JP2000112306A - Image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make eliminable noise without providing a structural body outside by providing a resonator which eliminates noises produced by an image forming unit by a hermetically sealed space formed between component members. SOLUTION: The various parts or the units such as the light source 1a3 of the optical unit 1a or the paper supply unit 1b, etc., of the image forming unit 1 are supported by a structural body 2. The resonator 3 is one or plural hermetically sealed spaces formed between the inside plate member 2a1 and the outside plate member 2a2 of the plate member 2a of the structural body 2 such as a base member, a side wall member and a diagonal brace and eliminates the produced sound produced by the unit 1. An aperture part 4 forms a path between the inside of the resonator 3 and the inside of the structural body 2. Thus, the frequency of a noise desired to be eliminated can be eliminated without troublesomeness in attachment/detachment and without spoiling the rigidity of the structural body 2 in the device which is miniaturized and so as not to require extra space.

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 having a function of silencing noise and abnormal noise generated by an image forming operation of a copying machine, a facsimile machine, a printer, or a multifunction peripheral thereof. The present invention relates to a forming apparatus.

[0002]

2. Description of the Related Art In order to reduce noise generated from an image forming apparatus or the like, a sound-insulating material and a sound-absorbing material are combined to shield an underfloor portion of an apparatus housing. A technique for reducing noise is known (see Japanese Patent Application Laid-Open No. 4-315161). However, in this conventional example, it is necessary to attach the members of the sound insulating material and the sound absorbing material under the floor each time the equipment is installed, or to remove the members from under the floor when moving, so that troublesome work is required. The problem of saying that had occurred. As a noise absorbing device of a copying machine, a resonance box whose volume can be changed by a movable mechanism according to a change in frequency, a device for analyzing the frequency of noise, and control for changing the wall of the resonance box in accordance with the frequency It is also known to dispose a noise absorbing device, which comprises a device and absorbs noise by changing the wall of a resonance box in accordance with the resonance frequency in accordance with the noise frequency, on the outer plate of the main body of the copying machine (Japanese Patent Laid-Open No. 6-208385). Reference). However, in such a conventional example, since the noise absorbing device is newly disposed on the exterior plate, there is a problem that the entire copying machine becomes large and the cost increases. Further, the frequency of the noise generated from the image forming apparatus is, for example, a frequency of a plurality of noises by one or a plurality of drive motors, a frequency of each noise during operation and a standby time, and a frequency having a high noise level is one. In spite of not being limited, such a noise absorbing device has a problem that the frequency can be variously changed, but only a single frequency can be silenced. Assemble a base member and a plurality of channel-shaped skeleton members, fix them by welding to form a lower skeleton, and assemble a plurality of skeleton members and fix them by welding to form an upper skeleton, A structure of an image forming apparatus having a high rigidity and a low cost by positioning and connecting a skeleton body and a lower skeleton body with pins is also known (see Japanese Patent Application Laid-Open No. 6-175419). However, such a structure of the image forming apparatus has a high rigidity and a low cost, but has a problem that the noise reduction is not performed. Therefore, such a conventional image forming apparatus includes:
Since the noise silencer is provided outside the structure, it is not only troublesome to mount and remove, but also requires a large and extra space, and furthermore, the frequency of the noise to be silenced cannot be silenced and remains. Had occurred.

[0003]

In the above-described conventional image forming apparatus, since a device for silencing noise is provided outside the structure, not only is the mounting and dismounting troublesome, but also a large and extra space is required. Furthermore, there is a problem that the frequency of the noise to be silenced remains without being silenced. Therefore, an object of the present invention is to solve such a problem. That is, there is no need to provide a device for noise reduction outside the structure, no hassle of mounting and dismounting, no need for small and extra space without losing the rigidity of the structure, and it is possible to mitigate the frequency of the noise to be muffled. An object of the present invention is to provide an image forming apparatus.

[0004]

According to one aspect of the present invention, there is provided an image forming apparatus for forming an image by silencing a sound generated by an image forming unit. An image forming unit that is driven by a driving source of the image forming apparatus, forms an image, a structure that supports the image forming unit, and an enclosed space formed between constituent members that constitute the structure in the structure. The most main feature of the image forming apparatus is an image forming apparatus including a resonator that silences a sound generated by the unit and an opening that forms a passage between the resonator and the structure. According to a second aspect of the present invention, in the image forming apparatus of the first aspect, the main feature is that the resonator is an image forming apparatus formed in a plate member of the structure.
According to a third aspect of the present invention, in the image forming apparatus according to the first or second aspect, the resonator is an image forming apparatus formed between an inner plate member and an outer plate member of a plate member of the structure. Is the main feature. Claim 4 of the present invention provides Claim 1,
4. The image forming apparatus according to item 2 or 3, characterized in that the resonator is an image forming apparatus having a plurality of resonators.
According to a fifth aspect of the present invention, in the image forming apparatus of the first, second, third, or fourth aspect, the opening is an image forming apparatus in which an opening cross-sectional area is made variable by an opening cross-sectional area changing means. Characteristics. The present invention of claim 6 is the invention of claim 5
In the image forming apparatus described in the above, the opening cross-sectional area variable means,
The main feature of the present invention is that the image forming apparatus is configured to change the cross-sectional area of the opening in accordance with an image forming mode in which an image is formed in the image forming unit and mute the sound. The invention of claim 7 is
A main feature of the image forming apparatus according to the fifth aspect is that the opening cross-sectional area varying means is an image forming apparatus that varies a cross-sectional area according to a frequency component and a level of a sound generated in a structure to muffle sound. According to an eighth aspect of the present invention, in the image forming apparatus according to the fifth or seventh aspect, the opening cross-sectional area changing means changes the opening cross-sectional area in accordance with the order of higher frequency of sound generated in the structure. The main feature is that there is an image forming apparatus for silencing.

[0005]

According to the first aspect of the present invention, there is provided an image forming apparatus which is generated by an image forming unit by a closed space formed between constituent members constituting a structure in a structure for supporting the image forming unit. By forming a passage with an opening between the inside of the resonator and the inside of the structure that silences the generated sound, there is no need to provide a device for silencing the noise outside the structure, without the hassle of mounting and dismounting, It is possible to provide an image forming apparatus in which a small and unnecessary space is not required without deteriorating the rigidity of the body and the frequency of noise to be silenced can be silenced. According to the second aspect, a passage is provided between an inside of the resonator and an inside of the structure, in which the sound generated by the image forming unit is silenced by a closed space formed in a plate member in the structure supporting the image forming unit. As a result, the device for suppressing noise is not provided outside the structure, there is no need for installation and removal, and there is no need for a small and unnecessary space without impairing the rigidity of the plate member of the structure, An image forming apparatus capable of silencing the frequency of noise to be silenced can be provided. According to the third aspect, the inside of the resonator that silences the sound generated by the image forming unit by the closed space formed between the inner plate member and the outer plate member of the plate member in the structure that supports the image forming unit; By forming a passage between the structure and the opening with an opening,
The noise reduction device is not provided outside the structure, so there is no need to install and remove it.There is no need for small and extra space without compromising the rigidity of the inner and outer plate members of the plate member of the structure. In addition, it is possible to provide an image forming apparatus capable of silencing the frequency of noise to be silenced. According to a fourth aspect of the present invention, the inside of the plurality of resonators and the structure inside the plurality of resonators for silencing the sound generated by the image forming unit by the closed space formed between the constituent members constituting the structure inside the structure supporting the image forming unit A noise reduction device is provided outside the structure by forming a passage between the opening and the opening, so that there is no hassle of installation and removal, and there is no need for a small and unnecessary space without impairing the rigidity of the structure. It is possible to provide an image forming apparatus which can eliminate noise without leaving a plurality of frequencies of noise to be eliminated. In claim 5,
A passage is provided between the inside of the resonator and the resonator, which silences the sound generated by the image forming unit by the closed space formed between the constituent members of the structure inside the structure supporting the image forming unit, and an opening. Forming and varying the opening cross-sectional area of the opening by means of the opening cross-sectional area variable means, the device for noise reduction is not provided outside the structure, there is no need for installation and removal, and the rigidity of the structure is reduced. It is possible to provide an image forming apparatus capable of automatically canceling a frequency at which noise to be silenced changes without requiring a small and unnecessary space without spoiling. According to the sixth aspect, between the resonator and the structure, which mute the sound generated by the image forming unit by the closed space formed between the constituent members of the structure inside the structure supporting the image forming unit. By forming a passage in the opening and making the opening cross-sectional area of the opening variable by the image forming mode by means of the opening cross-sectional area changing means, the noise canceling device can be attached and detached without being provided outside the structure. It is possible to provide an image forming apparatus which is small in size, does not require an extra space, does not impair the rigidity of the structure, does not need to be troublesome, and can automatically mute the frequency at which the noise to be silenced most changes. According to the seventh aspect, between the resonator and the structure, which mute the sound generated by the image forming unit by the closed space formed between the constituent members constituting the structure inside the structure supporting the image forming unit. A device for suppressing noise by forming a passage in the opening and making the opening cross-sectional area of the opening variable by the opening cross-sectional area varying means according to the frequency component and level of the sound generated in the structure. An image that can automatically mute the changing component and level frequency of the noise you want to muffle, without the need for installation and removal without the need for installation and removal, without compromising the rigidity of the structure, eliminating the need for a small and unnecessary space A forming device can be provided. According to claim 8, between the resonator and the structure which muffle the sound generated by the image forming unit by the closed space formed between the constituent members constituting the structure inside the structure supporting the image forming unit. A device that suppresses noise by forming a passage in the opening and varying the opening cross-sectional area of the opening by the opening cross-sectional area varying means in descending order of the level of the frequency of the sound generated in the structure. An image that can be automatically and effectively silenced at the changing frequency of the noise that you want to silence without the need for installation outside the body, without the hassle of installation and removal, without the need for extra space, without compromising the rigidity of the structure A forming device can be provided.

[0006]

Next, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is an explanatory diagram of the internal structure of a copying machine using an electrophotographic method, which is an example of an image forming apparatus. This copying machine is generally called a console type and has a total height so that it can be used by being placed on a floor. It is set high, and is entirely composed of an upper part 6 and a lower part 7. The upper part 6 has an optical unit 1a of the image forming unit 1 composed of optical elements, and each unit of an image forming system located therebelow. The lower part 7 has a plurality of sizes of transfer paper (P). An automatic document feeder 1c of the image forming unit 1 is mounted above the upper part 6 of the image forming unit 1 having the paper feeding unit 1b of the image forming unit 1 in which a plurality of mounted paper feed cassettes are stored. . The automatic document feeder 1c document placed on the document table 1c ₁ of (O)
But it has been stopped automatically feeds on the optical unit 1a contact glass 1a ₂ which is supported by the casing 1a ₁ of.
Then, the light source 1a ₃ of the optical unit 1a is moved to the right in the direction of arrow A shown, this time, the document surface of the document (O) is illuminated by the light source 1a _3, image formation of a document (O) the image optical system 1a _4, is imaged on the photosensitive drum of the image bearing member 1d of the image forming unit 1. The photosensitive drum of the image carrier 1d rotates clockwise in the direction of arrow B shown in the figure. At this time, the surface of the photosensitive drum is uniformly charged by the charging charger 1e.
Forms an original image. As a result, an electrostatic latent image is formed on the photosensitive drum of the image carrier 1d, and this latent image is visualized as a toner image by the developing unit 1f of the image forming unit 1. On the other hand, the transfer paper (P) is fed from the paper feed unit 1b disposed in the lower portion 7 toward the photosensitive drum of the image carrier 1d, and is transferred by the transfer charger 1g of the image forming unit 1 to the image carrier 1d. The toner image on the photosensitive drum is transferred to the transfer paper (P).

[0007] In order to minimize the copying time of the first sheet,
After the transfer paper (P) is separated by the paper feed unit 1b,
There is also a mode in which a transport motor (not shown) rotates at high speed and is transported at high speed to the photosensitive drum of the image carrier 1d. This transfer paper (P) is transferred to the fixing unit 1 of the image forming unit 1.
h, the transferred toner image is fixed on the transfer paper (P), and then the transfer paper (P) is discharged outside the machine as copy paper. Although the illustrated copying machine is configured to be capable of performing double-sided copying, its description is omitted here. The toner remaining on the photosensitive drum of the image carrier 1d is removed by the cleaning unit 1i of the image forming unit 1. As described above, the illustrated copying machine has various components and units of the image forming unit 1. These components are driven by a plurality of drive motors (not shown) and rotated. Further, the image forming unit 1 of the optical unit 1a the light source 1a ₃ and the paper feed unit 1b
Various parts and units such as are supported by the structure 2. The resonator 3 includes an inner plate member 2 a of a plate member 2 a such as a base member, a side wall member, and a brace (not shown) of the structure 2.
Between ₁ and the outer plate member 2a _2, a one or enclosed space in which a plurality is formed, so as to mute the generated sound generated by the image forming unit 1. Opening 4
Is configured to form a passage between the inside of the resonator 3 and the inside of the structure 2. The details of the resonator 3 will be described later.

FIG. 2 is an exploded perspective view of the structure. The structure 2 has an upper skeleton 2b and a lower skeleton 2c.
The upper skeleton 2b is used to support the above-mentioned upper portion 6 (not shown), and includes the optical unit 1a and the image carrier 1d.
Support the developing unit 1f, the fixing unit 1h, the cleaning unit 1i, and the like. The lower skeleton 2c is used to support the lower portion 7 of the copying machine, and supports the paper feed unit 1b and the like. First, the lower skeletal body 2c includes the plate member 2a of the base member located at the bottom thereof, and skeleton members 2d ₁ , 2d ₂ , and 2d _{3 of} a plurality of skeleton members 2d formed in a channel shape. Frame member 2d ₄ , frame member 2d ₅ , frame member 2d ₆ ,
Frame members 2d _7, frame members 2d _8, frame members 2d
₉ and assembled together by welding. The inner plate member 2a ₁ and the outer plate member 2a ₂ which have been subjected to the drawing process
Assembling the door with each other, they consist those integrally fixed by welding, to the corner of the four corners of the inner plate member 2a _1, 4 pieces of frame members 2d stood vertically as shown
_1, frame members 2d _2, frame members 2d _3, the lower portion of the frame members 2d ₄ is fixed by welding. The plate member 2a has a forming by drawing, by the upper and lower inner plate member 2a ₁ of the component and the outer plate member 2a ₂ with a welded those in lunch box-like configuration, has become a high rigidity .

The direction indicated by arrow C in the figure is the front side of the copying machine, that is, the side facing the normal operator, and the side indicated by arrow D in the figure is the back side. When the operator faces the copying machine, the direction of the left / right direction is indicated by an arrow E in the figure. Of the four framing members 2d ₁ , 2d ₂ , framing member 2d ₃ , and framing member 2d ₄ fixed to the plate member 2a, two framing members 2d ₁ on the near side and upper portions of the framing members 2d ₃ And the back 2
At the top of the scaffold member 2d ₂ and frame members 2d _4,
Frame members 2d ₅ and frame members 2d ₆ extending in the lateral direction respectively is fixed by welding, also the frame members 2d ₂ one of one frame members 2d ₁ and the back side of the front side frame members extending in a longitudinal each end of the 2d ₇ is fixed by welding. Similarly, the front and rear frame members 2d ₅ and frame member 2d _6, each end of the two frame members 2d ₈ and frame member 2d ₉ extending in the front-rear are fixed by welding. At the time of actual production, four frame members 2d ₅ , 2d
₆ , 2d ₈ , 2d ₉ are assembled and joined together as shown in the figure to form four vertical frame members 2d ₁ , 2d ₂ ,
The work efficiency is good if it is fixed to the upper part of 2d ₃ or 2d ₄ .

[0010] On the other hand, the upper skeleton 2b also four substantially horizontal frame members 2d ₁₀ of the assembly frame members 2d _11, frame members 2d _12, the frame members 2d ₁₃ rectangular, reinforced as necessary to Attach the frame member 2d ₁₄ for
A lower structure part fixed to each other by welding, and four skeleton members 2d ₁₅ , 2d ₁₆ , 2d ₁₇ , and 2d _18, which are fixed to this structure part by welding and stand vertically. , the back side of the frame members 2d _17, the frame members 2d ₁₉ secured by welding to the top of the frame member 2d _18, frame members 2d ₁₅ on the front side, the frame members 2d ₂₀ welded to the frame members 2d ₁₆ top,
Front and rear frame members 2d _15, frame members 2d ₁₇ and frame members 2d _16, frame members 2d ₂₁ integrated by welding to the frame members 2d _18, and a framing member 2d _22. The frame member 2d of the structure 2 is joined by at least one of a spot welding method and a plug welding method, and a spot where a welding electrode enters is spot-welded. It is only necessary to make a long hole and perform plug welding. Also, the lower skeleton 2
The upper left and right inner side of the frame members 2d ₆ of c, at least two pins 2e projecting upward is fixed, the frame members 2d ₁₀ of the pin 2e is the upper skeleton member 2b, the back side of the frame members 2d ₁₂ Is fitted into the mounting hole 2f drilled at the position. As described above, the upper skeleton 2b and the lower skeleton 2c are connected to each other via the pins 2e and positioned. At this time, one of the pair of mounting holes 2f may be an elongated hole. Generally, the structure 2
The exterior member 8 is attached to the housing 2 to improve the appearance, enhance safety for users, prevent dust from entering the structure 2, and prevent noise from leaking.

FIG. 3 is an exploded perspective view of a plate member provided with the resonator according to the present invention. The plate member 2a is replaced with an inner plate member 2a _1.
And it shows the disassembled state to the outer plate member 2a _2, in this state, is integrally fixed by welding. Inner plate member 2a ₁ and the outer plate member 2a ₂ of the upper and lower, peripheral flange drawing and overhang drawing has been subjected to squeezing against processing, it is molded into the shape as shown from a single sheet metal, respectively. The plate member 2a, which is configured by the inner plate member 2a ₁ and the outer plate member 2a _2, the inner plate member 2a
₁ and the outer plate member 2a ₂ can also be fixed by at least one of spot welding and plug welding.
Therefore, it can be manufactured simply and at low cost without using a large-scale welding facility. The plate member 2a is integrally fastened to the box-shaped welding points of X marks shown inner plate member 2a ₁ and the outer plate member 2a ₂ by the spot welding and the plug weld. Combined top G of the lower surface F and the outer plate member 2a ₂ of the inner plate member 2a _1, spot welding. Since the lower surface F and the upper surface G of the outer plate member 2a ₂ of the inner plate member 2a ₁ is the strength that only planar fall, the inner plate member 2a ₁ and the outer plate member 2a ₂ portions 2a ₃ against stop in a symmetric shape, the diaphragm contrary providing a portion 2a _4. In this embodiment the diaphragm against the portion 2a _3, are provided at four positions of the portions 2a ₄ against the diaphragm above. As a result, when assembled as the plate member 2a, four resonators 3 having a volume V1 for silencing the sound generated by the image forming unit 1 are formed in a sealed space. The opening 4 is provided only on the inner plate member 2a _1, is provided for each resonator 3 is a Helmholtz resonator.

[0012] Figure 4 is a sectional view of an example of a resonator, the resonator 3, the cavity volume V1, the length which is the thickness of the inner plate member 2a ₁ (Tb), the cross-sectional area of the (Sb) The opening 4 forming the passage of the short pipe is constituted by being connected, and the opening 4 is connected to the inside of the structure 2 as shown. That is, the upper and lower aperture stop portions 2a ₃ ,
Cavity formed between the portions 2a ₄ against the diaphragm above the opening 4 is formed in a portion 2a ₃ against diaphragm upper. The cross-sectional area (Sb) of the opening 4 is represented by a fixed value (a) of the length of one piece and a change value (X) of the length of the other piece.
b = a * X (FIG. 5). Now, assuming that sound pressure acts on the entrance of the opening 4 from the inside of the structure 2, the air in the medium in the opening 4 moves integrally, and a pressure fluctuation occurs in the medium in the cavity 3 in the cavity. . Such a phenomenon is caused by the opening 4
Assuming that the medium inside is a mass point and the pressure change due to the volume change of air in the cavity resonator 3 is a spring, the mass point of the dynamic system −
It is equivalent to a spring model, and resonance (resonance) occurs at a certain frequency (hereinafter referred to as Helmholtz resonance frequency). At this Helmholtz resonance frequency, the acoustic energy inside the cavity 3 inside the cavity is confined, and the inside of the structure 2 in the external space is silenced. Therefore, the frequency inside the structure 2 is confined in the resonator 3 and does not leak outside the structure 2. in this case,
The Helmholtz resonance frequency _Fh is expressed by equation (1). F _h (Hz) = C / 2π (Sb / V1 · Tb) ^1/2 (1) C: Sound velocity (340000 mm / s) Sb: Opening cross-sectional area of opening 4 (mm ² ) Tb: Opening Length of portion 4 (mm) V1: Volume of cavity 3 of resonator 3 (mm ³ ) From equation (1), opening sectional area (Sb), length (Tb) of opening 4 and volume V1 of resonator 3 Can be changed to change the Helmholtz resonance frequency.
In the present embodiment, the opening cross-sectional area (Sb) of the opening 4 changes the Helmholtz resonance frequency by changing the adjusting plate 5a of the opening cross-sectional area varying means 5 in the direction of the arrow H shown in the drawing. .

FIG. 5 is a perspective view showing a specific configuration example of the opening cross-sectional area changing means 5, which is a mechanism for changing the cross-sectional area (Sb) of the opening 4 and is attached to the plate member 2a. Fixed. The adjusting plate 5 of the opening cross section variable means 5
It is arranged so as to slidably fit on the adjusting plate tip 5a ₁ exactly opening 4 of a. Adjustment plate 5
The cross-sectional area (Sb) of the opening 4 changes due to the movement of “a” in the direction of arrow I shown in the figure. The adjusting plate 5a has a long hole 5b.
Is fixed to the adjustment plate holding bracket 5d with two stepped screws 5c. The combination of the stepped screw 5c and the elongated hole 5b allows free movement in the direction of arrow I in the drawing. The drive for moving the adjustment plate 5a is fixed to the adjustment plate holding bracket 5d, and the screw gear 5 is driven by the adjustment plate motor 5e, which is rotationally controlled by the control means 10.
f, transmitted by an idle gear 5h arranged on the shaft 5g and a precision rack 5i carved on the adjusting plate 5a. The adjustment plate 5a is provided with a projection 5j. When the projection 5j enters one of the front sensor 5k and the rear sensor 51 (both are photo interrupters), the drive of the adjustment plate 5a is stopped. Controlled. That is, the movable range of the adjustment plate 5a is between the front sensor 5k and the rear sensor 51.

FIG. 6 is a block diagram showing an example of a control system centering on the control means. The control means 10 includes a CPU (not shown) and an image forming mode in which an image is formed by the image forming unit 1 (not shown). ROM, which is a program memory for controlling the size of the cross-sectional area of the opening 4 in accordance with a signal corresponding to the above, RAM which is a data memory for storing processing data, an input / output circuit (I / O), A driver for driving the adjusting plate 5a is used. When the front sensor 5k detects the adjustment plate 5a, the length (X) of the opening cross-sectional area of the opening 4 in the movable direction is set to 0.
The number of rotations of the adjusting plate motor 5e from this home position, the length (X) of the opening cross-sectional area of the opening 4 in the movable direction, and the length at that time ( The relationship between X) and the resonance frequency is stored in the ROM in advance. When the image forming mode of the image forming unit 1 is detected by the image forming mode detecting unit 5m, the control unit 10 outputs a rotation amount control signal based on the data of the ROM storing the maximum frequency level in the image forming mode. Then, the adjusting plate motor 5e is rotationally driven. The screw gear 5f rotating integrally with the adjusting plate motor 5e is moved from the idle gear 5f.
h, the adjusting plate 5a is moved along the I direction via the precision rack 5i, and the opening cross-sectional area (Sb) of the opening 4 is automatically formed to a size corresponding to the generated frequency. The length (X) in the movable direction is changed as described above. Thus, the frequency generated by the image forming unit 1 is resonated by the resonator 3 of the Helmholtz resonator and attenuated (see FIGS. 4 and 5).

FIG. 7 is a block diagram showing another example of the control system of the present invention. This embodiment is different from the example of FIG. 6 in that the cross-sectional area of each of the openings 4 provided in a plurality of resonators is different. The operation for individually increasing / decreasing is performed by one control means. That is, the control unit 10a is a program memory for individually controlling the size of the opening cross-sectional area of each opening 4 in accordance with a signal corresponding to an image forming mode in which an image is formed by the image forming unit 1 (not shown). RO
M and RAM which is a data memory for storing processing data
And an input / output circuit (I / O), a driver for driving a plurality of the adjusting plates 5a (not shown), and the like. When the adjustment plate 5a is detected by the front sensor 5k provided in each resonator, the length (X) of the opening cross-sectional area of the opening 4 in the movable direction is set to 0.
The number of rotations of the adjusting plate motor 5e from this home position, the length of the opening cross-sectional area of the opening 4 in the movable direction (X), and the length of the movable direction at that time The relationship between (X) and the resonance frequency is stored in the ROM in advance. The relationship between the size of the cross-sectional area of the opening 4 and the resonance frequency at that time is stored in the ROM in advance. These relationships are stored for the number of resonators 3 provided. When the image forming mode of the image forming unit 1 is detected by the image forming mode detecting means 5m, the RO storing the maximum frequency level in the image forming mode is stored.
Based on the data of M, the control means 10a outputs a rotation amount control signal to rotate the plurality of adjusting plate motors 5e. The driving force is transmitted from the screw gear 5f rotating integrally with the adjusting plate motor 5e to the idle gear 5h, moves the adjusting plate 5a via the precision rack 5i, and moves the opening cross-sectional area (Sb ) Is automatically changed to a size corresponding to the generated frequency, and the length (X) in the movable direction is changed. Thus, the frequencies generated by the plurality of image forming units 1 are resonated and attenuated by the resonator 3 of the Helmholtz resonator. The operation of increasing or decreasing the opening cross-sectional area is performed individually for the openings provided in the individual resonators. Image forming unit 1
During operation, the frequency with a high noise level is not limited to one. In a series machine, when the frequency of noise generated by each drive motor changes, or when the frequency Even in a different case, by setting a plurality of resonance frequencies corresponding to the set image forming mode in advance, the noise can be efficiently eliminated (see FIGS. 3, 4, and 5). In other words, a series machine may employ a configuration in which components such as a motor are made different while using the same structure. In this case, noises with different frequencies are generated between the models, but this control method is used. According to this, it is possible to mute sound corresponding to various frequencies by using one control circuit.

FIG. 8 is a block diagram showing the configuration of a control system according to another embodiment of the present invention. The control means 10b replaces the image forming mode detecting means 5m of the control means 10a.
A generated frequency detecting means 5n for detecting a frequency component and a level of a sound generated in the structure 2 is used. The generated frequency detecting means 5n for detecting the frequency component and level of the sound generated in the structure 2 includes, for example, a sensor microphone, a microphone amplifier, and a frequency analyzer.
The noise generated during operation or standby of the image forming unit 1 is captured by the sensor microphone of the generated frequency detection means 5n attached in the structure 2, and the noise level corresponding to each frequency is detected by a frequency analyzer (not shown). And sends it to the control means 10b. The noise level of each frequency is output as a voltage. The control means 10b includes a CPU having various judgment and processing functions (not shown), a program necessary for detecting frequency analysis data in order of higher frequency, and the resonator 3 according to a frequency level output result. ROM as a program memory for controlling the rotation of the adjusting plate motor 5e for changing the size of the opening cross-sectional area of the opening 4, a RAM as a data memory for storing processing data, and an input / output circuit (I / O) And a driver for driving the plurality of adjustment plates 5a. And
When the adjustment plate 5a is detected by the front sensor 5k, the length (X) of the opening cross-sectional area of the opening 4 in the movable direction is set to 0, the home position is set, and the adjustment plate motor 5e is rotated how many times from this home position. Then, the relationship between the length (X) in the movable direction of the opening cross-sectional area of the opening 4 in the movable direction and the relationship between the length (X) in the movable direction at that time and the resonance frequency are stored in the ROM in advance. This information is stored in the resonator 3
Are stored for the number provided.

When noise during operation or standby of the image forming unit 1 is detected by the sensor microphone of the generated frequency detecting means 5n mounted in the structure 2, the control means 10b outputs a rotation amount control signal. Then, the plurality of adjustment plate motors 5e are rotationally driven. The screw gear 5 rotating integrally with the adjusting plate motor 5e.
f to the idle gear 5h, moves the adjusting plate 5a via the precision rack 5i, and moves the opening 4
The length (X) in the movable direction is changed so that the opening cross-sectional area (Sb) is automatically formed to a size corresponding to the generated frequency. Thus, the frequencies generated by the plurality of image forming units 1 are resonated and attenuated by the resonator 3 of the Helmholtz resonator. In this embodiment as well, as in FIG. 7, the opening cross-sectional areas of the openings 4 provided in the individual resonators 3 can be individually changed, and different types of devices are created using the same structure. In this case, the sound can be muted according to the frequency of the generated noise. When the image forming unit 1 is operating, the frequency at which the noise level is high is not limited to one. In a series machine, the frequency at which the noise generated by each drive motor changes varies, Even if the generated frequencies are different, by setting a plurality of resonance frequencies corresponding to the frequency component and the level of the noise to be silenced during the operation or standby of the image forming unit 1, the changing component and the level of the noise to be silenced The noise can be automatically and efficiently silenced without leaving the frequency (see FIGS. 3, 4 and 5).

9 and 10, FIG. 10 shows an example of the frequency distribution when the number of rotations of the drive motor of the image forming apparatus is 1.5 times faster than that in FIG. In the case of FIG. 10, FIG.
Both the noise level and the frequency are shifted to the higher side as compared with the case of. The level was high in FIG. 9, 290 Hz, 365
Hz, 465 Hz and 1200 Hz are respectively 43 in FIG.
Shifted to 5Hz, 547.5Hz, 697.5Hz, 1800Hz. Therefore, when the base member 2a is commonly used, the noise cannot be reduced unless the frequency of the resonator 3 of the Helmholtz resonator is also changed according to the generated frequency. When the frequency of the noise in the structure 2 is detected by the generated frequency detecting means 5n, four high-level frequencies are selected based on the data in the ROM, and it is determined whether each frequency corresponds to each resonator 3. The control means 10b outputs a rotation amount control signal to rotationally drive each adjustment plate motor 2e of the plurality of resonators 3. Then, the screw gear 5f rotating integrally with the adjusting plate motor 2e to the idle gear 5h
, The adjustment plate 5a is moved via the precision rack 5i, and the length in the movable direction (X) is adjusted so that the opening cross-sectional area (Sb) of the opening 4 is automatically formed to a size corresponding to the frequency. Change). Then, the frequencies generated in the plurality of structures 2 are resonated by the Helmholtz resonator 3 and attenuated. In this case, the type of sound source is not limited to the case where the frequency generated during standby or operation is different, or the case where only the first transfer paper (P) is conveyed at high speed to the photosensitive drum of the image carrier 1d. Instead, the noise generation frequency can always be detected and the noise can be attenuated from the frequency with the highest noise level.

Further, the base member 2 may be used with a series machine or the like.
When a is commonly used, even if the rotational speed of the drive motor changes, the resonators 3 of the four Helmholtz resonators can be automatically changed efficiently, so that sound can be effectively silenced. In this embodiment, the number of the resonators 3 of the Helmholtz resonator is four, but any number can be used as long as the base member 2a can be processed (see FIG. 3). In each of the above embodiments, the opening cross-sectional area of the opening 4 is made variable by the opening cross-sectional area changing means in the descending order of the level of the frequency of the sound generated in the structure, so that the frequency at which the noise to be silenced is changed The sound can be automatically and effectively silenced. That is, for example, when there are a plurality of high-level noises and the number thereof is larger than the number of resonators, the muffleable resonators are allocated and muffled in descending order of frequency level (in the order of loud noise). , More effective noise reduction can be performed. In addition, as for the plate member 2a on which the resonator 3 is formed, only the plate member 2a provided on the base member has been described. The following is omitted.

[0020]

According to the first aspect of the present invention, since the present invention is configured as described above, it is formed between the constituent members constituting the structure in the structure for supporting the image forming unit. A passage is formed by an opening between the inside of the resonator and the structure that silences the sound generated by the image forming unit by the closed space, so that a device for silencing the noise is not provided outside the structure. It is possible to provide an image forming apparatus capable of reducing the frequency of the noise to be reduced without requiring a small and unnecessary space without complicating installation and removal, without reducing the rigidity of the structure. In other words, the closed space forms a resonator, and is communicated with the inside of the image forming apparatus through an opening provided in a plate member forming the closed space. The sound can be effectively muted. According to the second aspect of the present invention, an opening is provided between the inside of the resonator and the resonator that silences the sound generated by the image forming unit by the closed space formed in the plate member in the structure supporting the image forming unit. Since the passage is formed by the part, there is no need to install a noise silencer outside the structure, no hassle of installation and removal, and a small and unnecessary space without impairing the rigidity of the plate member of the structure. It is no longer necessary to provide an image forming apparatus capable of silencing the frequency of noise to be silenced. According to the third aspect of the present invention, the resonance that silences the sound generated by the image forming unit is performed by the closed space formed between the inner plate member and the outer plate member of the plate member in the structure supporting the image forming unit. An opening is formed between the inside of the container and the inside of the structure, so there is no need to install a noise silencing device outside the structure, no need for installation and removal, and inside the plate member of the structure It is possible to provide an image forming apparatus capable of reducing the frequency of noise to be reduced without reducing the size and unnecessary space without deteriorating the rigidity of the plate member and the outer plate member.
According to the fourth aspect of the present invention, a plurality of resonators for silencing the sound generated by the image forming unit by the closed space formed between the constituent members constituting the structure inside the structure supporting the image forming unit are provided. An opening is formed between the structure and the inside of the structure, so there is no need to install a noise silencer outside the structure, no hassle of installation and removal, and a small size without impairing the rigidity of the structure As a result, an extra space is not required, and it is possible to provide an image forming apparatus capable of suppressing noise without leaving a plurality of frequencies of noise to be suppressed. That is, a plurality of resonators are provided, and the cross-sectional area of the opening is configured so that each resonator can muffle noise of a different frequency, whereby it is possible to cope with a plurality of different noises. According to the fifth aspect of the invention, the inside of the resonator and the inside of the structure for silencing the sound generated by the image forming unit by the closed space formed between the constituent members constituting the structure inside the structure supporting the image forming unit A passage is formed between the opening and the opening, and the opening cross-sectional area of the opening is made variable by means of the opening cross-section variable means, so that a device for noise reduction can be installed and removed without being provided outside the structure. It is possible to provide an image forming apparatus which is not troublesome and does not require a small and unnecessary space without deteriorating the rigidity of the structure, and which can automatically mute the frequency at which the noise to be muffled changes. According to the sixth aspect of the present invention, the inside of the resonator and the inside of the structure for silencing the sound generated by the image forming unit by the closed space formed between the constituent members constituting the structure inside the structure supporting the image forming unit A passage is formed between the opening and the opening, and the opening cross-sectional area of the opening is made variable by the image forming mode by the opening cross-section variable means, so that a device for suppressing noise is provided outside the structure. It is possible to provide an image forming apparatus that can automatically mute the frequency at which the noise that the user wants to mitigate most is small, does not require extra space without compromising the rigidity of the structure, without the hassle of mounting and dismounting. It became so. According to the seventh aspect of the present invention, the inside of the resonator and the inside of the structure for silencing the sound generated by the image forming unit by the closed space formed between the constituent members constituting the structure inside the structure supporting the image forming unit A passage is formed between the opening and the opening, and the opening cross-sectional area of the opening is made variable by the frequency component and level of the sound generated in the structure by the opening cross-section variable means, so that the noise is reduced. The device does not need to be installed outside the structure, hassle-free installation and removal, does not impair the rigidity of the structure, eliminates the need for a small and unnecessary space, and automatically changes the changing component and level of the noise to be silenced. Thus, an image forming apparatus capable of reducing noise can be provided. According to the eighth aspect of the present invention, the inside of the resonator and the inside of the structure for silencing the sound generated by the image forming unit by the closed space formed between the constituent members constituting the structure inside the structure supporting the image forming unit A passage is formed between the opening and the opening, and the opening cross-sectional area of the opening is made variable by the opening cross-sectional area changing means in descending order of the level of the frequency of the sound generated in the structure. The device does not need to be installed outside the structure, hassle-free installation and removal, does not impair the rigidity of the structure, eliminates the need for extra space and is effective at automatically changing the frequency of the noise you want to muffle. Thus, an image forming apparatus capable of reducing noise can be provided.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram illustrating an outline of an image forming apparatus according to an embodiment of the present invention.

FIG. 2 is an exploded perspective view illustrating a main part of the image forming apparatus according to the exemplary embodiment of the present invention.

FIG. 3 is an exploded perspective view illustrating another main part of the image forming apparatus according to the exemplary embodiment of the present invention.

FIG. 4 is an enlarged cross-sectional view illustrating another main part of the image forming apparatus according to the exemplary embodiment of the present invention.

FIG. 5 is an enlarged perspective view illustrating another main part of the image forming apparatus according to the exemplary embodiment of the present invention.

FIG. 6 is a block diagram illustrating a configuration of another main part of the image forming apparatus according to the exemplary embodiment of the present invention.

FIG. 7 is a block diagram illustrating a configuration of a main part of an image forming apparatus according to another embodiment of the present invention.

FIG. 8 is a block diagram illustrating a configuration of a main part of an image forming apparatus according to another embodiment of the present invention.

FIG. 9 is a graph illustrating characteristics of a sound pressure level and a frequency of the image forming apparatus according to the exemplary embodiment of the present invention.

FIG. 10 is a graph illustrating characteristics of a sound pressure level and a frequency in another state of the image forming apparatus according to the exemplary embodiment of the present invention.

[Explanation of symbols]

1 image forming unit, 1a optical unit, 1a ₁
Case, 1a ₂ contact glass, 1a ₃ Light source, 1a
_Four Imaging optical system, 1b paper feed unit, 1c automatic document feeder, 1c ₁ original table, 1d image carrier, 1e charging charger, 1f developing unit, 1g transfer charger, 1h fixing unit, 1i cleaning unit 2 structure, 2a Plate member, 2a ₁ inner plate member, 2
a ₂ outer plate member, 2a ₃ drawn back portion, 2a ₄ drawn back portion, 2b upper frame, 2c lower frame, 2
d frame members, 2d ₁ frame members, 2d ₂ frame members, 2d ₃ frame members, 2d ₄ Frame members, 2d
₅ frame members, 2d ₆ Frame members, 2d ₇ Frame members, 2d ₈ Frame members, 2d ₉ Frame members, 2d
₁₀ frame members, 2d ₁₁ frame members, 2d ₁₂ frame members, 2d ₁₃ frame members, 2d ₁₄ frame members, 2d
₁₅ frame members, 2d ₁₆ frame members, 2d ₁₇ frame members, 2d ₁₈ frame members, 2d ₁₉ frame members, 2d
₂₀ frame member, 2d ₂₁ frame member, 2d ₂₂ frame member, 2e pin, 2f mounting hole 3 resonator 4 opening 5 opening cross section variable means, 5a adjusting plate, 5a ₁ adjusting plate tip, 5b long hole, 5c step 5d adjustment plate holding bracket, 5e adjustment plate motor, 5f screw gear, 5g shaft, 5h idle gear, 5i precision rack, 5j projection, 5k front sensor, 5l rear sensor, 5m image forming mode detection means, 5n generation frequency Detecting means 6 Upper part 7 Lower part 8 Exterior material 10 Control means, 10a control means, 10b control means

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI theme coat ゛ (Reference) H04N 1/00 G10K 11/16 C 5D061

Claims (8)

[Claims] An image forming apparatus for forming an image by silencing a sound generated by the image forming unit, the image forming unit being driven by one or a plurality of driving sources to form an image, and the image forming unit , A resonator that silences the sound generated by the image forming unit by a closed space formed between constituent members of the structure in the structure, and a structure inside the resonator and the structure An image forming apparatus comprising: an opening that forms a passage between the image forming apparatus and a body. 2. The image forming apparatus according to claim 1, wherein
The image forming apparatus, wherein the resonator is formed in a plate member of the structure. 3. The image forming apparatus according to claim 1, wherein the resonator is formed between an inner plate member and an outer plate member of the plate member of the structure. 4. The image forming apparatus according to claim 1, wherein the image forming apparatus has a plurality of resonators. 5. The image forming apparatus according to claim 1, wherein the opening has a variable opening cross-sectional area by an opening cross-sectional area changing means. 6. The image forming apparatus according to claim 5, wherein
An image forming apparatus characterized in that the opening cross-sectional area varying means varies the opening cross-sectional area in accordance with an image forming mode in which an image is formed in the image forming unit and mutes the sound. 7. The image forming apparatus according to claim 5, wherein
An image forming apparatus characterized in that the opening cross section variable means varies the opening cross section according to the frequency component and level of the sound generated in the structure to muffle the sound. 8. The image forming apparatus according to claim 5, wherein the opening cross-sectional area varying means mutes the sound by changing the opening cross-sectional area in accordance with the order of the frequency of the frequency of the sound generated in the structure. An image forming apparatus comprising: