71 to 83
And a temperature sensor for detecting the temperature of the hot spot of each of the units 33 to 37 is provided. The control unit operates based on the detection result of the temperature sensor, including stopping each of the fans 71 to 83. To efficiently and appropriately air-cool the units 33 to 37.

That is, in the fixing unit 36, for example, after the power of the copying apparatus 30 is turned on, the lamp heater of the fixing roller 54 is turned on to start heating the fixing roller 54. Usually, it takes about one minute. Therefore, immediately after the power of the copying apparatus 30 is turned on, the temperature around the fixing unit 36 does not rise so much and is about room temperature, for example, about 30 ° C., so that the exhaust gas for cooling the fixing unit 36 is discharged. Fan 7
The operations of Steps 7 to 79 are stopped, and thereafter, the copying operation of the copying apparatus 30 is started, and when the temperature sensor detects that the temperature around the fixing unit 36 exceeds 40 ° C.,
The operation of the exhaust fans 77 to 79 is started, and the fixing unit 36 is air-cooled.

In the optical unit 33, the temperature rise in the optical unit 33 is usually 25 ° C. in one copy operation.
Because it is not so big, natural air cooling is enough,
The control unit stops the operations of the intake fans 72 and 73 and the exhaust fan 74 of the optical unit 33, and the continuous copy operation is continued for about ten sheets, and the temperature sensor raises the temperature in the optical unit 33 to about 34 ° C. Is detected, the driving of the intake fans 72 and 73 and the exhaust fan 74 is started, and the air cooling in the optical unit 33 is started. afterwards,
The control unit performs no copy operation and controls the intake fans 72 and 7
When the temperature sensor detects that the temperature in the optical unit 33 has decreased to a predetermined temperature by operating the exhaust fan 74 and the exhaust fan 74 for about one minute, the operation of the intake fans 72 and 73 and the exhaust fan 74 is stopped.

As described above, the copying machine 30 is
A temperature sensor detects at least the temperature of at least a main part of each of the various units 33 to 37 housed in the unit 1, and based on the detection result, the control unit cools each of the units 33 to 37 with cooling air. The operation of 71 to 83 is controlled to cool each unit 33 to 37 to a predetermined temperature.

Therefore, the temperature of each of the units 33 to 37 can be controlled to an appropriate temperature according to the operation state of the copying apparatus 30, and the image quality can be stabilized.

The copying apparatus 30 controls the operating voltage of the fans 71 to 83 in accordance with the temperature rise of each of the units 33 to 37.

For example, in the optical unit 33, when the copying operation of the copying apparatus 30 is not performed, the temperature does not rise. Therefore, the control unit stops the operations of the intake fans 72 and 73 and the exhaust fan 74, and When the temperature sensor detects that the operation in the optical unit 33 has started to increase and the temperature in the optical unit 33 has started to rise, the intake fans 72, 73 and Control is performed so that the operating voltage of the exhaust fan 74 is gradually increased. The control unit includes the intake fans 72, 7
When the temperature rise stops, the operating voltages of the intake fans 72, 73 and the exhaust fan 74 are reduced, and when the temperature decreases to a predetermined temperature, the intake fan 72 is operated. , 73 and the exhaust fan 74 are stopped.

Therefore, cooling air having a flow rate corresponding to the temperature in the optical unit 33 flows in the optical unit 33, and appropriately and efficiently cools the inside of the optical unit 33 according to the temperature rise. be able to.

In the fixing unit 36, even when the copying operation of the copying apparatus 30 is not performed, if the power of the copying apparatus 30 is turned on, the lamp heater of the fixing roller 54 is turned on to fix the fixing roller. Since the temperature of the fixing unit 54 is maintained at a predetermined standby temperature, the control unit monitors the ambient temperature of the fixing unit 36 with a temperature sensor, and in order to prevent the temperature from rising to a predetermined temperature or higher, the exhaust fans 77 to 7.
9 is operated at a relatively low operating voltage and is cooled by a relatively small air volume. Further, if the copying operation of the copying apparatus 30 is performed continuously, the temperature of the fixing roller 54 decreases, so that full power is supplied to the lamp heater, and the temperature of the fixing roller 54 is maintained at the fixing temperature. Therefore, the temperature around the fixing unit 36 also increases. When the temperature sensor detects the temperature increase, the control unit increases the operating voltage of the exhaust fans 77 to 79 to increase the air volume,
The temperature around the fixing unit 36 is prevented from rising.

As described above, the copying apparatus 30 controls the operation, the operation stop, the operation time, and the flow rate of the cooling air of the plurality of fans 71 to 83.

Therefore, the temperature of each of the units 33 to 37 can be controlled to a more appropriate temperature in accordance with the operation state of the copying apparatus 30, and the image quality can be further stabilized.

Further, the copying apparatus 30 generates cooling air having an appropriate air volume to each of the fans 71 to 83 based on the relationship between the air volume loss and the flow rate of each of the fans 71 to 83. Work as follows.

That is, even if the fans 71 to 83 have the same operating voltage due to the location and flow path provided in the copying apparatus 30, the flow rate of the flowing air is different, and the fans 71 to 83 supply the appropriate flow rate of air. The operating conditions required to perform this are different.

For example, in the optical unit 33, the relationship between the pressure loss and the air flow rate (air volume) is as shown in FIG. 4 when the rotation speeds of the intake fans 72 and 73 and the exhaust fan 74 are 50 Hz and 60 Hz. FIG. 4 shows the relationship between the pressure loss of the flow path and the flow rate of air flowing through the flow path. FIG. 4 shows the characteristics of each of the fans 71 to 83.
The intersection of the flow path characteristic and the air volume-static pressure curve is the fan 71 to 83
Operating point.

The RAM or ROM of the control unit stores the data on the relationship between the pressure loss and the flow rate in each of the fans 71 to 8.
3 and the flow path are stored in advance, and the control unit easily calculates the air volume required for cooling based on this relational data, and sets the operating conditions of each of the fans 71 to 83, that is, the operating voltage and the ON state of the operation. / Off, operation time, etc. are set optimally for operation.

For example, in the optical unit 33, the pressure loss is large because the carriage is in the flow path inside the optical unit 33.
Since it is not possible to obtain a sufficient air volume for air cooling with only the two intake fans 72, 73, as described above, one exhaust fan 74 is provided and the two intake fans 72, 7 are provided.
3 and one exhaust fan 74 have a push-pull relationship. The control unit controls the optical unit 3 based on the detection result of the temperature sensor provided in the optical unit 33.
3 to monitor the air cooling state, and when it is determined that the air cooling effect is small, the exhaust fan 74 is operated to increase the air volume,
Control such as changing the operating voltage of the intake fans 72 and 73 and the exhaust fan 74 is performed.

As described above, the copying apparatus 30 includes the fan 71
The operation state of each of the plurality of fans 71 to 83 is controlled based on the data indicating the relationship between the pressure loss data of the flow path of the cooling air generated by the fans 83 to 83 and the flow rate of the cooling air by the fans 71 to 83. Has been adjusted.

Therefore, the operation of the fans 71 to 83 can be appropriately controlled in accordance with the state of the pressure loss in the cooling air flow passage, and the temperature of each of the units 33 to 37 can be controlled to a more appropriate temperature. Quality can be further stabilized.

Further, the copying apparatus 30 can be configured such that each of the fans 71 to 71 is based on a preset reference temperature.
83 is controlled.

That is, the copying apparatus 30 includes the units 3
There is a reference temperature at which the valves 3 to 37 operate properly. If the air cooling is excessive, the air cooling is not performed for the temperature rise, or there is a delay, the proper operation is hindered.

Therefore, in the copying apparatus 30, for example, a reference temperature that operates properly is stored in the RAM or ROM of the control unit in advance, and the control unit determines the temperature of each unit of each of the units 33 to 37 based on the detection result of the temperature sensor. Monitor temperature. The control unit appropriately controls the operation of each of the fans 71 to 83 based on the detection result of the temperature sensor without excessively cooling the air, not performing the cooling with respect to the temperature rise, or causing no delay. And perform appropriate air cooling. In particular, since the copying apparatus 30 is often installed in an office and is often affected by the temperature in the office in each season, the reference temperature is set to, for example, 20 ° C. Control to perform air cooling in a certain situation.

In this case, as described above, the control unit calculates the amount of air required for cooling based on the data on the relationship between the pressure loss and the flow rate, and sets the operating conditions of each of the fans 71 to 83 optimally to operate. You may make it do.

As described above, the copying machine 30 is
The operating state of each of the plurality of fans 71 to 83 is controlled based on the reference temperature data to be maintained by each of the main parts and the detection results of the respective temperature sensors.

Therefore, the main part can be cooled to an appropriate temperature, and the image quality can be further stabilized.

Further, the copying apparatus 30 may adjust the flow of air flowing through the air flow path.

For example, the power supply unit 37 of the copying apparatus 30
Is a heat sink 58 made of aluminum, as shown in FIG.
A plurality of power ICs 57 are attached to the power supply unit 37, and a wind direction valve 59 is attached to a flow path of the air flowing through the power supply unit 37, and can be rotated by a predetermined angle by a motor 60. The power supply unit 37 is connected to the copier 30.
When the copying operation is continuously performed, a plurality of power ICs
Since the 57 operates at the same time with full power, the temperature of the hot spot rises, and the temperature may not be able to be appropriately reduced by normal fan operation.

Thus, the copying apparatus 30 of the present embodiment
The temperature of the hot spot of the power supply unit 37 is detected by a temperature sensor (not shown), and when the temperature of the hot spot is equal to or lower than a predetermined temperature, the control unit changes the flow of the air flowing through the air flow path through the wind direction valve 59 by the motor 60. When the temperature of the hot spot exceeds a predetermined temperature, the motor 60
Is operated to turn the wind direction valve 59 at a predetermined angle in the direction of the heat sink 58 (the direction of the position shown by the broken line in FIG. 2).

Therefore, the air flowing in the air flow path in the power supply unit 37 (this air flows from left to right in FIG. 2) flows in the direction of the heat sink 58, so that the air flows efficiently. The heat sink 58 and the power IC 57 can be cooled.

As described above, the copying apparatus 30 includes the fan 71
83 is provided in the flow path of the cooling air generated by the cooling air passage 83 and changes the wind direction of the cooling air flowing through the flow path.
Is controlled to adjust the wind direction of the cooling air.

Therefore, each of the units 33 to 37 can be cooled more efficiently, and the image quality can be improved.

Also, for example, when cooling two units with one fan, if it is desired to increase the cooling of only one unit, a wind direction valve 59 is provided at a location where the flow path of the cooling air is branched. By controlling the valve 59 while monitoring the temperature rise, it is possible to supply an air flow at an optimal ratio to the two units, reduce the number of fans to be installed, further reduce the size of the copying apparatus 30, and improve the image quality. Can be further stabilized.

Further, the copying apparatus 30 controls the operation of each of the fans 71 to 83 based on the flow rate of the cooling air detected by the flow rate sensor provided in the main body casing 31, as in claim 6. I have.

That is, a plurality of flow rate sensors (not shown) for measuring the flow rate of the cooling air flowing through each of the units 33 to 37 are provided in the main body casing 31. The flow rate of the air is measured and output to a control unit (not shown). The control unit controls the operation of each of the fans 71 to 83 based on the detection result of the flow velocity sensor to flow cooling air having a flow velocity appropriate for each of the units 33 to 37, thereby improving image quality.

For example, in the image forming unit 34, although there is a rise in temperature, the charging section 47 causes the dielectric breakdown of the air to generate ions such as ozone.
This may cause uneven charging of the photoreceptor 46 and deteriorate image quality. However, this imaging unit 34
As described above, since the temperature does not increase so much as described above, the operation of the intake fan 80 and the exhaust fan 81 of the image forming unit 34 may be stopped, but it is necessary to discharge ions as described above. .

When the flow rate sensor detects air stagnation in the image forming unit 34, the control unit detects
0 and the exhaust fan 81 are operated to exhaust the ions in the image forming unit 34.

As described above, the copying apparatus 30 includes the fan 71
The operation states of the fans 71 to 83 are controlled based on the detection result of the flow velocity sensor that detects the flow velocity of the cooling air generated by the fans 83 to 83.

Therefore, by adjusting the air volume to an appropriate value, the temperature of each of the units 33 to 37 can be controlled to a more appropriate temperature, and the image quality can be further stabilized.

Although the invention made by the inventor has been specifically described based on the preferred embodiments, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the gist of the invention. It goes without saying that it is possible.

For example, in the above-described embodiment, the case where the present invention is applied to a copying machine has been described. However, the image forming apparatus is not limited to the copying machine. Can be applied to

[0112]

According to the image forming apparatus of the first aspect of the present invention, the temperature of at least the main part of each of the various functional units for recording at least the image on the recording paper stored in the main body housing is detected by the temperature detecting means. Based on the detection result, the operation of a plurality of cooling means for cooling each functional unit with cooling air is controlled to cool each functional unit to a predetermined temperature. Accordingly, the temperature of each functional unit can be controlled to an appropriate temperature, and image quality can be stabilized.

According to the image forming apparatus of the second aspect of the present invention, the operation, stoppage, operation time, and flow rate of cooling air of the plurality of cooling means are controlled. The temperature of the functional unit can be controlled to a more appropriate temperature, and the image quality can be further stabilized.

According to the image forming apparatus of the present invention, based on the pressure loss data of the flow path of the cooling air generated by the cooling means and the data indicating the relationship between the flow rate of the cooling air by the cooling means, Since the operation state of each of the plurality of cooling units is controlled to adjust the air volume, the operation of the cooling unit is appropriately controlled in accordance with the state of the pressure loss of the cooling air flow path, so that each functional unit is set to a more appropriate temperature. , And the image quality can be further stabilized.

According to the image forming apparatus of the present invention, a plurality of cooling means are provided based on the reference temperature data to be maintained by the main parts and the detection results of the respective temperature detecting means. Since each operating state is controlled, the main part can be cooled to an appropriate temperature, and the image quality can be further stabilized.

According to the image forming apparatus of the present invention, the air flow direction changing means provided in the flow path of the cooling air generated by the cooling means and changing the air flow direction of the cooling air flowing through the flow path is controlled. And adjust the wind direction of the cooling air,
For example, when cooling two functional units with one cooling unit, when it is desired to increase the cooling of only one of the functional units, a wind direction changing unit is provided at a location where the flow path of the cooling air branches, and the wind direction changing unit is provided. By controlling the temperature while monitoring the temperature rise, it is possible to supply the air flow of the optimal ratio to the two functional units, reduce the number of cooling means installed, further reduce the size of the device, and improve the image quality. It can be further stabilized.

According to the image forming apparatus of the present invention, the operation state of the cooling means is controlled based on the detection result of the flow velocity detecting means for detecting the flow velocity of the cooling air generated by the cooling means. Temperature can be controlled to a more appropriate temperature by adjusting
Image quality can be further stabilized.

[Brief description of the drawings]

FIG. 1 is a front sectional view of a copying apparatus to which an embodiment of an image forming apparatus according to the present invention is applied.

FIG. 2 is a perspective view of a main part of a power supply unit of the copying apparatus of FIG.

FIG. 3 is a schematic diagram showing an attached state of a fan of the copying apparatus of FIG. 1;

FIG. 4 is a diagram showing a relationship between a pressure loss of an air flow path in an optical unit of the copying apparatus of FIG. 1 and an air flow rate.

FIG. 5 is a front sectional view showing an example of a conventional copying apparatus.

[Explanation of symbols]

 REFERENCE SIGNS LIST 30 copying apparatus 31 main body housing 32 paper feeding housing 33 optical unit 34 image forming unit 35 developing unit 36 fixing unit 37 power supply unit 38 to 40 paper feeding cassette 41 lamp 42 mirror 43 lens 44 CCD sensor 45 contact glass 46 photoconductor 47 Charging unit 48 Cleaning unit 49 Developing unit 50 Transfer belt 51, 52 Transfer unit 53 Conveying belt 54 Fixing roller 55 Pressure roller 56 Power supply board 57 Power IC 58 Heat sink 59 Wind direction valve 60 Motor 71 Developing fan 72, 73, 75, 77- 80 intake fan 74, 76, 81-83 exhaust fan 84, 85 fan

Claims (6)

[Claims] A temperature detecting means for detecting a temperature of at least a main part of each functional unit in an image forming apparatus in which various functional units for recording at least images on recording paper are housed in a main body housing; A plurality of cooling means for cooling the functional units with cooling air, and control means for controlling the operation of the cooling means based on the detection result of the temperature detecting means to cool the functional units to a predetermined temperature, An image forming apparatus comprising: 2. The image forming apparatus according to claim 1, wherein said control means controls operation, stop, and operation time of said plurality of cooling means, and a flow rate of said cooling air. 3. The control means has data indicating a relationship between pressure loss data of the flow path of the cooling air generated by the cooling means and a flow rate of the cooling air by the cooling means. The image forming apparatus according to claim 1, wherein an operation state of each of the plurality of cooling units is controlled based on the control to adjust an air volume. 4. The control means has reference temperature data to be maintained by each of the main parts in the main body casing, and based on the detection result of each of the temperature detection means and the reference temperature data, 4. The image forming apparatus according to claim 1, wherein an operation state of the cooling unit is controlled. 5. The image forming apparatus further includes a wind direction changing unit provided in a flow path of the cooling air generated by the cooling unit and changing a wind direction of cooling air flowing through the flow path. 5. The image forming apparatus according to claim 1, wherein the controller controls the wind direction changing unit to adjust a wind direction of the cooling air. 6. 6. The image forming apparatus further comprises a flow rate detecting means for detecting a flow rate of the cooling air generated by the cooling means, and the control means controls the cooling based on a detection result of the flow rate detecting means. 6. The image forming apparatus according to claim 1, wherein an operation state of the unit is controlled.