JPH0552244A - Belt driving device - Google Patents

Abstract

PURPOSE:To carry out the initial deflection of a belt with the simple constitution, as for a belt driving device which automatically detects and corrects the deflection. CONSTITUTION:A printing belt 3 is laid in traveling enabled form on the first and second rollers 1 and 2. A deflection component in the reverse direction is generated on the printing belt 3 by utilizing the revolution torque of a deflection detecting member 5 which is generated by the contact with the deflection detecting member 5 due to the deflection of the printing belt 3, and the initial deflection is eliminated. As a means for correcting the initial deflection, is provided a deflection adjusting member 6 for deflecting the printing belt 3 in the reverse direction to the initial deflection direction by increasing the belt tension of the edge part only by applying a pressing force at the edge part on the initial deflection direction side of the printing belt 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a belt driving device which is incorporated in a device using an electrophotographic system and uses a transfer belt, a photosensitive belt or the like.

[0002]

2. Description of the Related Art Conventionally, for example, in an electrophotographic apparatus, in order to reduce the weight and size of the apparatus,
A flat belt having a dielectric layer or a photoconductor layer on its surface is wound around a plurality of rollers arranged substantially parallel to each other, so that the flat belt is replaced with a transfer belt or a photoconductor drum instead of the transfer belt or the photoconductor drum. It is known to be used as a photoreceptor belt.

The base material of the flat belt used for such an application is often made of a material having a small elongation and a high strength such as a plastic film or a metal foil. Therefore, this type of flat belt is not easily elastically deformed. Therefore, when there are dimensional errors of parts housed in the electrophotographic apparatus, roller mounting errors, belt tension imbalance, uneven belt circumference, etc.,
These cannot be absorbed by the deformation of the belt itself. As a result, there is a problem that the flat belt deviates in the belt width direction during traveling.

However, since the electrophotographic apparatus is required to have high precision and high resolution in order to form an accurate image, it is necessary to prevent the flat belt from deviating.

As a conventional technique for preventing such a deviation of the flat belt, Japanese Patent Laid-Open No. 12750/1981 has been proposed.
No. 1 or JP-A-59-205052, a flat belt is provided with a guide for preventing deviation, and a restricting member is provided as shown in JP-A-57-60347. There is one that is designed to forcibly prevent deviation of the belt. In addition, the actual development Sho 58-11060
As disclosed in Japanese Patent Publication No. 9, a single roller is used as a deviation adjusting roller and a belt position sensor for detecting deviation is provided, and the deviation of the flat belt is detected by the belt position sensor. Then, the deviation is corrected by displacing the shaft end of the deviation adjusting roller in accordance with the deviation, or as disclosed in Japanese Utility Model Laid-Open No. 64-48457. When the flat belt is deviated, the roller is moved in the direction of the rotation axis along with the deviation, and the rotation shaft of the roller is swung by the movement of the roller to move the roller. There is one that corrects the deviation by moving it in the opposite direction.

[0006]

However, the above-mentioned JP-A-56-127501 and JP-A-59-2050 are known.
In the configurations as disclosed in Japanese Patent Laid-Open No. 52-52, and Japanese Patent Laid-Open No. 57-60347, the deviation of the flat belt is forcibly regulated by an external factor. There are cases where the mechanism cannot be established depending on the combination conditions of. That is, in the case where the deviation force due to the deviation of the flat belt becomes large, it is necessary to increase the strength of the guide and the regulation member. Further, it is necessary to increase the widthwise buckling strength of the flat belt itself, and at the same time, to increase the end strength so that the end portion of the flat belt is not damaged. Therefore, the thinner the belt, the more difficult it is to adopt the above method. Further, when the guide is provided on the flat belt, it is necessary to provide the guide with high precision, and particularly in the case of the seamless belt, it is very difficult to form this guide.

Further, in the constructions as disclosed in Japanese Utility Model Laid-Open No. 58-110609 and Japanese Utility Model Laid-Open No. 64-48457, the deviation is detected and corrected by using a complicated mechanism, which is expensive. Moreover, an extra space is required, which leads to an increase in size of the entire device. Not only that, but because of the complicated mechanism, the number of parts increases and the failure-causing factors increase accordingly, so it is hard to say that the reliability of the device is sufficiently secured. ..

In order to solve these problems, the inventors of the present invention are improving the structure of a belt drive device capable of automatically detecting and correcting the deviation. More specifically, one of the plurality of rollers is used as a deviation adjusting roller, and one side of the deviation adjusting roller is rotatable independently of the deviation adjusting roller. It is equipped with a motion detection roller. Then, the flat belt is configured to be biased in advance toward the deviation detecting roller. When the flat belt travels, the flat belt comes into contact with the deviation detecting roller due to its deviation, and this deviation causes the deviation detecting roller to rotate. A configuration is being developed in which the flat belt is given a deviation component in the opposite direction to correct the deviation.

In the belt driving device incorporated in the electrophotographic apparatus as described above, in order to further reduce the size and weight of the electrophotographic apparatus, it is desirable to configure the belt driving apparatus as a biaxial belt driving apparatus. ..

The present invention has been made in view of this point, and aims to improve the practicability of a belt driving device incorporated in an electrophotographic apparatus when a biaxial system is adopted as the apparatus. That is the purpose.

[0011]

In order to achieve the above object, the invention according to claims 1 and 2 sequentially corrects the deviation while preliminarily displacing the flat belt in a predetermined direction. The deviation of the flat belt is corrected by changing the belt tension of only one edge of the flat belt in the belt driving device. Specifically, the invention according to claim 1 is provided with a flat belt and a plurality of rollers around which the flat belt is stretched, which causes an initial deviation in the flat belt, and the flat belt. It is premised on a belt drive device that is biased in the direction opposite to the initial deviation direction to sequentially correct the initial deviation.
Then, when the initial deviation occurs in the flat belt, a pressing force is applied to an end edge portion of the flat belt on the initial deviation direction side to increase the belt tension only at the end edge portion. Is provided with a deviation adjusting member for causing the deviation in the direction opposite to the initial deviation direction.

According to a second aspect of the present invention, a flat belt and the flat belt are stretched around, and at least one flat belt is used for deviation adjustment.
A plurality of rollers configured as a roller and the deviation adjusting roller.
The deviation detecting member rotatably supported independently of the deviation adjusting roller at one shaft end of the la, and the flat belt is moved toward the position where the deviation detecting member is disposed. When the bias torque is applied to the deviation detection member and the flat belt is in contact with the deviation detection member, a rotational torque acts,
Utilizing the rotational movement, a deviation correcting means for moving the flat belt in a direction opposite to the moving direction of the offset imparting means is provided. Then, with the rotational movement of the deviation detecting member, a pressing force is applied to the deviation correcting means to an edge portion of the flat belt on the side where the deviation detecting member is disposed, and the edge is corrected. A bias adjusting member for moving the flat belt in a direction opposite to the moving direction of the offset applying means is provided by increasing the belt tension of only the portion.

According to the third aspect of the present invention, while displacing the flat belt in a predetermined direction in advance, one axial end portion of the roller is displaced to sequentially correct this eccentricity. With respect to the belt driving device, the displacement amount of the shaft end portion of the roller is adjusted by the flat belt. Specifically, a flat belt, a plurality of rollers around which the flat belt is wound, and at least one roller is configured as a deviation adjusting roller, and one of the deviation adjusting rollers. A deviation detecting member that is rotatably supported independently of the deviation adjusting roller at the shaft end of the shaft, and a donation that moves the flat belt toward the position of the deviation detecting member. When the flat belt is in contact with the deviation detecting member and the flat belt is in contact with the deviation detecting member and a rotational torque acts on the deviation detecting member, the rotational movement is caused by the shaft end portion of the deviation adjusting roller. Roller end displacing means for converting the flat belt into a movement displacing in a predetermined direction and moving the flat belt in a direction opposite to the moving direction by the offset imparting means. The flat belt is made of an elastic material.

[0014]

In the present invention having the above-mentioned structure, the following effects can be obtained. In the invention according to claim 1, when the initial deviation occurs in the flat belt, the deviation adjusting member applies a pressing force to the end edge portion of the flat belt on the side of the initial deviation direction, and only the end edge portion. By increasing the belt tension, the flat belt is biased in the direction opposite to the initial bias direction. Therefore, the deviation correction operation can be performed without using a mechanism for displacing the shaft end portion of the roller, and the belt driving device can be made smaller and lighter.
Therefore, it is particularly effective when applied to a two-axis belt drive device.

According to the second aspect of the present invention, the flat belt is biased toward the position where the deviation detection member is disposed by the action of the offset imparting means. That is, the flat belt is eccentrically moved toward the position where the deviation detecting member is arranged as the flat belt is traveling. Due to this deviation, when the flat belt comes into contact with the deviation detecting member, the deviation detecting member rotates due to contact friction with the flat belt. Then, with the rotation of this deviation detecting member, the deviation adjusting member
By applying a pressing force to the edge portion of the flat belt on the side where the deviation detecting member is disposed, and increasing the belt tension only at the edge portion, the flat belt is moved by the bias applying means. By moving in the direction opposite to the moving direction, the initial deviation is corrected. That is, the displacement amount of the shaft end portion of the deviation adjusting roller according to the initial fluctuation is automatically given to correct the deviation of the flat belt. Therefore, the flat belt can travel stably, and particularly when the belt driving device is applied to an electrophotographic device, accurate image formation can be performed. As described above, even in the present invention, it is possible to reduce the size and weight of the belt driving device as a whole.

According to the third aspect of the present invention, since the flat belt is formed of the elastic body, the flat belt is formed by the displacement of the shaft end portion of the deviation adjusting roller during the deviation correcting operation of the flat belt. Because of the extension, this extension generates an urging force in a direction opposite to the displacement direction of the shaft end portion of the deviation adjusting roller. Accordingly, the displacement amount of the shaft end portion of the deviation adjusting roller can be adjusted with a simple configuration.

[0017]

【Example】

(First Embodiment) A first embodiment according to the present invention will be described below in detail with reference to the drawings. FIG. 1 is a plan view of a biaxial belt driving device housed in an electrophotographic apparatus according to the present invention, and FIG. 2 is a side view thereof. In FIG. 1 and FIG. 2 showing the whole of the driving device of the transfer belt of this two-axis system, 1 and 2 are the first and second rollers, respectively.
It is LA. The rollers 1 and 2 have shaft members 1a and 2a, respectively.
And a portion excluding both left and right end portions of the shaft members 1a and 2a,
It is composed of shaft members 1a and 2a and cylindrical members 1b and 2b that are concentrically formed with a slightly larger diameter and are made of rubber or the like. As a material for the cylindrical bodies 1b and 2b, for example, EPDM cross-linked rubber is adopted. However, each of the tubular bodies 1b and 2b
May not be an elastic material such as resin or aluminum.

A transfer belt 3 as a flat belt according to the present invention, in which a dielectric layer is formed on the surface of a base material, is movably wound around each of the rollers 1 and 2. Therefore,
In the belt driving device, the transfer belt 3 functions as a transfer carrier of the electrophotographic device. Also,
As the base material of the transfer belt 3, for example, biaxially stretched polyester is adopted, and the tensile elastic modulus is 200 kg / mm.
It is set to ² or more.

In the first roller 1, the shaft member 1a is connected to the drive shaft of the drive motor 4 so that the drive force of the drive motor 4 can be transmitted. That is, this first roller 1 functions as a drive roller.

The second roller 2 is an eccentricity adjusting roller according to the present invention, and the axis thereof has an axial distance from the axis of the first roller 1 from the left side in FIG. The right side is also set to be slightly shorter. That is, the second roller 2 is arranged to be inclined with respect to the first roller 1 with a slight inclination angle. Therefore, when the transfer belt 3 travels in the direction of arrow A in FIG. 1 in this state, deviation in the direction of arrow B in FIG. 1 occurs, which causes the deviation imparting means in the present invention. Is configured. Further, the second roller 2 is provided with a biasing force in a direction away from the first roller 1 by a spring (not shown), whereby the tension of the transfer belt 3 is adjusted. ..

The shaft ends of the first and second rollers 1 and 2 are rotatably supported by bearing members (not shown). A deviation detecting member 5 is arranged at the right shaft end of the second roller 2 in FIG. The deviation detecting member 5 is formed of urethane elastomer or the like having a high friction coefficient with the belt material of the transfer belt 4 and excellent in wear resistance, and at the same time, the second roller is used.
It is supported by the shaft member 2a coaxially with the roller 2 and rotatable independently of the second roller 2. The inner edge surface of the deviation detecting member 5 is the second
It is arranged close to the end surface of the cylindrical body 2b of the roller 2 with a small gap. Further, the deviation detecting member 5 has an outer diameter of a portion facing the end surface of the cylindrical body 2b of the second roller 2 having a second diameter.
It has a riding surface 5a which is set to the same diameter as the outer diameter of the la 2 and which is inclined in a taper shape such that its diameter gradually increases with increasing distance from the end surface of the tubular body 2b. As a result, when the transfer belt 3 is deviated in the B direction, the deviation causes the transfer belt 3 to ride on the riding surface 5a of the deviation detecting member 5. Further, at the position outside the riding surface 5a of the deviation detecting member 5, the second
The cylindrical portion 5 formed to have a diameter slightly smaller than the outer diameter of the roller 2.
b is integrally formed.

As a characteristic member of this embodiment, the deviation adjusting member 6 is provided between the first roller 1 and the second roller 2.
Are arranged. The deviation adjusting member 6 is made of a plate material formed in a substantially arcuate shape in a side view so as to be convex toward the upper side, and the disposition position thereof is the first roller 1 described above.
Further, it is set at an intermediate position between the positions where the second roller 2 is provided and a position facing the back surface of the transfer belt 3 with a small gap. Further, the deviation adjusting member 6
Is a member having a self-lubricating property so that the friction coefficient when contacting the transfer belt 3 becomes small.

A string member 7 is stretched between the deviation adjusting member 6 and the cylindrical portion 5b of the deviation detecting member 5. Specifically, one end of the string member 7 is connected to the outer peripheral surface of the cylindrical portion 5b so that the string member 7 can be wound around the cylindrical portion 5b as the deviation detecting member 5 rotates. On the other hand, the other end of the cord member 6 has three rollers R1.
Is connected to the upper surface of the deviation adjusting member 7 through R3.

That is, the transfer belt 3 generated by the offset applying means formed by the arrangement state of the second roller 2
When the transfer belt 3 rides on the riding surface 5a of the deviation detecting member 5 due to the deviation, and the rotational torque acts on the deviation detecting member 5, the cord member 7 is displaced due to the rotation of the deviation detecting member 5. The deviation adjusting member 6 is wound around the cylindrical portion 5b of the detecting member 5 and moves upward with the winding operation of the string member 7. By the upward movement of the deviation adjusting member 6, the upper surface of the deviation adjusting member 6 is pressed against the back surface of the transfer belt 3 to apply an urging force to the transfer belt 3, and the transfer belt 3 shown in FIG. The belt tension is increased only at the right end edge portion of. At this time, since the transfer belt 3 is biased from the side having a large belt tension to the side having a small belt tension, the transfer belt 3 is configured to generate a bias component in a direction opposite to the direction B in the drawing. Has been done. As a result, when the transfer belt 3 is deviated, a deviation correction means for generating a deviation component in the opposite direction is configured.

Further, as shown in FIG. 2, a tension spring 8 for applying a downward biasing force to the deviation adjusting member 6 is connected to the back surface of the deviation adjusting member 6, and this spring 8
Is always urged in the direction opposite to the moving direction of the deviation adjusting member 6 due to the winding operation of the string member 7, so that the deviation detecting member 5 of the transfer belt 3 can be moved on the riding surface 5a. When it is eliminated, the contact state between the deviation adjusting member 6 and the transfer belt 3 is released by the spring 8 so that the belt tension is returned to normal (equal to left and right). With such a configuration, when the deviation component in the reverse direction due to the change of the belt tension becomes larger than the initial deviation component generated by the operation of the deviation imparting means, the transfer belt 3 starts the deviation in the reverse direction and detects the deviation. Since the riding amount of the member 5 on the riding surface 5a is reduced, the rotation torque of the deviation detecting member 5 is also reduced, and as a result, the change amount of the belt tension is reduced by the spring 8.

The operation of the above configuration will be described below. First, when the transfer belt 4 is running, as described above, since the second roller 2 is inclined with respect to the first roller 1, the transfer belt 3 always deviates in the B direction in FIG. A force acts on the transfer belt 3, which causes the transfer belt 3 to move toward the deviation detecting member 5 while traveling. Then, due to the deviation of the transfer belt 3, the edge portion of the transfer belt 3 rides on the riding surface 5 a of the deviation detecting member 5.
When the vehicle moves on, the frictional force acting between the transfer belt 3 and the riding surface 5a of the deviation detecting member 5 causes the deviation detecting member 5 to rotate with respect to the shaft member 2a, and the rotation causes the string member 7 to rotate. It is wound around the cylindrical portion 5b.

The winding of the cord member 7 causes the deviation adjusting member 6 to move upward as shown in FIG. 3, and with this movement, the upper surface of the deviation adjusting member 6 becomes the back surface of the transfer belt 3. The transfer belt 3 is pressed and biased. That is, the belt tension of only the right edge portion of the transfer belt 3 in FIG. 1 is increased. Then, since the transfer belt 3 is biased from the side having a large belt tension to the side having a small belt tension, a bias component in the direction opposite to the direction B in the drawing is generated in the transfer belt 3 to cause the transfer belt 3 to move. Is restricted in the B direction. At the same time, the movement of the deviation adjusting member 6 causes the spring 8 to expand and also exert a spring force. Therefore, the deviation adjusting member 6 is balanced by the balance between the winding force of the string member 7 and the spring force of the spring 8.
Is determined, and the pressing force applied to the one edge of the transfer belt is set at that position.

Since the transfer belt 3 travels in this way, a large deviation of the transfer belt 3 can be prevented, and the deviation amount of the transfer belt 3 can be suppressed to, for example, ten and several μm. That is, while the transfer belt 3 is preliminarily biased in one direction, the deviation is automatically and sequentially corrected, so that the deviation amount can be made small and the transfer belt 3 can be stably run. Therefore, in the electrophotographic apparatus of this example, accurate image formation can be performed.

As described above, in this embodiment, the transfer belt 3
When the deviation occurs in the transfer belt 3, the initial deviation of the transfer belt 3 can be corrected by increasing only the belt tension on one side of the transfer belt 3, so that it is not necessary to move the rollers 1 and 2. Since the setting position of each roller is easy and the flatness of the transfer belt 3 can be secured,
In particular, when it is adopted in an electrophotographic apparatus, it is effective because it can form an accurate image.

In this embodiment, the back surface of the transfer belt 3 is pressed by the deviation adjusting member 6 to increase the belt tension on one side, but the present invention is not limited to this, and the deviation adjusting member is not limited to this. The belt tension on one side may be increased by pressing 6 onto the surface of the transfer belt 3.

(Second Embodiment) Next, a second embodiment according to the invention of claim 3 will be described. This example is a modified example for improving the practicality of the two-axis belt drive device, and only differences from the above-described first example will be described. As shown in FIG. 4, in the belt drive device of this example, the transfer belt 3 wound around each roller is a rubber belt. Then, one end of the string member 7 whose one end is connected to the cylindrical portion 5b of the deviation detecting member 5 is connected to the other fixing member S such as a frame member of this belt drive device. When the transfer belt 3 is deviated in the direction of the arrow B in FIG. Motion detection member 5
The deviation detecting member 5 is caused to rotate with respect to the shaft member 2a by the frictional force acting on the riding surface 5a of the above, and the cord member 7 is wound around the cylindrical portion 5b by the rotation.

By winding the cord member 7, the shaft end of the second roller 2 on which the deviation detecting member 5 is arranged is displaced in the direction of arrow C, and the displacement causes the transfer belt 3 to move in the direction of B. Since the vehicle runs while being wound in the opposite direction, the deviation of the transfer belt 3 in the B direction is limited. At the same time, since the elastic force of the transfer belt 3 also acts due to the displacement of the shaft end portion, the displacement of the third roller 3 is caused by the balance between the winding force of the string member 7 and the elastic force of the transfer belt 3. The amount is regulated, and the position of the end portion of the transfer belt 4 is maintained at a certain fixed position.

Since the transfer belt 3 travels in this way, a large deviation of the transfer belt 3 can be prevented, and the deviation amount of the transfer belt 3 can be suppressed to, for example, ten and several μm. That is, while the transfer belt 3 is preliminarily biased in one direction, the deviation is automatically and sequentially corrected, so that the deviation amount can be made small and the transfer belt 3 can be stably run. Therefore, in the electrophotographic apparatus of this example, accurate image formation can be performed. In this way, in this embodiment, by adopting the rubber transfer belt 3, it is possible to obtain a mechanism for adjusting the displacement amount of the shaft end portion of the second roller 2 with a simple configuration.

In each of the above-mentioned examples, the driving device for the transfer belt 4 of the electrophotographic apparatus has been described.
The invention is not limited to this, and can be similarly applied to a photosensitive belt driving device or a normal flat belt driving device. In the configuration of this example, the deviation detection member 5 arranged coaxially with the third roller 3 detects the deviation of the transfer belt 3. However, the invention according to claim 1 is not limited to this. Instead of an object, the deviation of the transfer belt 4 may be detected by an infrared sensor or the like.

[0035]

As described above, according to the present invention,
The following effects are exhibited. According to the invention described in claim 1, when the initial deviation occurs in the flat belt, a pressing force is applied to the end edge portion of the flat belt on the side of the initial deviation direction to increase the belt tension only at the end edge portion. By providing the deviation adjusting member for causing the flat belt to deviate in a direction opposite to the initial deviation direction,
Since the deviation correction operation can be performed without using a mechanism for displacing the shaft end portion of the roller, it is possible to reduce the size and weight of the belt drive device. The practicality of the incorporated electrophotographic apparatus is greatly improved.

According to the invention described in claim 2, as in the invention described in claim 1, the deviation adjusting member and the deviation detecting member in the flat belt are arranged in accordance with the rotation of the deviation detecting member. The flat belt is moved in the direction opposite to the moving direction by the bias applying means by applying a pressing force to the end edge on the installed side and increasing the belt tension only at the end edge, Since the initial deviation is corrected, it is possible to perform the deviation correction operation with a simple configuration.
It is possible to reduce the size and weight of the belt driving device as a whole.

According to the third aspect of the present invention, the flat belt is formed of an elastic body, and when the flat belt is stretched during the deviation correction operation, the displacement direction of the shaft end portion of the deviation adjusting roller is changed. Since the urging force is generated in the opposite direction, the displacement amount of the shaft end portion of the deviation adjusting roller can be adjusted with a simple configuration.

[Brief description of drawings]

FIG. 1 is a plan view of a belt driving device according to a first embodiment.

FIG. 2 is a side view of a belt driving device.

FIG. 3 is a diagram corresponding to FIG. 2 for explaining the deviation correcting operation.

FIG. 4 is a view corresponding to FIG. 1 in the second embodiment.

[Explanation of symbols]

 1 First Roller 2 Second Roller 3 Transfer Belt (Flat Belt) 5 Deviation Detection Member 6 Deviation Adjustment Member

Claims (3)

[Claims] 1. A flat belt, and a plurality of rollers around which the flat belt is stretched. The flat belt is caused to undergo an initial deviation, and the flat belt is defined as the initial deviation direction. In a belt drive device that is biased in the opposite direction to sequentially correct the initial deviation, when an initial deviation occurs in the flat belt, the flat belt is pushed to an edge portion on the initial deviation direction side. A belt drive characterized by comprising a deviation adjusting member for causing the flat belt to deviate in a direction opposite to the initial deviation direction by applying a pressure and increasing a belt tension only at the end portion. apparatus. 2. A flat belt, a plurality of rollers around which the flat belt is stretched, at least one of which is configured as a deviation adjusting roller, and one of the deviation adjusting rollers. A deviation detecting member that is rotatably supported independently of the deviation adjusting roller at an end of the shaft, and a single donation that moves the flat belt toward a position where the deviation detecting member is disposed. Applying means and the deviation detecting member, and when the flat belt comes into contact with the deviation detecting member and a rotational torque acts on the deviation detecting member, the rotational movement is utilized to move the flat belt to the bias applying means. A deviation correction means for moving the deviation detection means in the flat belt in accordance with the rotational movement of the deviation detection member. The pressing force to the edge on the side where the tension is applied to increase the belt tension only at the edge. Therefore, the flat belt belt drive, characterized in that it comprises a Hendo adjusting member is moved in a direction opposite to the movement direction of the Katayose applying means. 3. A flat belt, a plurality of rollers around which the flat belt is stretched, at least one of which is configured as a deviation adjusting roller, and one of the deviation adjusting rollers. A deviation detecting member that is rotatably supported independently of the deviation adjusting roller at an end of the shaft, and a single donation that moves the flat belt toward a position where the deviation detecting member is disposed. When the rotating belt is connected to the applying means and the deviation detecting member, and the flat belt is in contact with the deviation detecting member and a rotational torque is applied, the rotational movement is caused by the shaft end portion of the deviation adjusting roller. The flat belt is formed of an elastic body, and includes a roller end displacing means for converting the flat belt into a movement displacing in a predetermined direction and moving the flat belt in a direction opposite to a moving direction by the offset imparting means. A belt drive device characterized in that