JPH05201578A - Belt meandering correction device for fixing device - Google Patents

Abstract

PURPOSE:To prevent sensors for detecting belt end and fault from producing abnormal rise in temperature due to heat radiation from a belt. CONSTITUTION:Belt end detection sensors 45a and 45b are positioned on both sides of an endless belt 41 apart from the endless belt 41. When a roller 49a is pressed by the end of the endless belt 41, a lever 47a is rotated clockwise about a pivot 48a, and the other end turns on the belt end detection sensor 45a. By this, the endless belt 41 meanders on the opposite side and, therefore, a roller 49a is pressed by the opposite side end of the endless belt 41 to change the meandering direction of the endless belt 41. If the belt end detection sensors 45a and 45b are not operated by some fault, fault detection sensors 52a and 52b are turned on by the levers 47a and 47b to stop the whole device.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fixing device of a type in which a toner image is thermally fixed on a sheet by pressing an endless belt against a heating roller, and a belt for correcting the meandering direction of the endless belt. The present invention relates to a meandering correction device.

[0002]

2. Description of the Related Art Generally, in an image forming apparatus using a dry toner such as an electronic copying machine or an image recording apparatus, a toner image formed on an image bearing member such as a photosensitive drum is transferred to a sheet and its undetermined state. The sheet carrying the deposited toner image is conveyed toward the fixing device, and the fixing device fuses the toner by applying heat or pressure to perform fixing.

As such a fixing device, a heating roller system is generally used in which a sheet is nipped between a pressure roller and a heating roller to fix the sheet by heat and pressure.
However, this heating roller type fixing device has a problem that wrinkles, image misalignment, etc. occur on the paper when the paper is passed between both rollers to be heated and pressed.

Therefore, the same applicant as the present applicant previously proposed a fixing device provided with a pressing mechanism by an endless belt mechanism and a belt meandering correction device for a heating roller (filed on March 15, 1991). ..

FIG. 4 shows the structure of the fixing device. The fixing device 1 is provided in a copying machine, and includes a heating roller 2 having a heating lamp 3 housed therein, a pressure belt mechanism 4 for pressing a sheet against the heating roller 2, and a pressure belt mechanism. 4 is composed of a pressure plate 5 for performing a pressing action from the back surface. Fixing device 1
The transport mechanism 6 and the guide plate 7 are arranged on the upstream side of
On the other hand, the discharge roller 8 is arranged on the downstream side. Also,
A temperature sensor 9 is provided for the heating roller 2 to adjust the temperature of the heating roller 2. A peeling claw 10 for peeling the fixed sheet from the heating roller 2 is arranged on the discharge side. The endless belt 11 that constitutes the pressure belt mechanism 4 is configured as an endless belt member by coating glass floss with fluororesin.

The endless belt 11 is wound around an advancing roller 12, a driving roller 13, a tension roller 14 and a meandering correction roller 15, which drives the belt.
Tension is set and meandering is prevented. Further, upstream of the position where the paper is set on the endless belt 11, belt end portion detection sensors 16a and 16b are arranged on both sides of the endless belt 11, respectively. With the belt edge detection sensors 16a and 16b,
While the fixing operation is being performed, the meandering of the endless belt 11 within the normal meandering range shown by A in FIG. 5 is detected, and the correcting operation is performed based on the detection signal. The tension roller 14 uses the spring 17 to form the endless belt 1.
A constant tension is applied to 1.

As the meandering correction roller 15, a long roller is arranged in the width direction of the endless belt 11, and meandering correction mechanisms are arranged at both ends of the roller shaft. This meandering correction mechanism is composed of a solenoid 18 and a link 19. The link 19 is swingable around a fulcrum 20, a solenoid 18 is connected to the base of the link 19, and a shaft 21 of the meandering correction roller 15 is connected to the other end. In this meandering correction mechanism, the solenoid 18 is driven by signals from the belt end portion detection sensors 16a and 16b, and the endless belt 1
The meandering correction roller 15 is swung according to the deviation of 1 to correct the position of the endless belt 11. The locus R of the meandering correction roller 15 swings along the entry roller 12
An ellipse having the axis of the center and the axis of the tension roller 14 as a focal point is drawn, and the meandering correction roller 15 is swung in accordance with the arc of the ellipse to form a guide mechanism for this roller.

Further, on both sides of the endless belt 11, as shown in FIG. 5, abnormality detecting sensors 22a and 22b are arranged at positions outside the belt end detecting sensors 16a and 16b. The abnormality detection sensors 22a and 22b detect the deviation of the endless belt 11 beyond a certain value, that is, the abnormal state in the abnormality detection range B.

FIG. 6 shows the meandering correction operation of the endless belt 11 in the normal meandering range A in this fixing device. FIG. 6A shows the state after the detection by the belt end portion detection sensor 16a. b) is a belt end detection sensor 16
The state after detection by b is shown. 6 is shown in FIG.
3 shows a cross-sectional structure viewed from the direction of arrow BB in FIG.
The endless belt 11 meanders and the belt end portion detection sensor 16a
Is detected, the solenoid 18 is in the off state, and the endless belt 11 meanders in the arrow direction while maintaining this state. When the endless belt 11 meanders in this state, the other belt end detection sensor 16b detects it, and the solenoid 18 is turned on to swing the meandering correction roller 15. As a result, the endless belt 11 shown in FIG.
As shown in (b), while meandering in the opposite direction, it moves again until the belt end portion detection sensor 16a detects the endless belt 11, and this operation is repeated thereafter.

By the way, in the previously proposed fixing device, the belt end detecting sensors 16a and 16b and the abnormality detecting sensors 22a and 22b are arranged in the vicinity of the endless belt 11, and these sensors are respectively provided in the belt 1.
It has a structure that directly contacts the end portion of No. 1 and detects a meandering state.

[0011]

However, in this fixing device, the endless belt 11 is heated by the heating roller 2 over the entire circumference during operation. Therefore, the radiant heat of the endless belt 11 causes the belt end portion detection sensor 16 to
a, 16b and the temperature of the abnormality detection sensors 22a, 22b rise to a high temperature of 100 ° C. or higher, and the guaranteed temperature (80
° C) is exceeded. Therefore, these sensors may malfunction or be damaged, making normal detection impossible.
As a result, normal correction of meandering and abnormal detection cannot be performed, and there is a problem that the endless belt 11 is damaged.

The present invention has been made in view of the above problems, and its purpose is to guarantee that the belt end portion and the sensor for detecting an abnormality do not cause an abnormal temperature rise due to radiant heat from the endless belt. To provide a belt meandering correction device for a fixing device, which can be kept at a temperature, does not cause malfunctions or thermal damages, can reliably detect the belt end portion, and can perform stable meandering correction. It is in.

[0013]

A belt meandering correction device of a fixing device according to the present invention includes a heating roller for heating and pressing a sheet carrying a toner image to melt the toner and fix the toner on the sheet. A belt as a pressurizing unit that presses the paper against the heating roller, a meandering correction signal output unit that is arranged apart from the belt and that outputs a meandering correction signal, and a belt according to the meandering state of the belt. A belt meandering transmission means for displacing and transmitting the belt meandering to the meandering correction signal output means, and a belt meandering correction means for receiving the meandering correction signal and correcting the meandering direction of the endless belt.

In the belt meandering correction device of the present invention, the meandering state of the belt is transmitted to the meandering correction signal output means through the belt meandering transmission means. When the meandering correction signal output means detects the meandering of the belt, it supplies a meandering correction signal to the belt meandering correction means. The belt meandering correction means that has received the meandering correction signal corrects the meandering direction of the belt, and thereafter repeats the same operation.

The meandering correction signal output means is specifically constituted by the above-mentioned belt end portion detection sensor, and can be arranged at a position separated from the belt by the above constitution. Therefore, the influence of the radiant heat from the belt, which becomes high temperature due to the heat from the heating roller during operation, on the belt end portion detection sensor is reduced, and an abnormal temperature rise can be prevented.

In the belt meandering correction device of the present invention,
In addition to the above configuration, when the meandering of the belt exceeds a certain value, a stop signal output means (abnormality detection sensor) for outputting an operation stop signal, and an apparatus for receiving a stop signal output from the stop signal output means Device stop means for stopping the entire operation is provided respectively, the stop signal output means is also arranged at a position separated from the belt, and the belt meandering transmission means also transmits the belt meandering to the stop signal output means. May be

With such a structure, by any chance,
When a trouble occurs in the meandering correction signal output means (belt end detection sensor), the operation of the apparatus is stopped when the meandering of the belt exceeds a certain value. Therefore, it is possible to prevent damage to expensive parts such as a belt and occurrence of defective fixing.

[0018]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a side view of a fixing device 31 according to one embodiment of the present invention, and FIG. 2 shows a C- line of FIG.
It shows the configuration as viewed from the direction of arrow C.

The fixing device 31 has a heat generating lamp 3 inside.
3, a pressure roller mechanism 35 for pressing the conveyed sheet 34, and a rear surface of the pressure belt mechanism 35 for performing a pressing action. The pressure plate 36 is used.

A transport mechanism 37 and a guide plate 38 are arranged on the upstream side of the fixing device 31, while a discharge roller (not shown) is arranged on the downstream side. In addition, the heating roller 3
A temperature sensor (thermistor) 39 is provided opposite to 2. A temperature control circuit (not shown) adjusts the temperature of the heating roller 32 based on the temperature detected by the temperature sensor 39. A peeling claw 40 for peeling the fixed sheet from the heating roller 32 is arranged on the discharge side.

The endless belt 41 constituting the pressure belt mechanism 35 is formed as an endless belt member by coating glass floss with fluororesin. The endless belt 41 is wound around the advancing roller 42, the driving roller 43, and the meandering correction roller 44, whereby the belt 41 is driven and the meandering correction is performed. Further, on the upstream side of the position where the sheet 34 of the endless belt 41 enters, belt end portion detection sensors 45 a and 45 b are provided on both sides of the endless belt 41, respectively.
It is arranged at a position separated from 1. These belt end portion detection sensors 45a and 45b detect the meandering of the endless belt 41 within the normal meandering range shown in FIG. 5A during the fixing operation, and perform the correcting operation based on the detection signal. It is like this.

The belt edge detecting sensors 45a and 45b are arranged on the frame 46, respectively. Frame 46
Lever 47a, 47b is further arrange | positioned on the top. The levers 47a and 47b are fulcrums 48a and 48, respectively.
It is rotatable about b. Lever 47a,
Rollers 49a and 49b are attached to one end of each 47b. The rollers 49a and 49b face the end surface of the endless belt 41, and either one of them contacts the end surface of the endless belt 41. The other ends of the levers 47a and 47b face the belt end detection sensors 45a and 45b, respectively.

A fulcrum 48 of each of the levers 47a and 47b
a, 48b and the intermediate portion between the rollers 49a, 49b,
The frame 46 is connected to the frame 46 by springs 50a and 50b, and the elastic forces of the springs 50a and 50b urge the levers 47a and 47b toward the endless belt 41, respectively. On the other hand, the levers 47a and 47b
The stopper 51 faces the intermediate portion on the other end side of each.
a and 51b are provided, whereby the lever 47
Each of a and 47b is held at an initial position along the end surface of the endless belt 41.

As the meandering correction roller 44, a roller long in the width direction of the endless belt 41 is arranged, and a meandering correction mechanism (not shown) is arranged at both ends of the roller shaft. This meandering correction mechanism is a belt end detection sensor 45a,
Actuated by the detection signal output from 45b, the meandering correction roller 44 is swung in accordance with the deviation of the endless belt 41 to correct the position of the endless belt 41. Since the details of the meandering correction mechanism are disclosed in the above-mentioned specification, the description thereof will be omitted.

Further, on the frame 46, abnormality detection sensors 52a and 52b are arranged at positions inside the belt end portion detection sensors 45a and 45b, respectively, and the endless belt 41 is provided by these abnormality detection sensors 52a and 52b. Of a certain value or more, that is, an abnormal state in the abnormal detection range B as shown in FIG. 5 is detected.

Next, the operation of the belt meandering correction device of this embodiment will be described with reference to FIGS. 1 and 2. Here, FIG.
Shows the state in which the endless belt 41 meanders to the right in the figure, and the belt end portion detection sensor 45a detects this.

The end surface of the endless belt 41 allows the roller 49a.
When is pressed, the lever 47a starts to rotate in the clockwise direction in the figure about the fulcrum 48a against the elastic force of the spring 50a. When the lever 47a rotates a certain amount, the other end of the lever 47a contacts the belt end detection sensor 45a, and the belt end detection sensor 45a is turned on. The detection signal of the belt end portion detection sensor 45a is sent to a meandering correction mechanism (not shown), and as a result, the meandering correction roller 44 swings by a predetermined amount and stops.

As a result, the endless belt 41 meanders to the opposite side, so that the roller 49b is pushed by the opposite end surface of the endless belt 41. As a result, the lever 47b rotates counterclockwise in the drawing around the fulcrum 48b against the elastic force of the spring 50b, and the other end of the lever 47b comes into contact with the belt end detection sensor 45b to turn on. To do. The detection signal of the belt end portion detection sensor 45b causes the meandering correction roller 44 to swing to the side opposite to the above, whereby the meandering direction of the endless belt 41 changes.

Further, the belt end detecting sensors 45a, 45
When b does not operate due to some abnormality, the levers 47a and 47b rotate further than the above-mentioned cases, respectively. As a result, the abnormality detection sensors 52a and 52b detect this and output from these sensors 52a and 52b. Upon receipt of the detection signal, a stop mechanism (not shown) operates to stop the entire device.

As described above, according to the belt meandering correction device of this embodiment, the end portions of the endless belt 41 can be reliably detected by the belt end portion detection sensors 45a and 45b and the abnormality detection sensors 52a and 52b. Moreover, since these sensors are arranged at positions separated from the endless belt 41, the influence of heat radiation from the endless belt 41 is reduced, and there is no possibility of causing an abnormal temperature rise.

FIG. 3 shows another embodiment of the present invention.

In the above embodiment, the parts necessary for detecting the belt end portions such as the belt end portion detection sensors 45a and 45b are arranged on both sides of the endless belt 41, but in the present embodiment, these components are arranged. Is arranged only on one end side of the endless belt 41.

That is, on the frame 60, there are arranged levers 61 which can be rotated in both clockwise and counterclockwise directions about a fulcrum 62, and belt end detecting sensors are provided on both sides of one end of the lever 61. 63a and 63b are arranged, and abnormality detection sensors 64a and 64b are arranged at positions outside of these sensors 63a and 63b. On the other hand, a roller 65 is attached to the other end side of the lever 61, and the lever 61 and the frame 60 are connected by a spring 66, and the elastic force of the spring 65 causes the roller 65 to constantly contact the end surface of the endless belt 41. It will be in the state where it did.

In the belt meandering correction device of this embodiment having such a structure, the lever 61 is always the endless belt 4
One of the belt end portion detection sensors 63a and 63b operates according to the meandering direction, following the movement of 1. As a result, the meandering correction roller 44 shown in FIG. 1 swings, and the meandering correction is performed. When an abnormality occurs, the abnormality detection sensor 64a,
The operation of the entire device is stopped by the operation of 64b.

According to this embodiment, like the above embodiment,
Since the end portions of the endless belt 41 can be reliably detected by the belt end portion detection sensors 63a and 63b and the abnormality detection sensors 64a and 64b, these sensors can be arranged at positions apart from the endless belt 41. No abnormal temperature rise will occur. Further, the number of parts is reduced as compared with the above embodiment, and the space can be effectively used.

[0037]

As described above, according to the belt meandering correction device of the fixing device according to the present invention, the meandering correction signal output means for outputting the meandering correction signal is arranged apart from the belt, and the meandering correction signal is provided. Since the belt meandering transmission means is used to transmit the belt meandering state to the output means, the meandering correction signal output means for detection or the like does not cause an abnormal temperature rise due to radiant heat from the belt and is within the guaranteed temperature range. Can be kept at Therefore, the belt end portion can be reliably detected without causing malfunction or thermal damage, and stable meandering correction can be performed.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a main configuration of a belt meandering correction device according to an embodiment of the present invention.

FIG. 2 is a diagram viewed from a direction of arrows CC in FIG.

FIG. 3 is a diagram showing a main configuration of a belt meandering correction device according to another embodiment of the present invention.

FIG. 4 is a cross-sectional view showing a configuration of a belt meandering correction device proposed previously.

5 is a view as seen from the direction of arrow AA in FIG.

6 is a view for explaining the operation of the belt meandering correction device of FIG. 4, and is a view seen from the direction of arrows BB of FIG.

[Explanation of symbols]

31 ... Fixing device, 32 ... Heating roller, 34 ... Paper, 44
... meandering correction rollers, 45a, 45b ... belt end detection sensor, 46 ... plates, 47a, 47b ... lever, 48
a, 48b ... fulcrum, 49a, 49b ... roller, 52a,
52b ... Abnormality detection sensor

Claims (1)

[Claims] 1. A heating roller that heats and presses a sheet carrying a toner image to melt the toner and fix the sheet on the sheet, and a belt as a pressing unit that presses the sheet against the heating roller. A meandering correction signal output means for outputting a meandering correction signal and a belt that is displaced in accordance with the meandering state of the belt and transmits the belt meandering to the meandering correction signal output means. A belt meandering correction device for a fixing device, comprising: meandering transmission means; and belt meandering correction means for receiving the meandering correction signal and correcting the meandering direction of the endless belt.